From d0f445b9f98ef161ebae644d71e9a42c34d7ca17 Mon Sep 17 00:00:00 2001 From: Adrian Conlon <98398945+AdrianConlon@users.noreply.github.com> Date: Mon, 1 Jan 2024 22:35:38 +0000 Subject: [PATCH] Update simdjson for M6502 tests --- M6502/HarteTest_6502/simdjson/simdjson.cpp | 42924 +++++++-- M6502/HarteTest_6502/simdjson/simdjson.h | 86233 +++++++++++++++---- 2 files changed, 106517 insertions(+), 22640 deletions(-) diff --git a/M6502/HarteTest_6502/simdjson/simdjson.cpp b/M6502/HarteTest_6502/simdjson/simdjson.cpp index 76e7e37..855c3cf 100644 --- a/M6502/HarteTest_6502/simdjson/simdjson.cpp +++ b/M6502/HarteTest_6502/simdjson/simdjson.cpp @@ -1,11 +1,2770 @@ -/* auto-generated on 2023-03-13 21:26:32 -0400. Do not edit! */ -/* begin file src/simdjson.cpp */ -#include "simdjson.h" +/* auto-generated on 2023-12-07 12:42:28 -0500. Do not edit! */ +/* including simdjson.cpp: */ +/* begin file simdjson.cpp */ +#define SIMDJSON_SRC_SIMDJSON_CPP -SIMDJSON_PUSH_DISABLE_WARNINGS -SIMDJSON_DISABLE_UNDESIRED_WARNINGS +/* including base.h: #include */ +/* begin file base.h */ +#ifndef SIMDJSON_SRC_BASE_H +#define SIMDJSON_SRC_BASE_H + +/* including simdjson/base.h: #include */ +/* begin file simdjson/base.h */ +/** + * @file Base declarations for all simdjson headers + * @private + */ +#ifndef SIMDJSON_BASE_H +#define SIMDJSON_BASE_H + + /* including simdjson/common_defs.h: #include "simdjson/common_defs.h" */ + /* begin file simdjson/common_defs.h */ +#ifndef SIMDJSON_COMMON_DEFS_H +#define SIMDJSON_COMMON_DEFS_H + +#include +/* including simdjson/compiler_check.h: #include "simdjson/compiler_check.h" */ +/* begin file simdjson/compiler_check.h */ +#ifndef SIMDJSON_COMPILER_CHECK_H +#define SIMDJSON_COMPILER_CHECK_H + +#ifndef __cplusplus +#error simdjson requires a C++ compiler +#endif + +#ifndef SIMDJSON_CPLUSPLUS +#if defined(_MSVC_LANG) && !defined(__clang__) +#define SIMDJSON_CPLUSPLUS (_MSC_VER == 1900 ? 201103L : _MSVC_LANG) +#else +#define SIMDJSON_CPLUSPLUS __cplusplus +#endif +#endif + +// C++ 17 +#if !defined(SIMDJSON_CPLUSPLUS17) && (SIMDJSON_CPLUSPLUS >= 201703L) +#define SIMDJSON_CPLUSPLUS17 1 +#endif + +// C++ 14 +#if !defined(SIMDJSON_CPLUSPLUS14) && (SIMDJSON_CPLUSPLUS >= 201402L) +#define SIMDJSON_CPLUSPLUS14 1 +#endif + +// C++ 11 +#if !defined(SIMDJSON_CPLUSPLUS11) && (SIMDJSON_CPLUSPLUS >= 201103L) +#define SIMDJSON_CPLUSPLUS11 1 +#endif + +#ifndef SIMDJSON_CPLUSPLUS11 +#error simdjson requires a compiler compliant with the C++11 standard +#endif + +#ifndef SIMDJSON_IF_CONSTEXPR +#if SIMDJSON_CPLUSPLUS17 +#define SIMDJSON_IF_CONSTEXPR if constexpr +#else +#define SIMDJSON_IF_CONSTEXPR if +#endif +#endif + +#endif // SIMDJSON_COMPILER_CHECK_H +/* end file simdjson/compiler_check.h */ +/* including simdjson/portability.h: #include "simdjson/portability.h" */ +/* begin file simdjson/portability.h */ +#ifndef SIMDJSON_PORTABILITY_H +#define SIMDJSON_PORTABILITY_H + +#include +#include +#include +#include +#include +#ifndef _WIN32 +// strcasecmp, strncasecmp +#include +#endif + +#ifdef _MSC_VER +#define SIMDJSON_VISUAL_STUDIO 1 +/** + * We want to differentiate carefully between + * clang under visual studio and regular visual + * studio. + * + * Under clang for Windows, we enable: + * * target pragmas so that part and only part of the + * code gets compiled for advanced instructions. + * + */ +#ifdef __clang__ + // clang under visual studio +#define SIMDJSON_CLANG_VISUAL_STUDIO 1 +#else + // just regular visual studio (best guess) +#define SIMDJSON_REGULAR_VISUAL_STUDIO 1 +#endif // __clang__ +#endif // _MSC_VER + +#if defined(__x86_64__) || defined(_M_AMD64) +#define SIMDJSON_IS_X86_64 1 +#elif defined(__aarch64__) || defined(_M_ARM64) +#define SIMDJSON_IS_ARM64 1 +#elif defined(__riscv) && __riscv_xlen == 64 +#define SIMDJSON_IS_RISCV64 1 +#elif defined(__PPC64__) || defined(_M_PPC64) +#if defined(__ALTIVEC__) +#define SIMDJSON_IS_PPC64_VMX 1 +#endif // defined(__ALTIVEC__) +#else +#define SIMDJSON_IS_32BITS 1 + +#if defined(_M_IX86) || defined(__i386__) +#define SIMDJSON_IS_X86_32BITS 1 +#elif defined(__arm__) || defined(_M_ARM) +#define SIMDJSON_IS_ARM_32BITS 1 +#elif defined(__PPC__) || defined(_M_PPC) +#define SIMDJSON_IS_PPC_32BITS 1 +#endif + +#endif // defined(__x86_64__) || defined(_M_AMD64) +#ifndef SIMDJSON_IS_32BITS +#define SIMDJSON_IS_32BITS 0 +#endif + +#if SIMDJSON_IS_32BITS +#ifndef SIMDJSON_NO_PORTABILITY_WARNING +// In the future, we should allow programmers +// to get warning. +#endif // SIMDJSON_NO_PORTABILITY_WARNING +#endif // SIMDJSON_IS_32BITS + +#define SIMDJSON_CAT_IMPLEMENTATION_(a,...) a ## __VA_ARGS__ +#define SIMDJSON_CAT(a,...) SIMDJSON_CAT_IMPLEMENTATION_(a, __VA_ARGS__) + +#define SIMDJSON_STRINGIFY_IMPLEMENTATION_(a,...) #a SIMDJSON_STRINGIFY(__VA_ARGS__) +#define SIMDJSON_STRINGIFY(a,...) SIMDJSON_CAT_IMPLEMENTATION_(a, __VA_ARGS__) + +// this is almost standard? +#undef SIMDJSON_STRINGIFY_IMPLEMENTATION_ +#undef SIMDJSON_STRINGIFY +#define SIMDJSON_STRINGIFY_IMPLEMENTATION_(a) #a +#define SIMDJSON_STRINGIFY(a) SIMDJSON_STRINGIFY_IMPLEMENTATION_(a) + +// Our fast kernels require 64-bit systems. +// +// On 32-bit x86, we lack 64-bit popcnt, lzcnt, blsr instructions. +// Furthermore, the number of SIMD registers is reduced. +// +// On 32-bit ARM, we would have smaller registers. +// +// The simdjson users should still have the fallback kernel. It is +// slower, but it should run everywhere. + +// +// Enable valid runtime implementations, and select SIMDJSON_BUILTIN_IMPLEMENTATION +// + +// We are going to use runtime dispatch. +#if SIMDJSON_IS_X86_64 +#ifdef __clang__ +// clang does not have GCC push pop +// warning: clang attribute push can't be used within a namespace in clang up +// til 8.0 so SIMDJSON_TARGET_REGION and SIMDJSON_UNTARGET_REGION must be *outside* of a +// namespace. +#define SIMDJSON_TARGET_REGION(T) \ + _Pragma(SIMDJSON_STRINGIFY( \ + clang attribute push(__attribute__((target(T))), apply_to = function))) +#define SIMDJSON_UNTARGET_REGION _Pragma("clang attribute pop") +#elif defined(__GNUC__) +// GCC is easier +#define SIMDJSON_TARGET_REGION(T) \ + _Pragma("GCC push_options") _Pragma(SIMDJSON_STRINGIFY(GCC target(T))) +#define SIMDJSON_UNTARGET_REGION _Pragma("GCC pop_options") +#endif // clang then gcc + +#endif // x86 + +// Default target region macros don't do anything. +#ifndef SIMDJSON_TARGET_REGION +#define SIMDJSON_TARGET_REGION(T) +#define SIMDJSON_UNTARGET_REGION +#endif + +// Is threading enabled? +#if defined(_REENTRANT) || defined(_MT) +#ifndef SIMDJSON_THREADS_ENABLED +#define SIMDJSON_THREADS_ENABLED +#endif +#endif + +// workaround for large stack sizes under -O0. +// https://github.com/simdjson/simdjson/issues/691 +#ifdef __APPLE__ +#ifndef __OPTIMIZE__ +// Apple systems have small stack sizes in secondary threads. +// Lack of compiler optimization may generate high stack usage. +// Users may want to disable threads for safety, but only when +// in debug mode which we detect by the fact that the __OPTIMIZE__ +// macro is not defined. +#undef SIMDJSON_THREADS_ENABLED +#endif +#endif + + +#if defined(__clang__) +#define SIMDJSON_NO_SANITIZE_UNDEFINED __attribute__((no_sanitize("undefined"))) +#elif defined(__GNUC__) +#define SIMDJSON_NO_SANITIZE_UNDEFINED __attribute__((no_sanitize_undefined)) +#else +#define SIMDJSON_NO_SANITIZE_UNDEFINED +#endif + + +#if defined(__clang__) || defined(__GNUC__) +#if defined(__has_feature) +# if __has_feature(memory_sanitizer) +#define SIMDJSON_NO_SANITIZE_MEMORY __attribute__((no_sanitize("memory"))) +# endif // if __has_feature(memory_sanitizer) +#endif // defined(__has_feature) +#endif +// make sure it is defined as 'nothing' if it is unapplicable. +#ifndef SIMDJSON_NO_SANITIZE_MEMORY +#define SIMDJSON_NO_SANITIZE_MEMORY +#endif + +#if SIMDJSON_VISUAL_STUDIO +// This is one case where we do not distinguish between +// regular visual studio and clang under visual studio. +// clang under Windows has _stricmp (like visual studio) but not strcasecmp (as clang normally has) +#define simdjson_strcasecmp _stricmp +#define simdjson_strncasecmp _strnicmp +#else +// The strcasecmp, strncasecmp, and strcasestr functions do not work with multibyte strings (e.g. UTF-8). +// So they are only useful for ASCII in our context. +// https://www.gnu.org/software/libunistring/manual/libunistring.html#char-_002a-strings +#define simdjson_strcasecmp strcasecmp +#define simdjson_strncasecmp strncasecmp +#endif + +#if defined(NDEBUG) || defined(__OPTIMIZE__) || (defined(_MSC_VER) && !defined(_DEBUG)) +// If NDEBUG is set, or __OPTIMIZE__ is set, or we are under MSVC in release mode, +// then do away with asserts and use __assume. +#if SIMDJSON_VISUAL_STUDIO +#define SIMDJSON_UNREACHABLE() __assume(0) +#define SIMDJSON_ASSUME(COND) __assume(COND) +#else +#define SIMDJSON_UNREACHABLE() __builtin_unreachable(); +#define SIMDJSON_ASSUME(COND) do { if (!(COND)) __builtin_unreachable(); } while (0) +#endif + +#else // defined(NDEBUG) || defined(__OPTIMIZE__) || (defined(_MSC_VER) && !defined(_DEBUG)) +// This should only ever be enabled in debug mode. +#define SIMDJSON_UNREACHABLE() assert(0); +#define SIMDJSON_ASSUME(COND) assert(COND) + +#endif + +#endif // SIMDJSON_PORTABILITY_H +/* end file simdjson/portability.h */ + +namespace simdjson { + namespace internal { + /** + * @private + * Our own implementation of the C++17 to_chars function. + * Defined in src/to_chars + */ + char* to_chars(char* first, const char* last, double value); + /** + * @private + * A number parsing routine. + * Defined in src/from_chars + */ + double from_chars(const char* first) noexcept; + double from_chars(const char* first, const char* end) noexcept; + } + +#ifndef SIMDJSON_EXCEPTIONS +#if __cpp_exceptions +#define SIMDJSON_EXCEPTIONS 1 +#else +#define SIMDJSON_EXCEPTIONS 0 +#endif +#endif + +} // namespace simdjson + +#if defined(__GNUC__) + // Marks a block with a name so that MCA analysis can see it. +#define SIMDJSON_BEGIN_DEBUG_BLOCK(name) __asm volatile("# LLVM-MCA-BEGIN " #name); +#define SIMDJSON_END_DEBUG_BLOCK(name) __asm volatile("# LLVM-MCA-END " #name); +#define SIMDJSON_DEBUG_BLOCK(name, block) BEGIN_DEBUG_BLOCK(name); block; END_DEBUG_BLOCK(name); +#else +#define SIMDJSON_BEGIN_DEBUG_BLOCK(name) +#define SIMDJSON_END_DEBUG_BLOCK(name) +#define SIMDJSON_DEBUG_BLOCK(name, block) +#endif + +// Align to N-byte boundary +#define SIMDJSON_ROUNDUP_N(a, n) (((a) + ((n)-1)) & ~((n)-1)) +#define SIMDJSON_ROUNDDOWN_N(a, n) ((a) & ~((n)-1)) + +#define SIMDJSON_ISALIGNED_N(ptr, n) (((uintptr_t)(ptr) & ((n)-1)) == 0) + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + +#define simdjson_really_inline __forceinline +#define simdjson_never_inline __declspec(noinline) + +#define simdjson_unused +#define simdjson_warn_unused + +#ifndef simdjson_likely +#define simdjson_likely(x) x +#endif +#ifndef simdjson_unlikely +#define simdjson_unlikely(x) x +#endif + +#define SIMDJSON_PUSH_DISABLE_WARNINGS __pragma(warning( push )) +#define SIMDJSON_PUSH_DISABLE_ALL_WARNINGS __pragma(warning( push, 0 )) +#define SIMDJSON_DISABLE_VS_WARNING(WARNING_NUMBER) __pragma(warning( disable : WARNING_NUMBER )) +// Get rid of Intellisense-only warnings (Code Analysis) +// Though __has_include is C++17, it is supported in Visual Studio 2017 or better (_MSC_VER>=1910). +#ifdef __has_include +#if __has_include() +#include +#define SIMDJSON_DISABLE_UNDESIRED_WARNINGS SIMDJSON_DISABLE_VS_WARNING(ALL_CPPCORECHECK_WARNINGS) +#endif +#endif + +#ifndef SIMDJSON_DISABLE_UNDESIRED_WARNINGS +#define SIMDJSON_DISABLE_UNDESIRED_WARNINGS +#endif + +#define SIMDJSON_DISABLE_DEPRECATED_WARNING SIMDJSON_DISABLE_VS_WARNING(4996) +#define SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING +#define SIMDJSON_POP_DISABLE_WARNINGS __pragma(warning( pop )) + +#define SIMDJSON_PUSH_DISABLE_UNUSED_WARNINGS +#define SIMDJSON_POP_DISABLE_UNUSED_WARNINGS + +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + +#define simdjson_really_inline inline __attribute__((always_inline)) +#define simdjson_never_inline inline __attribute__((noinline)) + +#define simdjson_unused __attribute__((unused)) +#define simdjson_warn_unused __attribute__((warn_unused_result)) + +#ifndef simdjson_likely +#define simdjson_likely(x) __builtin_expect(!!(x), 1) +#endif +#ifndef simdjson_unlikely +#define simdjson_unlikely(x) __builtin_expect(!!(x), 0) +#endif + +#define SIMDJSON_PUSH_DISABLE_WARNINGS _Pragma("GCC diagnostic push") +// gcc doesn't seem to disable all warnings with all and extra, add warnings here as necessary +// We do it separately for clang since it has different warnings. +#ifdef __clang__ +// clang is missing -Wmaybe-uninitialized. +#define SIMDJSON_PUSH_DISABLE_ALL_WARNINGS SIMDJSON_PUSH_DISABLE_WARNINGS \ + SIMDJSON_DISABLE_GCC_WARNING(-Weffc++) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wall) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wconversion) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wextra) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wattributes) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wimplicit-fallthrough) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wnon-virtual-dtor) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wreturn-type) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wshadow) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wunused-parameter) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wunused-variable) +#else // __clang__ +#define SIMDJSON_PUSH_DISABLE_ALL_WARNINGS SIMDJSON_PUSH_DISABLE_WARNINGS \ + SIMDJSON_DISABLE_GCC_WARNING(-Weffc++) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wall) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wconversion) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wextra) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wattributes) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wimplicit-fallthrough) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wnon-virtual-dtor) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wreturn-type) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wshadow) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wunused-parameter) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wunused-variable) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wmaybe-uninitialized) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wformat-security) +#endif // __clang__ + +#define SIMDJSON_PRAGMA(P) _Pragma(#P) +#define SIMDJSON_DISABLE_GCC_WARNING(WARNING) SIMDJSON_PRAGMA(GCC diagnostic ignored #WARNING) +#if SIMDJSON_CLANG_VISUAL_STUDIO +#define SIMDJSON_DISABLE_UNDESIRED_WARNINGS SIMDJSON_DISABLE_GCC_WARNING(-Wmicrosoft-include) +#else +#define SIMDJSON_DISABLE_UNDESIRED_WARNINGS +#endif +#define SIMDJSON_DISABLE_DEPRECATED_WARNING SIMDJSON_DISABLE_GCC_WARNING(-Wdeprecated-declarations) +#define SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING SIMDJSON_DISABLE_GCC_WARNING(-Wstrict-overflow) +#define SIMDJSON_POP_DISABLE_WARNINGS _Pragma("GCC diagnostic pop") + +#define SIMDJSON_PUSH_DISABLE_UNUSED_WARNINGS SIMDJSON_PUSH_DISABLE_WARNINGS \ + SIMDJSON_DISABLE_GCC_WARNING(-Wunused) +#define SIMDJSON_POP_DISABLE_UNUSED_WARNINGS SIMDJSON_POP_DISABLE_WARNINGS + + + +#endif // MSC_VER + +#if defined(simdjson_inline) + // Prefer the user's definition of simdjson_inline; don't define it ourselves. +#elif defined(__GNUC__) && !defined(__OPTIMIZE__) + // If optimizations are disabled, forcing inlining can lead to significant + // code bloat and high compile times. Don't use simdjson_really_inline for + // unoptimized builds. +#define simdjson_inline inline +#else + // Force inlining for most simdjson functions. +#define simdjson_inline simdjson_really_inline +#endif + +#if SIMDJSON_VISUAL_STUDIO + /** + * Windows users need to do some extra work when building + * or using a dynamic library (DLL). When building, we need + * to set SIMDJSON_DLLIMPORTEXPORT to __declspec(dllexport). + * When *using* the DLL, the user needs to set + * SIMDJSON_DLLIMPORTEXPORT __declspec(dllimport). + * + * Static libraries not need require such work. + * + * It does not matter here whether you are using + * the regular visual studio or clang under visual + * studio, you still need to handle these issues. + * + * Non-Windows systems do not have this complexity. + */ +#if SIMDJSON_BUILDING_WINDOWS_DYNAMIC_LIBRARY + // We set SIMDJSON_BUILDING_WINDOWS_DYNAMIC_LIBRARY when we build a DLL under Windows. + // It should never happen that both SIMDJSON_BUILDING_WINDOWS_DYNAMIC_LIBRARY and + // SIMDJSON_USING_WINDOWS_DYNAMIC_LIBRARY are set. +#define SIMDJSON_DLLIMPORTEXPORT __declspec(dllexport) +#elif SIMDJSON_USING_WINDOWS_DYNAMIC_LIBRARY + // Windows user who call a dynamic library should set SIMDJSON_USING_WINDOWS_DYNAMIC_LIBRARY to 1. +#define SIMDJSON_DLLIMPORTEXPORT __declspec(dllimport) +#else + // We assume by default static linkage +#define SIMDJSON_DLLIMPORTEXPORT +#endif + +/** + * Workaround for the vcpkg package manager. Only vcpkg should + * ever touch the next line. The SIMDJSON_USING_LIBRARY macro is otherwise unused. + */ +#if SIMDJSON_USING_LIBRARY +#define SIMDJSON_DLLIMPORTEXPORT __declspec(dllimport) +#endif + /** + * End of workaround for the vcpkg package manager. + */ +#else +#define SIMDJSON_DLLIMPORTEXPORT +#endif + +// C++17 requires string_view. +#if SIMDJSON_CPLUSPLUS17 +#define SIMDJSON_HAS_STRING_VIEW +#include // by the standard, this has to be safe. +#endif + +// This macro (__cpp_lib_string_view) has to be defined +// for C++17 and better, but if it is otherwise defined, +// we are going to assume that string_view is available +// even if we do not have C++17 support. +#ifdef __cpp_lib_string_view +#define SIMDJSON_HAS_STRING_VIEW +#endif + +// Some systems have string_view even if we do not have C++17 support, +// and even if __cpp_lib_string_view is undefined, it is the case +// with Apple clang version 11. +// We must handle it. *This is important.* +#ifndef SIMDJSON_HAS_STRING_VIEW +#if defined __has_include +// do not combine the next #if with the previous one (unsafe) +#if __has_include () +// now it is safe to trigger the include +#include // though the file is there, it does not follow that we got the implementation +#if defined(_LIBCPP_STRING_VIEW) +// Ah! So we under libc++ which under its Library Fundamentals Technical Specification, which preceded C++17, +// included string_view. +// This means that we have string_view *even though* we may not have C++17. +#define SIMDJSON_HAS_STRING_VIEW +#endif // _LIBCPP_STRING_VIEW +#endif // __has_include () +#endif // defined __has_include +#endif // def SIMDJSON_HAS_STRING_VIEW +// end of complicated but important routine to try to detect string_view. + +// +// Backfill std::string_view using nonstd::string_view on systems where +// we expect that string_view is missing. Important: if we get this wrong, +// we will end up with two string_view definitions and potential trouble. +// That is why we work so hard above to avoid it. +// +#ifndef SIMDJSON_HAS_STRING_VIEW +SIMDJSON_PUSH_DISABLE_ALL_WARNINGS +/* including simdjson/nonstd/string_view.hpp: #include "simdjson/nonstd/string_view.hpp" */ +/* begin file simdjson/nonstd/string_view.hpp */ +// Copyright 2017-2020 by Martin Moene +// +// string-view lite, a C++17-like string_view for C++98 and later. +// For more information see https://github.com/martinmoene/string-view-lite +// +// Distributed under the Boost Software License, Version 1.0. +// (See accompanying file LICENSE.txt or copy at http://www.boost.org/LICENSE_1_0.txt) + +#pragma once + +#ifndef NONSTD_SV_LITE_H_INCLUDED +#define NONSTD_SV_LITE_H_INCLUDED + +#define string_view_lite_MAJOR 1 +#define string_view_lite_MINOR 7 +#define string_view_lite_PATCH 0 + +#define string_view_lite_VERSION nssv_STRINGIFY(string_view_lite_MAJOR) "." nssv_STRINGIFY(string_view_lite_MINOR) "." nssv_STRINGIFY(string_view_lite_PATCH) + +#define nssv_STRINGIFY( x ) nssv_STRINGIFY_( x ) +#define nssv_STRINGIFY_( x ) #x + +// string-view lite configuration: + +#define nssv_STRING_VIEW_DEFAULT 0 +#define nssv_STRING_VIEW_NONSTD 1 +#define nssv_STRING_VIEW_STD 2 + +// tweak header support: + +#ifdef __has_include +# if __has_include() +# include +# endif +#define nssv_HAVE_TWEAK_HEADER 1 +#else +#define nssv_HAVE_TWEAK_HEADER 0 +//# pragma message("string_view.hpp: Note: Tweak header not supported.") +#endif + +// string_view selection and configuration: + +#if !defined( nssv_CONFIG_SELECT_STRING_VIEW ) +# define nssv_CONFIG_SELECT_STRING_VIEW ( nssv_HAVE_STD_STRING_VIEW ? nssv_STRING_VIEW_STD : nssv_STRING_VIEW_NONSTD ) +#endif + +#ifndef nssv_CONFIG_STD_SV_OPERATOR +# define nssv_CONFIG_STD_SV_OPERATOR 0 +#endif + +#ifndef nssv_CONFIG_USR_SV_OPERATOR +# define nssv_CONFIG_USR_SV_OPERATOR 1 +#endif + +#ifdef nssv_CONFIG_CONVERSION_STD_STRING +# define nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS nssv_CONFIG_CONVERSION_STD_STRING +# define nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS nssv_CONFIG_CONVERSION_STD_STRING +#endif + +#ifndef nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS +# define nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS 1 +#endif + +#ifndef nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS +# define nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS 1 +#endif + +#ifndef nssv_CONFIG_NO_STREAM_INSERTION +# define nssv_CONFIG_NO_STREAM_INSERTION 0 +#endif + +// Control presence of exception handling (try and auto discover): + +#ifndef nssv_CONFIG_NO_EXCEPTIONS +# if defined(_MSC_VER) +# include // for _HAS_EXCEPTIONS +# endif +# if defined(__cpp_exceptions) || defined(__EXCEPTIONS) || (_HAS_EXCEPTIONS) +# define nssv_CONFIG_NO_EXCEPTIONS 0 +# else +# define nssv_CONFIG_NO_EXCEPTIONS 1 +# endif +#endif + +// C++ language version detection (C++23 is speculative): +// Note: VC14.0/1900 (VS2015) lacks too much from C++14. + +#ifndef nssv_CPLUSPLUS +# if defined(_MSVC_LANG ) && !defined(__clang__) +# define nssv_CPLUSPLUS (_MSC_VER == 1900 ? 201103L : _MSVC_LANG ) +# else +# define nssv_CPLUSPLUS __cplusplus +# endif +#endif + +#define nssv_CPP98_OR_GREATER ( nssv_CPLUSPLUS >= 199711L ) +#define nssv_CPP11_OR_GREATER ( nssv_CPLUSPLUS >= 201103L ) +#define nssv_CPP11_OR_GREATER_ ( nssv_CPLUSPLUS >= 201103L ) +#define nssv_CPP14_OR_GREATER ( nssv_CPLUSPLUS >= 201402L ) +#define nssv_CPP17_OR_GREATER ( nssv_CPLUSPLUS >= 201703L ) +#define nssv_CPP20_OR_GREATER ( nssv_CPLUSPLUS >= 202002L ) +#define nssv_CPP23_OR_GREATER ( nssv_CPLUSPLUS >= 202300L ) + +// use C++17 std::string_view if available and requested: + +#if nssv_CPP17_OR_GREATER && defined(__has_include ) +# if __has_include( ) +# define nssv_HAVE_STD_STRING_VIEW 1 +# else +# define nssv_HAVE_STD_STRING_VIEW 0 +# endif +#else +# define nssv_HAVE_STD_STRING_VIEW 0 +#endif + +#define nssv_USES_STD_STRING_VIEW ( (nssv_CONFIG_SELECT_STRING_VIEW == nssv_STRING_VIEW_STD) || ((nssv_CONFIG_SELECT_STRING_VIEW == nssv_STRING_VIEW_DEFAULT) && nssv_HAVE_STD_STRING_VIEW) ) + +#define nssv_HAVE_STARTS_WITH ( nssv_CPP20_OR_GREATER || !nssv_USES_STD_STRING_VIEW ) +#define nssv_HAVE_ENDS_WITH nssv_HAVE_STARTS_WITH + +// +// Use C++17 std::string_view: +// + +#if nssv_USES_STD_STRING_VIEW + +#include + +// Extensions for std::string: + +#if nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS + +namespace nonstd { + + template< class CharT, class Traits, class Allocator = std::allocator > + std::basic_string + to_string(std::basic_string_view v, Allocator const& a = Allocator()) + { + return std::basic_string(v.begin(), v.end(), a); + } + + template< class CharT, class Traits, class Allocator > + std::basic_string_view + to_string_view(std::basic_string const& s) + { + return std::basic_string_view(s.data(), s.size()); + } + + // Literal operators sv and _sv: + +#if nssv_CONFIG_STD_SV_OPERATOR + + using namespace std::literals::string_view_literals; + +#endif + +#if nssv_CONFIG_USR_SV_OPERATOR + + inline namespace literals { + inline namespace string_view_literals { + + + constexpr std::string_view operator "" _sv(const char* str, size_t len) noexcept // (1) + { + return std::string_view{ str, len }; + } + + constexpr std::u16string_view operator "" _sv(const char16_t* str, size_t len) noexcept // (2) + { + return std::u16string_view{ str, len }; + } + + constexpr std::u32string_view operator "" _sv(const char32_t* str, size_t len) noexcept // (3) + { + return std::u32string_view{ str, len }; + } + + constexpr std::wstring_view operator "" _sv(const wchar_t* str, size_t len) noexcept // (4) + { + return std::wstring_view{ str, len }; + } + + } + } // namespace literals::string_view_literals + +#endif // nssv_CONFIG_USR_SV_OPERATOR + +} // namespace nonstd + +#endif // nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS + +namespace nonstd { + + using std::string_view; + using std::wstring_view; + using std::u16string_view; + using std::u32string_view; + using std::basic_string_view; + + // literal "sv" and "_sv", see above + + using std::operator==; + using std::operator!=; + using std::operator<; + using std::operator<=; + using std::operator>; + using std::operator>=; + + using std::operator<<; + +} // namespace nonstd + +#else // nssv_HAVE_STD_STRING_VIEW + +// +// Before C++17: use string_view lite: +// + +// Compiler versions: +// +// MSVC++ 6.0 _MSC_VER == 1200 nssv_COMPILER_MSVC_VERSION == 60 (Visual Studio 6.0) +// MSVC++ 7.0 _MSC_VER == 1300 nssv_COMPILER_MSVC_VERSION == 70 (Visual Studio .NET 2002) +// MSVC++ 7.1 _MSC_VER == 1310 nssv_COMPILER_MSVC_VERSION == 71 (Visual Studio .NET 2003) +// MSVC++ 8.0 _MSC_VER == 1400 nssv_COMPILER_MSVC_VERSION == 80 (Visual Studio 2005) +// MSVC++ 9.0 _MSC_VER == 1500 nssv_COMPILER_MSVC_VERSION == 90 (Visual Studio 2008) +// MSVC++ 10.0 _MSC_VER == 1600 nssv_COMPILER_MSVC_VERSION == 100 (Visual Studio 2010) +// MSVC++ 11.0 _MSC_VER == 1700 nssv_COMPILER_MSVC_VERSION == 110 (Visual Studio 2012) +// MSVC++ 12.0 _MSC_VER == 1800 nssv_COMPILER_MSVC_VERSION == 120 (Visual Studio 2013) +// MSVC++ 14.0 _MSC_VER == 1900 nssv_COMPILER_MSVC_VERSION == 140 (Visual Studio 2015) +// MSVC++ 14.1 _MSC_VER >= 1910 nssv_COMPILER_MSVC_VERSION == 141 (Visual Studio 2017) +// MSVC++ 14.2 _MSC_VER >= 1920 nssv_COMPILER_MSVC_VERSION == 142 (Visual Studio 2019) + +#if defined(_MSC_VER ) && !defined(__clang__) +# define nssv_COMPILER_MSVC_VER (_MSC_VER ) +# define nssv_COMPILER_MSVC_VERSION (_MSC_VER / 10 - 10 * ( 5 + (_MSC_VER < 1900 ) ) ) +#else +# define nssv_COMPILER_MSVC_VER 0 +# define nssv_COMPILER_MSVC_VERSION 0 +#endif + +#define nssv_COMPILER_VERSION( major, minor, patch ) ( 10 * ( 10 * (major) + (minor) ) + (patch) ) + +#if defined( __apple_build_version__ ) +# define nssv_COMPILER_APPLECLANG_VERSION nssv_COMPILER_VERSION(__clang_major__, __clang_minor__, __clang_patchlevel__) +# define nssv_COMPILER_CLANG_VERSION 0 +#elif defined( __clang__ ) +# define nssv_COMPILER_APPLECLANG_VERSION 0 +# define nssv_COMPILER_CLANG_VERSION nssv_COMPILER_VERSION(__clang_major__, __clang_minor__, __clang_patchlevel__) +#else +# define nssv_COMPILER_APPLECLANG_VERSION 0 +# define nssv_COMPILER_CLANG_VERSION 0 +#endif + +#if defined(__GNUC__) && !defined(__clang__) +# define nssv_COMPILER_GNUC_VERSION nssv_COMPILER_VERSION(__GNUC__, __GNUC_MINOR__, __GNUC_PATCHLEVEL__) +#else +# define nssv_COMPILER_GNUC_VERSION 0 +#endif + +// half-open range [lo..hi): +#define nssv_BETWEEN( v, lo, hi ) ( (lo) <= (v) && (v) < (hi) ) + +// Presence of language and library features: + +#ifdef _HAS_CPP0X +# define nssv_HAS_CPP0X _HAS_CPP0X +#else +# define nssv_HAS_CPP0X 0 +#endif + +// Unless defined otherwise below, consider VC14 as C++11 for variant-lite: + +#if nssv_COMPILER_MSVC_VER >= 1900 +# undef nssv_CPP11_OR_GREATER +# define nssv_CPP11_OR_GREATER 1 +#endif + +#define nssv_CPP11_90 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1500) +#define nssv_CPP11_100 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1600) +#define nssv_CPP11_110 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1700) +#define nssv_CPP11_120 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1800) +#define nssv_CPP11_140 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1900) +#define nssv_CPP11_141 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1910) + +#define nssv_CPP14_000 (nssv_CPP14_OR_GREATER) +#define nssv_CPP17_000 (nssv_CPP17_OR_GREATER) + +// Presence of C++11 language features: + +#define nssv_HAVE_CONSTEXPR_11 nssv_CPP11_140 +#define nssv_HAVE_EXPLICIT_CONVERSION nssv_CPP11_140 +#define nssv_HAVE_INLINE_NAMESPACE nssv_CPP11_140 +#define nssv_HAVE_IS_DEFAULT nssv_CPP11_140 +#define nssv_HAVE_IS_DELETE nssv_CPP11_140 +#define nssv_HAVE_NOEXCEPT nssv_CPP11_140 +#define nssv_HAVE_NULLPTR nssv_CPP11_100 +#define nssv_HAVE_REF_QUALIFIER nssv_CPP11_140 +#define nssv_HAVE_UNICODE_LITERALS nssv_CPP11_140 +#define nssv_HAVE_USER_DEFINED_LITERALS nssv_CPP11_140 +#define nssv_HAVE_WCHAR16_T nssv_CPP11_100 +#define nssv_HAVE_WCHAR32_T nssv_CPP11_100 + +#if ! ( ( nssv_CPP11_OR_GREATER && nssv_COMPILER_CLANG_VERSION ) || nssv_BETWEEN( nssv_COMPILER_CLANG_VERSION, 300, 400 ) ) +# define nssv_HAVE_STD_DEFINED_LITERALS nssv_CPP11_140 +#else +# define nssv_HAVE_STD_DEFINED_LITERALS 0 +#endif + +// Presence of C++14 language features: + +#define nssv_HAVE_CONSTEXPR_14 nssv_CPP14_000 + +// Presence of C++17 language features: + +#define nssv_HAVE_NODISCARD nssv_CPP17_000 + +// Presence of C++ library features: + +#define nssv_HAVE_STD_HASH nssv_CPP11_120 + +// Presence of compiler intrinsics: + +// Providing char-type specializations for compare() and length() that +// use compiler intrinsics can improve compile- and run-time performance. +// +// The challenge is in using the right combinations of builtin availability +// and its constexpr-ness. +// +// | compiler | __builtin_memcmp (constexpr) | memcmp (constexpr) | +// |----------|------------------------------|---------------------| +// | clang | 4.0 (>= 4.0 ) | any (? ) | +// | clang-a | 9.0 (>= 9.0 ) | any (? ) | +// | gcc | any (constexpr) | any (? ) | +// | msvc | >= 14.2 C++17 (>= 14.2 ) | any (? ) | + +#define nssv_HAVE_BUILTIN_VER ( (nssv_CPP17_000 && nssv_COMPILER_MSVC_VERSION >= 142) || nssv_COMPILER_GNUC_VERSION > 0 || nssv_COMPILER_CLANG_VERSION >= 400 || nssv_COMPILER_APPLECLANG_VERSION >= 900 ) +#define nssv_HAVE_BUILTIN_CE ( nssv_HAVE_BUILTIN_VER ) + +#define nssv_HAVE_BUILTIN_MEMCMP ( (nssv_HAVE_CONSTEXPR_14 && nssv_HAVE_BUILTIN_CE) || !nssv_HAVE_CONSTEXPR_14 ) +#define nssv_HAVE_BUILTIN_STRLEN ( (nssv_HAVE_CONSTEXPR_11 && nssv_HAVE_BUILTIN_CE) || !nssv_HAVE_CONSTEXPR_11 ) + +#ifdef __has_builtin +# define nssv_HAVE_BUILTIN( x ) __has_builtin( x ) +#else +# define nssv_HAVE_BUILTIN( x ) 0 +#endif + +#if nssv_HAVE_BUILTIN(__builtin_memcmp) || nssv_HAVE_BUILTIN_VER +# define nssv_BUILTIN_MEMCMP __builtin_memcmp +#else +# define nssv_BUILTIN_MEMCMP memcmp +#endif + +#if nssv_HAVE_BUILTIN(__builtin_strlen) || nssv_HAVE_BUILTIN_VER +# define nssv_BUILTIN_STRLEN __builtin_strlen +#else +# define nssv_BUILTIN_STRLEN strlen +#endif + +// C++ feature usage: + +#if nssv_HAVE_CONSTEXPR_11 +# define nssv_constexpr constexpr +#else +# define nssv_constexpr /*constexpr*/ +#endif + +#if nssv_HAVE_CONSTEXPR_14 +# define nssv_constexpr14 constexpr +#else +# define nssv_constexpr14 /*constexpr*/ +#endif + +#if nssv_HAVE_EXPLICIT_CONVERSION +# define nssv_explicit explicit +#else +# define nssv_explicit /*explicit*/ +#endif + +#if nssv_HAVE_INLINE_NAMESPACE +# define nssv_inline_ns inline +#else +# define nssv_inline_ns /*inline*/ +#endif + +#if nssv_HAVE_NOEXCEPT +# define nssv_noexcept noexcept +#else +# define nssv_noexcept /*noexcept*/ +#endif + +//#if nssv_HAVE_REF_QUALIFIER +//# define nssv_ref_qual & +//# define nssv_refref_qual && +//#else +//# define nssv_ref_qual /*&*/ +//# define nssv_refref_qual /*&&*/ +//#endif + +#if nssv_HAVE_NULLPTR +# define nssv_nullptr nullptr +#else +# define nssv_nullptr NULL +#endif + +#if nssv_HAVE_NODISCARD +# define nssv_nodiscard [[nodiscard]] +#else +# define nssv_nodiscard /*[[nodiscard]]*/ +#endif + +// Additional includes: + +#include +#include +#include +#include +#include // std::char_traits<> + +#if ! nssv_CONFIG_NO_STREAM_INSERTION +# include +#endif + +#if ! nssv_CONFIG_NO_EXCEPTIONS +# include +#endif + +#if nssv_CPP11_OR_GREATER +# include +#endif + +// Clang, GNUC, MSVC warning suppression macros: + +#if defined(__clang__) +# pragma clang diagnostic ignored "-Wreserved-user-defined-literal" +# pragma clang diagnostic push +# pragma clang diagnostic ignored "-Wuser-defined-literals" +#elif defined(__GNUC__) +# pragma GCC diagnostic push +# pragma GCC diagnostic ignored "-Wliteral-suffix" +#endif // __clang__ + +#if nssv_COMPILER_MSVC_VERSION >= 140 +# define nssv_SUPPRESS_MSGSL_WARNING(expr) [[gsl::suppress(expr)]] +# define nssv_SUPPRESS_MSVC_WARNING(code, descr) __pragma(warning(suppress: code) ) +# define nssv_DISABLE_MSVC_WARNINGS(codes) __pragma(warning(push)) __pragma(warning(disable: codes)) +#else +# define nssv_SUPPRESS_MSGSL_WARNING(expr) +# define nssv_SUPPRESS_MSVC_WARNING(code, descr) +# define nssv_DISABLE_MSVC_WARNINGS(codes) +#endif + +#if defined(__clang__) +# define nssv_RESTORE_WARNINGS() _Pragma("clang diagnostic pop") +#elif defined(__GNUC__) +# define nssv_RESTORE_WARNINGS() _Pragma("GCC diagnostic pop") +#elif nssv_COMPILER_MSVC_VERSION >= 140 +# define nssv_RESTORE_WARNINGS() __pragma(warning(pop )) +#else +# define nssv_RESTORE_WARNINGS() +#endif + +// Suppress the following MSVC (GSL) warnings: +// - C4455, non-gsl : 'operator ""sv': literal suffix identifiers that do not +// start with an underscore are reserved +// - C26472, gsl::t.1 : don't use a static_cast for arithmetic conversions; +// use brace initialization, gsl::narrow_cast or gsl::narow +// - C26481: gsl::b.1 : don't use pointer arithmetic. Use span instead + +nssv_DISABLE_MSVC_WARNINGS(4455 26481 26472) +//nssv_DISABLE_CLANG_WARNINGS( "-Wuser-defined-literals" ) +//nssv_DISABLE_GNUC_WARNINGS( -Wliteral-suffix ) + +namespace nonstd { + namespace sv_lite { + + // + // basic_string_view declaration: + // + + template + < + class CharT, + class Traits = std::char_traits + > + class basic_string_view; + + namespace detail { + + // support constexpr comparison in C++14; + // for C++17 and later, use provided traits: + + template< typename CharT > + inline nssv_constexpr14 int compare(CharT const* s1, CharT const* s2, std::size_t count) + { + while (count-- != 0) + { + if (*s1 < *s2) return -1; + if (*s1 > *s2) return +1; + ++s1; ++s2; + } + return 0; + } + +#if nssv_HAVE_BUILTIN_MEMCMP + + // specialization of compare() for char, see also generic compare() above: + + inline nssv_constexpr14 int compare(char const* s1, char const* s2, std::size_t count) + { + return nssv_BUILTIN_MEMCMP(s1, s2, count); + } + +#endif + +#if nssv_HAVE_BUILTIN_STRLEN + + // specialization of length() for char, see also generic length() further below: + + inline nssv_constexpr std::size_t length(char const* s) + { + return nssv_BUILTIN_STRLEN(s); + } + +#endif + +#if defined(__OPTIMIZE__) + + // gcc, clang provide __OPTIMIZE__ + // Expect tail call optimization to make length() non-recursive: + + template< typename CharT > + inline nssv_constexpr std::size_t length(CharT* s, std::size_t result = 0) + { + return *s == '\0' ? result : length(s + 1, result + 1); + } + +#else // OPTIMIZE + + // non-recursive: + + template< typename CharT > + inline nssv_constexpr14 std::size_t length(CharT* s) + { + std::size_t result = 0; + while (*s++ != '\0') + { + ++result; + } + return result; + } + +#endif // OPTIMIZE + +#if nssv_CPP11_OR_GREATER && ! nssv_CPP17_OR_GREATER +#if defined(__OPTIMIZE__) + + // gcc, clang provide __OPTIMIZE__ + // Expect tail call optimization to make search() non-recursive: + + template< class CharT, class Traits = std::char_traits > + constexpr const CharT* search(basic_string_view haystack, basic_string_view needle) + { + return haystack.starts_with(needle) ? haystack.begin() : + haystack.empty() ? haystack.end() : search(haystack.substr(1), needle); + } + +#else // OPTIMIZE + + // non-recursive: + + template< class CharT, class Traits = std::char_traits > + constexpr const CharT* search(basic_string_view haystack, basic_string_view needle) + { + return std::search(haystack.begin(), haystack.end(), needle.begin(), needle.end()); + } + +#endif // OPTIMIZE +#endif // nssv_CPP11_OR_GREATER && ! nssv_CPP17_OR_GREATER + + } // namespace detail + + // + // basic_string_view: + // + + template + < + class CharT, + class Traits /* = std::char_traits */ + > + class basic_string_view + { + public: + // Member types: + + typedef Traits traits_type; + typedef CharT value_type; + + typedef CharT* pointer; + typedef CharT const* const_pointer; + typedef CharT& reference; + typedef CharT const& const_reference; + + typedef const_pointer iterator; + typedef const_pointer const_iterator; + typedef std::reverse_iterator< const_iterator > reverse_iterator; + typedef std::reverse_iterator< const_iterator > const_reverse_iterator; + + typedef std::size_t size_type; + typedef std::ptrdiff_t difference_type; + + // 24.4.2.1 Construction and assignment: + + nssv_constexpr basic_string_view() nssv_noexcept + : data_(nssv_nullptr) + , size_(0) + {} + +#if nssv_CPP11_OR_GREATER + nssv_constexpr basic_string_view(basic_string_view const& other) nssv_noexcept = default; +#else + nssv_constexpr basic_string_view(basic_string_view const& other) nssv_noexcept + : data_(other.data_) + , size_(other.size_) + {} +#endif + + nssv_constexpr basic_string_view(CharT const* s, size_type count) nssv_noexcept // non-standard noexcept + : data_(s) + , size_(count) + {} + + nssv_constexpr basic_string_view(CharT const* s) nssv_noexcept // non-standard noexcept + : data_(s) +#if nssv_CPP17_OR_GREATER + , size_(Traits::length(s)) +#elif nssv_CPP11_OR_GREATER + , size_(detail::length(s)) +#else + , size_(Traits::length(s)) +#endif + {} + +#if nssv_HAVE_NULLPTR +# if nssv_HAVE_IS_DELETE + nssv_constexpr basic_string_view(std::nullptr_t) nssv_noexcept = delete; +# else + private: nssv_constexpr basic_string_view(std::nullptr_t) nssv_noexcept; public: +# endif +#endif + + // Assignment: + +#if nssv_CPP11_OR_GREATER + nssv_constexpr14 basic_string_view& operator=(basic_string_view const& other) nssv_noexcept = default; +#else + nssv_constexpr14 basic_string_view& operator=(basic_string_view const& other) nssv_noexcept + { + data_ = other.data_; + size_ = other.size_; + return *this; + } +#endif + + // 24.4.2.2 Iterator support: + + nssv_constexpr const_iterator begin() const nssv_noexcept { return data_; } + nssv_constexpr const_iterator end() const nssv_noexcept { return data_ + size_; } + + nssv_constexpr const_iterator cbegin() const nssv_noexcept { return begin(); } + nssv_constexpr const_iterator cend() const nssv_noexcept { return end(); } + + nssv_constexpr const_reverse_iterator rbegin() const nssv_noexcept { return const_reverse_iterator(end()); } + nssv_constexpr const_reverse_iterator rend() const nssv_noexcept { return const_reverse_iterator(begin()); } + + nssv_constexpr const_reverse_iterator crbegin() const nssv_noexcept { return rbegin(); } + nssv_constexpr const_reverse_iterator crend() const nssv_noexcept { return rend(); } + + // 24.4.2.3 Capacity: + + nssv_constexpr size_type size() const nssv_noexcept { return size_; } + nssv_constexpr size_type length() const nssv_noexcept { return size_; } + nssv_constexpr size_type max_size() const nssv_noexcept { return (std::numeric_limits< size_type >::max)(); } + + // since C++20 + nssv_nodiscard nssv_constexpr bool empty() const nssv_noexcept + { + return 0 == size_; + } + + // 24.4.2.4 Element access: + + nssv_constexpr const_reference operator[](size_type pos) const + { + return data_at(pos); + } + + nssv_constexpr14 const_reference at(size_type pos) const + { +#if nssv_CONFIG_NO_EXCEPTIONS + assert(pos < size()); +#else + if (pos >= size()) + { + throw std::out_of_range("nonstd::string_view::at()"); + } +#endif + return data_at(pos); + } + + nssv_constexpr const_reference front() const { return data_at(0); } + nssv_constexpr const_reference back() const { return data_at(size() - 1); } + + nssv_constexpr const_pointer data() const nssv_noexcept { return data_; } + + // 24.4.2.5 Modifiers: + + nssv_constexpr14 void remove_prefix(size_type n) + { + assert(n <= size()); + data_ += n; + size_ -= n; + } + + nssv_constexpr14 void remove_suffix(size_type n) + { + assert(n <= size()); + size_ -= n; + } + + nssv_constexpr14 void swap(basic_string_view& other) nssv_noexcept + { + const basic_string_view tmp(other); + other = *this; + *this = tmp; + } + + // 24.4.2.6 String operations: + + size_type copy(CharT* dest, size_type n, size_type pos = 0) const + { +#if nssv_CONFIG_NO_EXCEPTIONS + assert(pos <= size()); +#else + if (pos > size()) + { + throw std::out_of_range("nonstd::string_view::copy()"); + } +#endif + const size_type rlen = (std::min)(n, size() - pos); + + (void)Traits::copy(dest, data() + pos, rlen); + + return rlen; + } + + nssv_constexpr14 basic_string_view substr(size_type pos = 0, size_type n = npos) const + { +#if nssv_CONFIG_NO_EXCEPTIONS + assert(pos <= size()); +#else + if (pos > size()) + { + throw std::out_of_range("nonstd::string_view::substr()"); + } +#endif + return basic_string_view(data() + pos, (std::min)(n, size() - pos)); + } + + // compare(), 6x: + + nssv_constexpr14 int compare(basic_string_view other) const nssv_noexcept // (1) + { +#if nssv_CPP17_OR_GREATER + if (const int result = Traits::compare(data(), other.data(), (std::min)(size(), other.size()))) +#else + if (const int result = detail::compare(data(), other.data(), (std::min)(size(), other.size()))) +#endif + { + return result; + } + + return size() == other.size() ? 0 : size() < other.size() ? -1 : 1; + } + + nssv_constexpr int compare(size_type pos1, size_type n1, basic_string_view other) const // (2) + { + return substr(pos1, n1).compare(other); + } + + nssv_constexpr int compare(size_type pos1, size_type n1, basic_string_view other, size_type pos2, size_type n2) const // (3) + { + return substr(pos1, n1).compare(other.substr(pos2, n2)); + } + + nssv_constexpr int compare(CharT const* s) const // (4) + { + return compare(basic_string_view(s)); + } + + nssv_constexpr int compare(size_type pos1, size_type n1, CharT const* s) const // (5) + { + return substr(pos1, n1).compare(basic_string_view(s)); + } + + nssv_constexpr int compare(size_type pos1, size_type n1, CharT const* s, size_type n2) const // (6) + { + return substr(pos1, n1).compare(basic_string_view(s, n2)); + } + + // 24.4.2.7 Searching: + + // starts_with(), 3x, since C++20: + + nssv_constexpr bool starts_with(basic_string_view v) const nssv_noexcept // (1) + { + return size() >= v.size() && compare(0, v.size(), v) == 0; + } + + nssv_constexpr bool starts_with(CharT c) const nssv_noexcept // (2) + { + return starts_with(basic_string_view(&c, 1)); + } + + nssv_constexpr bool starts_with(CharT const* s) const // (3) + { + return starts_with(basic_string_view(s)); + } + + // ends_with(), 3x, since C++20: + + nssv_constexpr bool ends_with(basic_string_view v) const nssv_noexcept // (1) + { + return size() >= v.size() && compare(size() - v.size(), npos, v) == 0; + } + + nssv_constexpr bool ends_with(CharT c) const nssv_noexcept // (2) + { + return ends_with(basic_string_view(&c, 1)); + } + + nssv_constexpr bool ends_with(CharT const* s) const // (3) + { + return ends_with(basic_string_view(s)); + } + + // find(), 4x: + + nssv_constexpr size_type find(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) + { + return assert(v.size() == 0 || v.data() != nssv_nullptr) + , pos >= size() + ? npos : to_pos( +#if nssv_CPP11_OR_GREATER && ! nssv_CPP17_OR_GREATER + detail::search(substr(pos), v) +#else + std::search(cbegin() + pos, cend(), v.cbegin(), v.cend(), Traits::eq) +#endif + ); + } + + nssv_constexpr size_type find(CharT c, size_type pos = 0) const nssv_noexcept // (2) + { + return find(basic_string_view(&c, 1), pos); + } + + nssv_constexpr size_type find(CharT const* s, size_type pos, size_type n) const // (3) + { + return find(basic_string_view(s, n), pos); + } + + nssv_constexpr size_type find(CharT const* s, size_type pos = 0) const // (4) + { + return find(basic_string_view(s), pos); + } + + // rfind(), 4x: + + nssv_constexpr14 size_type rfind(basic_string_view v, size_type pos = npos) const nssv_noexcept // (1) + { + if (size() < v.size()) + { + return npos; + } + + if (v.empty()) + { + return (std::min)(size(), pos); + } + + const_iterator last = cbegin() + (std::min)(size() - v.size(), pos) + v.size(); + const_iterator result = std::find_end(cbegin(), last, v.cbegin(), v.cend(), Traits::eq); + + return result != last ? size_type(result - cbegin()) : npos; + } + + nssv_constexpr14 size_type rfind(CharT c, size_type pos = npos) const nssv_noexcept // (2) + { + return rfind(basic_string_view(&c, 1), pos); + } + + nssv_constexpr14 size_type rfind(CharT const* s, size_type pos, size_type n) const // (3) + { + return rfind(basic_string_view(s, n), pos); + } + + nssv_constexpr14 size_type rfind(CharT const* s, size_type pos = npos) const // (4) + { + return rfind(basic_string_view(s), pos); + } + + // find_first_of(), 4x: + + nssv_constexpr size_type find_first_of(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) + { + return pos >= size() + ? npos + : to_pos(std::find_first_of(cbegin() + pos, cend(), v.cbegin(), v.cend(), Traits::eq)); + } + + nssv_constexpr size_type find_first_of(CharT c, size_type pos = 0) const nssv_noexcept // (2) + { + return find_first_of(basic_string_view(&c, 1), pos); + } + + nssv_constexpr size_type find_first_of(CharT const* s, size_type pos, size_type n) const // (3) + { + return find_first_of(basic_string_view(s, n), pos); + } + + nssv_constexpr size_type find_first_of(CharT const* s, size_type pos = 0) const // (4) + { + return find_first_of(basic_string_view(s), pos); + } + + // find_last_of(), 4x: + + nssv_constexpr size_type find_last_of(basic_string_view v, size_type pos = npos) const nssv_noexcept // (1) + { + return empty() + ? npos + : pos >= size() + ? find_last_of(v, size() - 1) + : to_pos(std::find_first_of(const_reverse_iterator(cbegin() + pos + 1), crend(), v.cbegin(), v.cend(), Traits::eq)); + } + + nssv_constexpr size_type find_last_of(CharT c, size_type pos = npos) const nssv_noexcept // (2) + { + return find_last_of(basic_string_view(&c, 1), pos); + } + + nssv_constexpr size_type find_last_of(CharT const* s, size_type pos, size_type count) const // (3) + { + return find_last_of(basic_string_view(s, count), pos); + } + + nssv_constexpr size_type find_last_of(CharT const* s, size_type pos = npos) const // (4) + { + return find_last_of(basic_string_view(s), pos); + } + + // find_first_not_of(), 4x: + + nssv_constexpr size_type find_first_not_of(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) + { + return pos >= size() + ? npos + : to_pos(std::find_if(cbegin() + pos, cend(), not_in_view(v))); + } + + nssv_constexpr size_type find_first_not_of(CharT c, size_type pos = 0) const nssv_noexcept // (2) + { + return find_first_not_of(basic_string_view(&c, 1), pos); + } + + nssv_constexpr size_type find_first_not_of(CharT const* s, size_type pos, size_type count) const // (3) + { + return find_first_not_of(basic_string_view(s, count), pos); + } + + nssv_constexpr size_type find_first_not_of(CharT const* s, size_type pos = 0) const // (4) + { + return find_first_not_of(basic_string_view(s), pos); + } + + // find_last_not_of(), 4x: + + nssv_constexpr size_type find_last_not_of(basic_string_view v, size_type pos = npos) const nssv_noexcept // (1) + { + return empty() + ? npos + : pos >= size() + ? find_last_not_of(v, size() - 1) + : to_pos(std::find_if(const_reverse_iterator(cbegin() + pos + 1), crend(), not_in_view(v))); + } + + nssv_constexpr size_type find_last_not_of(CharT c, size_type pos = npos) const nssv_noexcept // (2) + { + return find_last_not_of(basic_string_view(&c, 1), pos); + } + + nssv_constexpr size_type find_last_not_of(CharT const* s, size_type pos, size_type count) const // (3) + { + return find_last_not_of(basic_string_view(s, count), pos); + } + + nssv_constexpr size_type find_last_not_of(CharT const* s, size_type pos = npos) const // (4) + { + return find_last_not_of(basic_string_view(s), pos); + } + + // Constants: + +#if nssv_CPP17_OR_GREATER + static nssv_constexpr size_type npos = size_type(-1); +#elif nssv_CPP11_OR_GREATER + enum : size_type { npos = size_type(-1) }; +#else + enum { npos = size_type(-1) }; +#endif + + private: + struct not_in_view + { + const basic_string_view v; + + nssv_constexpr explicit not_in_view(basic_string_view v_) : v(v_) {} + + nssv_constexpr bool operator()(CharT c) const + { + return npos == v.find_first_of(c); + } + }; + + nssv_constexpr size_type to_pos(const_iterator it) const + { + return it == cend() ? npos : size_type(it - cbegin()); + } + + nssv_constexpr size_type to_pos(const_reverse_iterator it) const + { + return it == crend() ? npos : size_type(crend() - it - 1); + } + + nssv_constexpr const_reference data_at(size_type pos) const + { +#if nssv_BETWEEN( nssv_COMPILER_GNUC_VERSION, 1, 500 ) + return data_[pos]; +#else + return assert(pos < size()), data_[pos]; +#endif + } + + private: + const_pointer data_; + size_type size_; + + public: +#if nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS + + template< class Allocator > + basic_string_view(std::basic_string const& s) nssv_noexcept + : data_(s.data()) + , size_(s.size()) + {} + +#if nssv_HAVE_EXPLICIT_CONVERSION + + template< class Allocator > + explicit operator std::basic_string() const + { + return to_string(Allocator()); + } + +#endif // nssv_HAVE_EXPLICIT_CONVERSION + +#if nssv_CPP11_OR_GREATER + + template< class Allocator = std::allocator > + std::basic_string + to_string(Allocator const& a = Allocator()) const + { + return std::basic_string(begin(), end(), a); + } + +#else + + std::basic_string + to_string() const + { + return std::basic_string(begin(), end()); + } + + template< class Allocator > + std::basic_string + to_string(Allocator const& a) const + { + return std::basic_string(begin(), end(), a); + } + +#endif // nssv_CPP11_OR_GREATER + +#endif // nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS + }; + + // + // Non-member functions: + // + + // 24.4.3 Non-member comparison functions: + // lexicographically compare two string views (function template): + + template< class CharT, class Traits > + nssv_constexpr bool operator== ( + basic_string_view lhs, + basic_string_view rhs) nssv_noexcept + { + return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; + } + + template< class CharT, class Traits > + nssv_constexpr bool operator!= ( + basic_string_view lhs, + basic_string_view rhs) nssv_noexcept + { + return !(lhs == rhs); + } + + template< class CharT, class Traits > + nssv_constexpr bool operator< ( + basic_string_view lhs, + basic_string_view rhs) nssv_noexcept + { + return lhs.compare(rhs) < 0; + } + + template< class CharT, class Traits > + nssv_constexpr bool operator<= ( + basic_string_view lhs, + basic_string_view rhs) nssv_noexcept + { + return lhs.compare(rhs) <= 0; + } + + template< class CharT, class Traits > + nssv_constexpr bool operator> ( + basic_string_view lhs, + basic_string_view rhs) nssv_noexcept + { + return lhs.compare(rhs) > 0; + } + + template< class CharT, class Traits > + nssv_constexpr bool operator>= ( + basic_string_view lhs, + basic_string_view rhs) nssv_noexcept + { + return lhs.compare(rhs) >= 0; + } + + // Let S be basic_string_view, and sv be an instance of S. + // Implementations shall provide sufficient additional overloads marked + // constexpr and noexcept so that an object t with an implicit conversion + // to S can be compared according to Table 67. + +#if ! nssv_CPP11_OR_GREATER || nssv_BETWEEN( nssv_COMPILER_MSVC_VERSION, 100, 141 ) + +// accommodate for older compilers: + +// == + + template< class CharT, class Traits> + nssv_constexpr bool operator==( + basic_string_view lhs, + CharT const* rhs) nssv_noexcept + { + return lhs.size() == detail::length(rhs) && lhs.compare(rhs) == 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator==( + CharT const* lhs, + basic_string_view rhs) nssv_noexcept + { + return detail::length(lhs) == rhs.size() && rhs.compare(lhs) == 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator==( + basic_string_view lhs, + std::basic_string rhs) nssv_noexcept + { + return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator==( + std::basic_string rhs, + basic_string_view lhs) nssv_noexcept + { + return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; + } + + // != + + template< class CharT, class Traits> + nssv_constexpr bool operator!=( + basic_string_view lhs, + CharT const* rhs) nssv_noexcept + { + return !(lhs == rhs); + } + + template< class CharT, class Traits> + nssv_constexpr bool operator!=( + CharT const* lhs, + basic_string_view rhs) nssv_noexcept + { + return !(lhs == rhs); + } + + template< class CharT, class Traits> + nssv_constexpr bool operator!=( + basic_string_view lhs, + std::basic_string rhs) nssv_noexcept + { + return !(lhs == rhs); + } + + template< class CharT, class Traits> + nssv_constexpr bool operator!=( + std::basic_string rhs, + basic_string_view lhs) nssv_noexcept + { + return !(lhs == rhs); + } + + // < + + template< class CharT, class Traits> + nssv_constexpr bool operator<( + basic_string_view lhs, + CharT const* rhs) nssv_noexcept + { + return lhs.compare(rhs) < 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator<( + CharT const* lhs, + basic_string_view rhs) nssv_noexcept + { + return rhs.compare(lhs) > 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator<( + basic_string_view lhs, + std::basic_string rhs) nssv_noexcept + { + return lhs.compare(rhs) < 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator<( + std::basic_string rhs, + basic_string_view lhs) nssv_noexcept + { + return rhs.compare(lhs) > 0; + } + + // <= + + template< class CharT, class Traits> + nssv_constexpr bool operator<=( + basic_string_view lhs, + CharT const* rhs) nssv_noexcept + { + return lhs.compare(rhs) <= 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator<=( + CharT const* lhs, + basic_string_view rhs) nssv_noexcept + { + return rhs.compare(lhs) >= 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator<=( + basic_string_view lhs, + std::basic_string rhs) nssv_noexcept + { + return lhs.compare(rhs) <= 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator<=( + std::basic_string rhs, + basic_string_view lhs) nssv_noexcept + { + return rhs.compare(lhs) >= 0; + } + + // > + + template< class CharT, class Traits> + nssv_constexpr bool operator>( + basic_string_view lhs, + CharT const* rhs) nssv_noexcept + { + return lhs.compare(rhs) > 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator>( + CharT const* lhs, + basic_string_view rhs) nssv_noexcept + { + return rhs.compare(lhs) < 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator>( + basic_string_view lhs, + std::basic_string rhs) nssv_noexcept + { + return lhs.compare(rhs) > 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator>( + std::basic_string rhs, + basic_string_view lhs) nssv_noexcept + { + return rhs.compare(lhs) < 0; + } + + // >= + + template< class CharT, class Traits> + nssv_constexpr bool operator>=( + basic_string_view lhs, + CharT const* rhs) nssv_noexcept + { + return lhs.compare(rhs) >= 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator>=( + CharT const* lhs, + basic_string_view rhs) nssv_noexcept + { + return rhs.compare(lhs) <= 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator>=( + basic_string_view lhs, + std::basic_string rhs) nssv_noexcept + { + return lhs.compare(rhs) >= 0; + } + + template< class CharT, class Traits> + nssv_constexpr bool operator>=( + std::basic_string rhs, + basic_string_view lhs) nssv_noexcept + { + return rhs.compare(lhs) <= 0; + } + +#else // newer compilers: + +#define nssv_BASIC_STRING_VIEW_I(T,U) typename std::decay< basic_string_view >::type + +#if defined(_MSC_VER) // issue 40 +# define nssv_MSVC_ORDER(x) , int=x +#else +# define nssv_MSVC_ORDER(x) /*, int=x*/ +#endif + +// == + + template< class CharT, class Traits nssv_MSVC_ORDER(1) > + nssv_constexpr bool operator==( + basic_string_view lhs, + nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept + { + return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; + } + + template< class CharT, class Traits nssv_MSVC_ORDER(2) > + nssv_constexpr bool operator==( + nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, + basic_string_view rhs) nssv_noexcept + { + return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; + } + + // != + + template< class CharT, class Traits nssv_MSVC_ORDER(1) > + nssv_constexpr bool operator!= ( + basic_string_view < CharT, Traits > lhs, + nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept + { + return !(lhs == rhs); + } + + template< class CharT, class Traits nssv_MSVC_ORDER(2) > + nssv_constexpr bool operator!= ( + nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, + basic_string_view < CharT, Traits > rhs) nssv_noexcept + { + return !(lhs == rhs); + } + + // < + + template< class CharT, class Traits nssv_MSVC_ORDER(1) > + nssv_constexpr bool operator< ( + basic_string_view < CharT, Traits > lhs, + nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept + { + return lhs.compare(rhs) < 0; + } + + template< class CharT, class Traits nssv_MSVC_ORDER(2) > + nssv_constexpr bool operator< ( + nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, + basic_string_view < CharT, Traits > rhs) nssv_noexcept + { + return lhs.compare(rhs) < 0; + } + + // <= + + template< class CharT, class Traits nssv_MSVC_ORDER(1) > + nssv_constexpr bool operator<= ( + basic_string_view < CharT, Traits > lhs, + nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept + { + return lhs.compare(rhs) <= 0; + } + + template< class CharT, class Traits nssv_MSVC_ORDER(2) > + nssv_constexpr bool operator<= ( + nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, + basic_string_view < CharT, Traits > rhs) nssv_noexcept + { + return lhs.compare(rhs) <= 0; + } + + // > + + template< class CharT, class Traits nssv_MSVC_ORDER(1) > + nssv_constexpr bool operator> ( + basic_string_view < CharT, Traits > lhs, + nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept + { + return lhs.compare(rhs) > 0; + } + + template< class CharT, class Traits nssv_MSVC_ORDER(2) > + nssv_constexpr bool operator> ( + nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, + basic_string_view < CharT, Traits > rhs) nssv_noexcept + { + return lhs.compare(rhs) > 0; + } + + // >= + + template< class CharT, class Traits nssv_MSVC_ORDER(1) > + nssv_constexpr bool operator>= ( + basic_string_view < CharT, Traits > lhs, + nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept + { + return lhs.compare(rhs) >= 0; + } + + template< class CharT, class Traits nssv_MSVC_ORDER(2) > + nssv_constexpr bool operator>= ( + nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, + basic_string_view < CharT, Traits > rhs) nssv_noexcept + { + return lhs.compare(rhs) >= 0; + } + +#undef nssv_MSVC_ORDER +#undef nssv_BASIC_STRING_VIEW_I + +#endif // compiler-dependent approach to comparisons + + // 24.4.4 Inserters and extractors: + +#if ! nssv_CONFIG_NO_STREAM_INSERTION + + namespace detail { + + template< class Stream > + void write_padding(Stream& os, std::streamsize n) + { + for (std::streamsize i = 0; i < n; ++i) + os.rdbuf()->sputc(os.fill()); + } + + template< class Stream, class View > + Stream& write_to_stream(Stream& os, View const& sv) + { + typename Stream::sentry sentry(os); + + if (!sentry) + return os; + + const std::streamsize length = static_cast(sv.length()); + + // Whether, and how, to pad: + const bool pad = (length < os.width()); + const bool left_pad = pad && (os.flags() & std::ios_base::adjustfield) == std::ios_base::right; + + if (left_pad) + write_padding(os, os.width() - length); + + // Write span characters: + os.rdbuf()->sputn(sv.begin(), length); + + if (pad && !left_pad) + write_padding(os, os.width() - length); + + // Reset output stream width: + os.width(0); + + return os; + } + + } // namespace detail + + template< class CharT, class Traits > + std::basic_ostream& + operator<<( + std::basic_ostream& os, + basic_string_view sv) + { + return detail::write_to_stream(os, sv); + } + +#endif // nssv_CONFIG_NO_STREAM_INSERTION + + // Several typedefs for common character types are provided: + + typedef basic_string_view string_view; + typedef basic_string_view wstring_view; +#if nssv_HAVE_WCHAR16_T + typedef basic_string_view u16string_view; + typedef basic_string_view u32string_view; +#endif + + } +} // namespace nonstd::sv_lite + +// +// 24.4.6 Suffix for basic_string_view literals: +// + +#if nssv_HAVE_USER_DEFINED_LITERALS + +namespace nonstd { + nssv_inline_ns namespace literals { + nssv_inline_ns namespace string_view_literals { + +#if nssv_CONFIG_STD_SV_OPERATOR && nssv_HAVE_STD_DEFINED_LITERALS + + nssv_constexpr nonstd::sv_lite::string_view operator "" sv(const char* str, size_t len) nssv_noexcept // (1) + { + return nonstd::sv_lite::string_view{ str, len }; + } + + nssv_constexpr nonstd::sv_lite::u16string_view operator "" sv(const char16_t* str, size_t len) nssv_noexcept // (2) + { + return nonstd::sv_lite::u16string_view{ str, len }; + } + + nssv_constexpr nonstd::sv_lite::u32string_view operator "" sv(const char32_t* str, size_t len) nssv_noexcept // (3) + { + return nonstd::sv_lite::u32string_view{ str, len }; + } + + nssv_constexpr nonstd::sv_lite::wstring_view operator "" sv(const wchar_t* str, size_t len) nssv_noexcept // (4) + { + return nonstd::sv_lite::wstring_view{ str, len }; + } + +#endif // nssv_CONFIG_STD_SV_OPERATOR && nssv_HAVE_STD_DEFINED_LITERALS + +#if nssv_CONFIG_USR_SV_OPERATOR + + nssv_constexpr nonstd::sv_lite::string_view operator "" _sv(const char* str, size_t len) nssv_noexcept // (1) + { + return nonstd::sv_lite::string_view{ str, len }; + } + + nssv_constexpr nonstd::sv_lite::u16string_view operator "" _sv(const char16_t* str, size_t len) nssv_noexcept // (2) + { + return nonstd::sv_lite::u16string_view{ str, len }; + } + + nssv_constexpr nonstd::sv_lite::u32string_view operator "" _sv(const char32_t* str, size_t len) nssv_noexcept // (3) + { + return nonstd::sv_lite::u32string_view{ str, len }; + } + + nssv_constexpr nonstd::sv_lite::wstring_view operator "" _sv(const wchar_t* str, size_t len) nssv_noexcept // (4) + { + return nonstd::sv_lite::wstring_view{ str, len }; + } + +#endif // nssv_CONFIG_USR_SV_OPERATOR + + } + } +} // namespace nonstd::literals::string_view_literals + +#endif + +// +// Extensions for std::string: +// + +#if nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS + +namespace nonstd { + namespace sv_lite { + + // Exclude MSVC 14 (19.00): it yields ambiguous to_string(): + +#if nssv_CPP11_OR_GREATER && nssv_COMPILER_MSVC_VERSION != 140 + + template< class CharT, class Traits, class Allocator = std::allocator > + std::basic_string + to_string(basic_string_view v, Allocator const& a = Allocator()) + { + return std::basic_string(v.begin(), v.end(), a); + } + +#else + + template< class CharT, class Traits > + std::basic_string + to_string(basic_string_view v) + { + return std::basic_string(v.begin(), v.end()); + } + + template< class CharT, class Traits, class Allocator > + std::basic_string + to_string(basic_string_view v, Allocator const& a) + { + return std::basic_string(v.begin(), v.end(), a); + } + +#endif // nssv_CPP11_OR_GREATER + + template< class CharT, class Traits, class Allocator > + basic_string_view + to_string_view(std::basic_string const& s) + { + return basic_string_view(s.data(), s.size()); + } + + } +} // namespace nonstd::sv_lite + +#endif // nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS + +// +// make types and algorithms available in namespace nonstd: +// + +namespace nonstd { + + using sv_lite::basic_string_view; + using sv_lite::string_view; + using sv_lite::wstring_view; + +#if nssv_HAVE_WCHAR16_T + using sv_lite::u16string_view; +#endif +#if nssv_HAVE_WCHAR32_T + using sv_lite::u32string_view; +#endif + + // literal "sv" + + using sv_lite::operator==; + using sv_lite::operator!=; + using sv_lite::operator<; + using sv_lite::operator<=; + using sv_lite::operator>; + using sv_lite::operator>=; + +#if ! nssv_CONFIG_NO_STREAM_INSERTION + using sv_lite::operator<<; +#endif + +#if nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS + using sv_lite::to_string; + using sv_lite::to_string_view; +#endif + +} // namespace nonstd + +// 24.4.5 Hash support (C++11): + +// Note: The hash value of a string view object is equal to the hash value of +// the corresponding string object. + +#if nssv_HAVE_STD_HASH + +#include + +namespace std { + + template<> + struct hash< nonstd::string_view > + { + public: + std::size_t operator()(nonstd::string_view v) const nssv_noexcept + { + return std::hash()(std::string(v.data(), v.size())); + } + }; + + template<> + struct hash< nonstd::wstring_view > + { + public: + std::size_t operator()(nonstd::wstring_view v) const nssv_noexcept + { + return std::hash()(std::wstring(v.data(), v.size())); + } + }; + + template<> + struct hash< nonstd::u16string_view > + { + public: + std::size_t operator()(nonstd::u16string_view v) const nssv_noexcept + { + return std::hash()(std::u16string(v.data(), v.size())); + } + }; + + template<> + struct hash< nonstd::u32string_view > + { + public: + std::size_t operator()(nonstd::u32string_view v) const nssv_noexcept + { + return std::hash()(std::u32string(v.data(), v.size())); + } + }; + +} // namespace std + +#endif // nssv_HAVE_STD_HASH + +nssv_RESTORE_WARNINGS() + +#endif // nssv_HAVE_STD_STRING_VIEW +#endif // NONSTD_SV_LITE_H_INCLUDED +/* end file simdjson/nonstd/string_view.hpp */ +SIMDJSON_POP_DISABLE_WARNINGS + +namespace std { + using string_view = nonstd::string_view; +} +#endif // SIMDJSON_HAS_STRING_VIEW +#undef SIMDJSON_HAS_STRING_VIEW // We are not going to need this macro anymore. + +/// If EXPR is an error, returns it. +#define SIMDJSON_TRY(EXPR) { auto _err = (EXPR); if (_err) { return _err; } } + +// Unless the programmer has already set SIMDJSON_DEVELOPMENT_CHECKS, +// we want to set it under debug builds. We detect a debug build +// under Visual Studio when the _DEBUG macro is set. Under the other +// compilers, we use the fact that they define __OPTIMIZE__ whenever +// they allow optimizations. +// It is possible that this could miss some cases where SIMDJSON_DEVELOPMENT_CHECKS +// is helpful, but the programmer can set the macro SIMDJSON_DEVELOPMENT_CHECKS. +// It could also wrongly set SIMDJSON_DEVELOPMENT_CHECKS (e.g., if the programmer +// sets _DEBUG in a release build under Visual Studio, or if some compiler fails to +// set the __OPTIMIZE__ macro). +#ifndef SIMDJSON_DEVELOPMENT_CHECKS +#ifdef _MSC_VER +// Visual Studio seems to set _DEBUG for debug builds. +#ifdef _DEBUG +#define SIMDJSON_DEVELOPMENT_CHECKS 1 +#endif // _DEBUG +#else // _MSC_VER +// All other compilers appear to set __OPTIMIZE__ to a positive integer +// when the compiler is optimizing. +#ifndef __OPTIMIZE__ +#define SIMDJSON_DEVELOPMENT_CHECKS 1 +#endif // __OPTIMIZE__ +#endif // _MSC_VER +#endif // SIMDJSON_DEVELOPMENT_CHECKS + +// The SIMDJSON_CHECK_EOF macro is a feature flag for the "don't require padding" +// feature. + +#if SIMDJSON_CPLUSPLUS17 +// if we have C++, then fallthrough is a default attribute +# define simdjson_fallthrough [[fallthrough]] +// check if we have __attribute__ support +#elif defined(__has_attribute) +// check if we have the __fallthrough__ attribute +#if __has_attribute(__fallthrough__) +// we are good to go: +# define simdjson_fallthrough __attribute__((__fallthrough__)) +#endif // __has_attribute(__fallthrough__) +#endif // SIMDJSON_CPLUSPLUS17 +// on some systems, we simply do not have support for fallthrough, so use a default: +#ifndef simdjson_fallthrough +# define simdjson_fallthrough do {} while (0) /* fallthrough */ +#endif // simdjson_fallthrough + +#if SIMDJSON_DEVELOPMENT_CHECKS +#define SIMDJSON_DEVELOPMENT_ASSERT(expr) do { assert ((expr)); } while (0) +#else +#define SIMDJSON_DEVELOPMENT_ASSERT(expr) do { } while (0) +#endif + +#ifndef SIMDJSON_UTF8VALIDATION +#define SIMDJSON_UTF8VALIDATION 1 +#endif + +#ifdef __has_include +// How do we detect that a compiler supports vbmi2? +// For sure if the following header is found, we are ok? +#if __has_include() +#define SIMDJSON_COMPILER_SUPPORTS_VBMI2 1 +#endif +#endif + +#ifdef _MSC_VER +#if _MSC_VER >= 1920 +// Visual Studio 2019 and up support VBMI2 under x64 even if the header +// avx512vbmi2intrin.h is not found. +#define SIMDJSON_COMPILER_SUPPORTS_VBMI2 1 +#endif +#endif + +// By default, we allow AVX512. +#ifndef SIMDJSON_AVX512_ALLOWED +#define SIMDJSON_AVX512_ALLOWED 1 +#endif + +#endif // SIMDJSON_COMMON_DEFS_H +/* end file simdjson/common_defs.h */ +/* skipped duplicate #include "simdjson/compiler_check.h" */ +/* including simdjson/error.h: #include "simdjson/error.h" */ +/* begin file simdjson/error.h */ +#ifndef SIMDJSON_ERROR_H +#define SIMDJSON_ERROR_H + +/* skipped duplicate #include "simdjson/base.h" */ + +#include +#include + +namespace simdjson { + + /** + * All possible errors returned by simdjson. These error codes are subject to change + * and not all simdjson kernel returns the same error code given the same input: it is not + * well defined which error a given input should produce. + * + * Only SUCCESS evaluates to false as a Boolean. All other error codes will evaluate + * to true as a Boolean. + */ + enum error_code { + SUCCESS = 0, ///< No error + CAPACITY, ///< This parser can't support a document that big + MEMALLOC, ///< Error allocating memory, most likely out of memory + TAPE_ERROR, ///< Something went wrong, this is a generic error + DEPTH_ERROR, ///< Your document exceeds the user-specified depth limitation + STRING_ERROR, ///< Problem while parsing a string + T_ATOM_ERROR, ///< Problem while parsing an atom starting with the letter 't' + F_ATOM_ERROR, ///< Problem while parsing an atom starting with the letter 'f' + N_ATOM_ERROR, ///< Problem while parsing an atom starting with the letter 'n' + NUMBER_ERROR, ///< Problem while parsing a number + UTF8_ERROR, ///< the input is not valid UTF-8 + UNINITIALIZED, ///< unknown error, or uninitialized document + EMPTY, ///< no structural element found + UNESCAPED_CHARS, ///< found unescaped characters in a string. + UNCLOSED_STRING, ///< missing quote at the end + UNSUPPORTED_ARCHITECTURE, ///< unsupported architecture + INCORRECT_TYPE, ///< JSON element has a different type than user expected + NUMBER_OUT_OF_RANGE, ///< JSON number does not fit in 64 bits + INDEX_OUT_OF_BOUNDS, ///< JSON array index too large + NO_SUCH_FIELD, ///< JSON field not found in object + IO_ERROR, ///< Error reading a file + INVALID_JSON_POINTER, ///< Invalid JSON pointer reference + INVALID_URI_FRAGMENT, ///< Invalid URI fragment + UNEXPECTED_ERROR, ///< indicative of a bug in simdjson + PARSER_IN_USE, ///< parser is already in use. + OUT_OF_ORDER_ITERATION, ///< tried to iterate an array or object out of order (checked when SIMDJSON_DEVELOPMENT_CHECKS=1) + INSUFFICIENT_PADDING, ///< The JSON doesn't have enough padding for simdjson to safely parse it. + INCOMPLETE_ARRAY_OR_OBJECT, ///< The document ends early. + SCALAR_DOCUMENT_AS_VALUE, ///< A scalar document is treated as a value. + OUT_OF_BOUNDS, ///< Attempted to access location outside of document. + TRAILING_CONTENT, ///< Unexpected trailing content in the JSON input + NUM_ERROR_CODES + }; + + /** + * It is the convention throughout the code that the macro SIMDJSON_DEVELOPMENT_CHECKS determines whether + * we check for OUT_OF_ORDER_ITERATION. The logic behind it is that these errors only occurs when the code + * that was written while breaking some simdjson::ondemand requirement. They should not occur in released + * code after these issues were fixed. + */ + + /** + * Get the error message for the given error code. + * + * dom::parser parser; + * dom::element doc; + * auto error = parser.parse("foo",3).get(doc); + * if (error) { printf("Error: %s\n", error_message(error)); } + * + * @return The error message. + */ + inline const char* error_message(error_code error) noexcept; + + /** + * Write the error message to the output stream + */ + inline std::ostream& operator<<(std::ostream& out, error_code error) noexcept; + + /** + * Exception thrown when an exception-supporting simdjson method is called + */ + struct simdjson_error : public std::exception { + /** + * Create an exception from a simdjson error code. + * @param error The error code + */ + simdjson_error(error_code error) noexcept : _error{ error } { } + /** The error message */ + const char* what() const noexcept { return error_message(error()); } + /** The error code */ + error_code error() const noexcept { return _error; } + private: + /** The error code that was used */ + error_code _error; + }; + + namespace internal { + + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::simdjson_result_base { + * simdjson_result() noexcept : internal::simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct simdjson_result_base : protected std::pair { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline simdjson_result_base() noexcept; + + /** + * Create a new error result. + */ + simdjson_inline simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + + }; // struct simdjson_result_base + + } // namespace internal + + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + */ + template + struct simdjson_result : public internal::simdjson_result_base { + /** + * @private Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline simdjson_result() noexcept; + /** + * @private Create a new successful result. + */ + simdjson_inline simdjson_result(T&& value) noexcept; + /** + * @private Create a new error result. + */ + simdjson_inline simdjson_result(error_code error_code) noexcept; + /** + * @private Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline simdjson_result(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_warn_unused simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + + }; // struct simdjson_result + +#if SIMDJSON_EXCEPTIONS + + template + inline std::ostream& operator<<(std::ostream& out, simdjson_result value) { return out << value.value(); } +#endif // SIMDJSON_EXCEPTIONS + +#ifndef SIMDJSON_DISABLE_DEPRECATED_API + /** + * @deprecated This is an alias and will be removed, use error_code instead + */ + using ErrorValues [[deprecated("This is an alias and will be removed, use error_code instead")]] = error_code; + + /** + * @deprecated Error codes should be stored and returned as `error_code`, use `error_message()` instead. + */ + [[deprecated("Error codes should be stored and returned as `error_code`, use `error_message()` instead.")]] + inline const std::string error_message(int error) noexcept; +#endif // SIMDJSON_DISABLE_DEPRECATED_API +} // namespace simdjson + +#endif // SIMDJSON_ERROR_H +/* end file simdjson/error.h */ +/* skipped duplicate #include "simdjson/portability.h" */ + +/** + * @brief The top level simdjson namespace, containing everything the library provides. + */ +namespace simdjson { + + SIMDJSON_PUSH_DISABLE_UNUSED_WARNINGS + + /** The maximum document size supported by simdjson. */ + constexpr size_t SIMDJSON_MAXSIZE_BYTES = 0xFFFFFFFF; + + /** + * The amount of padding needed in a buffer to parse JSON. + * + * The input buf should be readable up to buf + SIMDJSON_PADDING + * this is a stopgap; there should be a better description of the + * main loop and its behavior that abstracts over this + * See https://github.com/simdjson/simdjson/issues/174 + */ + constexpr size_t SIMDJSON_PADDING = 64; + + /** + * By default, simdjson supports this many nested objects and arrays. + * + * This is the default for parser::max_depth(). + */ + constexpr size_t DEFAULT_MAX_DEPTH = 1024; + + SIMDJSON_POP_DISABLE_UNUSED_WARNINGS + + class implementation; + struct padded_string; + class padded_string_view; + enum class stage1_mode; + + namespace internal { + + template + class atomic_ptr; + class dom_parser_implementation; + class escape_json_string; + class tape_ref; + struct value128; + enum class tape_type; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_BASE_H +/* end file simdjson/base.h */ + +#endif // SIMDJSON_SRC_BASE_H +/* end file base.h */ + +SIMDJSON_PUSH_DISABLE_UNUSED_WARNINGS + +/* including to_chars.cpp: #include */ +/* begin file to_chars.cpp */ +#ifndef SIMDJSON_SRC_TO_CHARS_CPP +#define SIMDJSON_SRC_TO_CHARS_CPP + +/* skipped duplicate #include */ -/* begin file src/to_chars.cpp */ #include #include #include @@ -965,9 +3724,20 @@ namespace simdjson { } } // namespace internal } // namespace simdjson -/* end file src/to_chars.cpp */ -/* begin file src/from_chars.cpp */ + +#endif // SIMDJSON_SRC_TO_CHARS_CPP +/* end file to_chars.cpp */ +/* including from_chars.cpp: #include */ +/* begin file from_chars.cpp */ +#ifndef SIMDJSON_SRC_FROM_CHARS_CPP +#define SIMDJSON_SRC_FROM_CHARS_CPP + +/* skipped duplicate #include */ + +#include +#include #include + namespace simdjson { namespace internal { @@ -1576,50 +4346,279 @@ namespace simdjson { } // internal } // simdjson -/* end file src/from_chars.cpp */ -/* begin file src/internal/error_tables.cpp */ + +#endif // SIMDJSON_SRC_FROM_CHARS_CPP +/* end file from_chars.cpp */ +/* including internal/error_tables.cpp: #include */ +/* begin file internal/error_tables.cpp */ +#ifndef SIMDJSON_SRC_ERROR_TABLES_CPP +#define SIMDJSON_SRC_ERROR_TABLES_CPP + +/* including simdjson/internal/jsoncharutils_tables.h: #include */ +/* begin file simdjson/internal/jsoncharutils_tables.h */ +#ifndef SIMDJSON_INTERNAL_JSONCHARUTILS_TABLES_H +#define SIMDJSON_INTERNAL_JSONCHARUTILS_TABLES_H + +/* skipped duplicate #include "simdjson/base.h" */ + +#ifdef JSON_TEST_STRINGS +void found_string(const uint8_t* buf, const uint8_t* parsed_begin, + const uint8_t* parsed_end); +void found_bad_string(const uint8_t* buf); +#endif + +namespace simdjson { + namespace internal { + // structural chars here are + // they are { 0x7b } 0x7d : 0x3a [ 0x5b ] 0x5d , 0x2c (and NULL) + // we are also interested in the four whitespace characters + // space 0x20, linefeed 0x0a, horizontal tab 0x09 and carriage return 0x0d + + extern SIMDJSON_DLLIMPORTEXPORT const bool structural_or_whitespace_negated[256]; + extern SIMDJSON_DLLIMPORTEXPORT const bool structural_or_whitespace[256]; + extern SIMDJSON_DLLIMPORTEXPORT const uint32_t digit_to_val32[886]; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_JSONCHARUTILS_TABLES_H +/* end file simdjson/internal/jsoncharutils_tables.h */ +/* including simdjson/error-inl.h: #include */ +/* begin file simdjson/error-inl.h */ +#ifndef SIMDJSON_ERROR_INL_H +#define SIMDJSON_ERROR_INL_H + +/* skipped duplicate #include "simdjson/error.h" */ + +#include + +namespace simdjson { + namespace internal { + // We store the error code so we can validate the error message is associated with the right code + struct error_code_info { + error_code code; + const char* message; // do not use a fancy std::string where a simple C string will do (no alloc, no destructor) + }; + // These MUST match the codes in error_code. We check this constraint in basictests. + extern SIMDJSON_DLLIMPORTEXPORT const error_code_info error_codes[]; + } // namespace internal + + + inline const char* error_message(error_code error) noexcept { + // If you're using error_code, we're trusting you got it from the enum. + return internal::error_codes[int(error)].message; + } + + // deprecated function +#ifndef SIMDJSON_DISABLE_DEPRECATED_API + inline const std::string error_message(int error) noexcept { + if (error < 0 || error >= error_code::NUM_ERROR_CODES) { + return internal::error_codes[UNEXPECTED_ERROR].message; + } + return internal::error_codes[error].message; + } +#endif // SIMDJSON_DISABLE_DEPRECATED_API + + inline std::ostream& operator<<(std::ostream& out, error_code error) noexcept { + return out << error_message(error); + } + + namespace internal { + + // + // internal::simdjson_result_base inline implementation + // + + template + simdjson_inline void simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T&& simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline simdjson_result_base::simdjson_result_base(T&& value, error_code error) noexcept + : std::pair(std::forward(value), error) {} + template + simdjson_inline simdjson_result_base::simdjson_result_base(error_code error) noexcept + : simdjson_result_base(T{}, error) {} + template + simdjson_inline simdjson_result_base::simdjson_result_base(T&& value) noexcept + : simdjson_result_base(std::forward(value), SUCCESS) {} + template + simdjson_inline simdjson_result_base::simdjson_result_base() noexcept + : simdjson_result_base(T{}, UNINITIALIZED) {} + + } // namespace internal + + /// + /// simdjson_result inline implementation + /// + + template + simdjson_inline void simdjson_result::tie(T& value, error_code& error) && noexcept { + std::forward>(*this).tie(value, error); + } + + template + simdjson_warn_unused simdjson_inline error_code simdjson_result::get(T& value) && noexcept { + return std::forward>(*this).get(value); + } + + template + simdjson_inline error_code simdjson_result::error() const noexcept { + return internal::simdjson_result_base::error(); + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& simdjson_result::value() & noexcept(false) { + return internal::simdjson_result_base::value(); + } + + template + simdjson_inline T&& simdjson_result::value() && noexcept(false) { + return std::forward>(*this).value(); + } + + template + simdjson_inline T&& simdjson_result::take_value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline simdjson_result::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& simdjson_result::value_unsafe() const& noexcept { + return internal::simdjson_result_base::value_unsafe(); + } + + template + simdjson_inline T&& simdjson_result::value_unsafe() && noexcept { + return std::forward>(*this).value_unsafe(); + } + + template + simdjson_inline simdjson_result::simdjson_result(T&& value, error_code error) noexcept + : internal::simdjson_result_base(std::forward(value), error) {} + template + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : internal::simdjson_result_base(error) {} + template + simdjson_inline simdjson_result::simdjson_result(T&& value) noexcept + : internal::simdjson_result_base(std::forward(value)) {} + template + simdjson_inline simdjson_result::simdjson_result() noexcept + : internal::simdjson_result_base() {} + +} // namespace simdjson + +#endif // SIMDJSON_ERROR_INL_H +/* end file simdjson/error-inl.h */ namespace simdjson { namespace internal { SIMDJSON_DLLIMPORTEXPORT const error_code_info error_codes[]{ - { SUCCESS, "No error" }, - { CAPACITY, "This parser can't support a document that big" }, - { MEMALLOC, "Error allocating memory, we're most likely out of memory" }, - { TAPE_ERROR, "The JSON document has an improper structure: missing or superfluous commas, braces, missing keys, etc." }, - { DEPTH_ERROR, "The JSON document was too deep (too many nested objects and arrays)" }, - { STRING_ERROR, "Problem while parsing a string" }, - { T_ATOM_ERROR, "Problem while parsing an atom starting with the letter 't'" }, - { F_ATOM_ERROR, "Problem while parsing an atom starting with the letter 'f'" }, - { N_ATOM_ERROR, "Problem while parsing an atom starting with the letter 'n'" }, - { NUMBER_ERROR, "Problem while parsing a number" }, - { UTF8_ERROR, "The input is not valid UTF-8" }, - { UNINITIALIZED, "Uninitialized" }, - { EMPTY, "Empty: no JSON found" }, - { UNESCAPED_CHARS, "Within strings, some characters must be escaped, we found unescaped characters" }, - { UNCLOSED_STRING, "A string is opened, but never closed." }, - { UNSUPPORTED_ARCHITECTURE, "simdjson does not have an implementation supported by this CPU architecture (perhaps it's a non-SIMD CPU?)." }, - { INCORRECT_TYPE, "The JSON element does not have the requested type." }, - { NUMBER_OUT_OF_RANGE, "The JSON number is too large or too small to fit within the requested type." }, - { INDEX_OUT_OF_BOUNDS, "Attempted to access an element of a JSON array that is beyond its length." }, - { NO_SUCH_FIELD, "The JSON field referenced does not exist in this object." }, - { IO_ERROR, "Error reading the file." }, - { INVALID_JSON_POINTER, "Invalid JSON pointer syntax." }, - { INVALID_URI_FRAGMENT, "Invalid URI fragment syntax." }, - { UNEXPECTED_ERROR, "Unexpected error, consider reporting this problem as you may have found a bug in simdjson" }, - { PARSER_IN_USE, "Cannot parse a new document while a document is still in use." }, - { OUT_OF_ORDER_ITERATION, "Objects and arrays can only be iterated when they are first encountered." }, - { INSUFFICIENT_PADDING, "simdjson requires the input JSON string to have at least SIMDJSON_PADDING extra bytes allocated, beyond the string's length. Consider using the simdjson::padded_string class if needed." }, - { INCOMPLETE_ARRAY_OR_OBJECT, "JSON document ended early in the middle of an object or array." }, - { SCALAR_DOCUMENT_AS_VALUE, "A JSON document made of a scalar (number, Boolean, null or string) is treated as a value. Use get_bool(), get_double(), etc. on the document instead. "}, - { OUT_OF_BOUNDS, "Attempted to access location outside of document."}, - { TRAILING_CONTENT, "Unexpected trailing content in the JSON input."} + { SUCCESS, "SUCCESS: No error" }, + { CAPACITY, "CAPACITY: This parser can't support a document that big" }, + { MEMALLOC, "MEMALLOC: Error allocating memory, we're most likely out of memory" }, + { TAPE_ERROR, "TAPE_ERROR: The JSON document has an improper structure: missing or superfluous commas, braces, missing keys, etc." }, + { DEPTH_ERROR, "DEPTH_ERROR: The JSON document was too deep (too many nested objects and arrays)" }, + { STRING_ERROR, "STRING_ERROR: Problem while parsing a string" }, + { T_ATOM_ERROR, "T_ATOM_ERROR: Problem while parsing an atom starting with the letter 't'" }, + { F_ATOM_ERROR, "F_ATOM_ERROR: Problem while parsing an atom starting with the letter 'f'" }, + { N_ATOM_ERROR, "N_ATOM_ERROR: Problem while parsing an atom starting with the letter 'n'" }, + { NUMBER_ERROR, "NUMBER_ERROR: Problem while parsing a number" }, + { UTF8_ERROR, "UTF8_ERROR: The input is not valid UTF-8" }, + { UNINITIALIZED, "UNINITIALIZED: Uninitialized" }, + { EMPTY, "EMPTY: no JSON found" }, + { UNESCAPED_CHARS, "UNESCAPED_CHARS: Within strings, some characters must be escaped, we found unescaped characters" }, + { UNCLOSED_STRING, "UNCLOSED_STRING: A string is opened, but never closed." }, + { UNSUPPORTED_ARCHITECTURE, "UNSUPPORTED_ARCHITECTURE: simdjson does not have an implementation supported by this CPU architecture. Please report this error to the core team as it should never happen." }, + { INCORRECT_TYPE, "INCORRECT_TYPE: The JSON element does not have the requested type." }, + { NUMBER_OUT_OF_RANGE, "NUMBER_OUT_OF_RANGE: The JSON number is too large or too small to fit within the requested type." }, + { INDEX_OUT_OF_BOUNDS, "INDEX_OUT_OF_BOUNDS: Attempted to access an element of a JSON array that is beyond its length." }, + { NO_SUCH_FIELD, "NO_SUCH_FIELD: The JSON field referenced does not exist in this object." }, + { IO_ERROR, "IO_ERROR: Error reading the file." }, + { INVALID_JSON_POINTER, "INVALID_JSON_POINTER: Invalid JSON pointer syntax." }, + { INVALID_URI_FRAGMENT, "INVALID_URI_FRAGMENT: Invalid URI fragment syntax." }, + { UNEXPECTED_ERROR, "UNEXPECTED_ERROR: Unexpected error, consider reporting this problem as you may have found a bug in simdjson" }, + { PARSER_IN_USE, "PARSER_IN_USE: Cannot parse a new document while a document is still in use." }, + { OUT_OF_ORDER_ITERATION, "OUT_OF_ORDER_ITERATION: Objects and arrays can only be iterated when they are first encountered." }, + { INSUFFICIENT_PADDING, "INSUFFICIENT_PADDING: simdjson requires the input JSON string to have at least SIMDJSON_PADDING extra bytes allocated, beyond the string's length. Consider using the simdjson::padded_string class if needed." }, + { INCOMPLETE_ARRAY_OR_OBJECT, "INCOMPLETE_ARRAY_OR_OBJECT: JSON document ended early in the middle of an object or array." }, + { SCALAR_DOCUMENT_AS_VALUE, "SCALAR_DOCUMENT_AS_VALUE: A JSON document made of a scalar (number, Boolean, null or string) is treated as a value. Use get_bool(), get_double(), etc. on the document instead. "}, + { OUT_OF_BOUNDS, "OUT_OF_BOUNDS: Attempt to access location outside of document."}, + { TRAILING_CONTENT, "TRAILING_CONTENT: Unexpected trailing content in the JSON input."} }; // error_messages[] } // namespace internal } // namespace simdjson -/* end file src/internal/error_tables.cpp */ -/* begin file src/internal/jsoncharutils_tables.cpp */ + +#endif // SIMDJSON_SRC_ERROR_TABLES_CPP +/* end file internal/error_tables.cpp */ +/* including internal/jsoncharutils_tables.cpp: #include */ +/* begin file internal/jsoncharutils_tables.cpp */ +#ifndef SIMDJSON_SRC_JSONCHARUTILS_TABLES_CPP +#define SIMDJSON_SRC_JSONCHARUTILS_TABLES_CPP + +/* skipped duplicate #include */ namespace simdjson { namespace internal { @@ -1811,17 +4810,55 @@ namespace simdjson { } // namespace internal } // namespace simdjson -/* end file src/internal/jsoncharutils_tables.cpp */ -/* begin file src/internal/numberparsing_tables.cpp */ + +#endif // SIMDJSON_SRC_JSONCHARUTILS_TABLES_CPP +/* end file internal/jsoncharutils_tables.cpp */ +/* including internal/numberparsing_tables.cpp: #include */ +/* begin file internal/numberparsing_tables.cpp */ +#ifndef SIMDJSON_SRC_NUMBERPARSING_TABLES_CPP +#define SIMDJSON_SRC_NUMBERPARSING_TABLES_CPP + +/* skipped duplicate #include */ +/* including simdjson/internal/numberparsing_tables.h: #include */ +/* begin file simdjson/internal/numberparsing_tables.h */ +#ifndef SIMDJSON_INTERNAL_NUMBERPARSING_TABLES_H +#define SIMDJSON_INTERNAL_NUMBERPARSING_TABLES_H + +/* skipped duplicate #include "simdjson/base.h" */ namespace simdjson { namespace internal { + /** + * The smallest non-zero float (binary64) is 2^-1074. + * We take as input numbers of the form w x 10^q where w < 2^64. + * We have that w * 10^-343 < 2^(64-344) 5^-343 < 2^-1076. + * However, we have that + * (2^64-1) * 10^-342 = (2^64-1) * 2^-342 * 5^-342 > 2^-1074. + * Thus it is possible for a number of the form w * 10^-342 where + * w is a 64-bit value to be a non-zero floating-point number. + ********* + * Any number of form w * 10^309 where w>= 1 is going to be + * infinite in binary64 so we never need to worry about powers + * of 5 greater than 308. + */ + constexpr int smallest_power = -342; + constexpr int largest_power = 308; + + /** + * Represents a 128-bit value. + * low: least significant 64 bits. + * high: most significant 64 bits. + */ + struct value128 { + uint64_t low; + uint64_t high; + }; + // Precomputed powers of ten from 10^0 to 10^22. These // can be represented exactly using the double type. - SIMDJSON_DLLIMPORTEXPORT const double power_of_ten[] = { - 1e0, 1e1, 1e2, 1e3, 1e4, 1e5, 1e6, 1e7, 1e8, 1e9, 1e10, 1e11, - 1e12, 1e13, 1e14, 1e15, 1e16, 1e17, 1e18, 1e19, 1e20, 1e21, 1e22 }; + extern SIMDJSON_DLLIMPORTEXPORT const double power_of_ten[]; + /** * When mapping numbers from decimal to binary, @@ -1838,663 +4875,810 @@ namespace simdjson { // The truncated powers of five from 5^-342 all the way to 5^308 // The mantissa is truncated to 128 bits, and // never rounded up. Uses about 10KB. - SIMDJSON_DLLIMPORTEXPORT const uint64_t power_of_five_128[] = { - 0xeef453d6923bd65a,0x113faa2906a13b3f, - 0x9558b4661b6565f8,0x4ac7ca59a424c507, - 0xbaaee17fa23ebf76,0x5d79bcf00d2df649, - 0xe95a99df8ace6f53,0xf4d82c2c107973dc, - 0x91d8a02bb6c10594,0x79071b9b8a4be869, - 0xb64ec836a47146f9,0x9748e2826cdee284, - 0xe3e27a444d8d98b7,0xfd1b1b2308169b25, - 0x8e6d8c6ab0787f72,0xfe30f0f5e50e20f7, - 0xb208ef855c969f4f,0xbdbd2d335e51a935, - 0xde8b2b66b3bc4723,0xad2c788035e61382, - 0x8b16fb203055ac76,0x4c3bcb5021afcc31, - 0xaddcb9e83c6b1793,0xdf4abe242a1bbf3d, - 0xd953e8624b85dd78,0xd71d6dad34a2af0d, - 0x87d4713d6f33aa6b,0x8672648c40e5ad68, - 0xa9c98d8ccb009506,0x680efdaf511f18c2, - 0xd43bf0effdc0ba48,0x212bd1b2566def2, - 0x84a57695fe98746d,0x14bb630f7604b57, - 0xa5ced43b7e3e9188,0x419ea3bd35385e2d, - 0xcf42894a5dce35ea,0x52064cac828675b9, - 0x818995ce7aa0e1b2,0x7343efebd1940993, - 0xa1ebfb4219491a1f,0x1014ebe6c5f90bf8, - 0xca66fa129f9b60a6,0xd41a26e077774ef6, - 0xfd00b897478238d0,0x8920b098955522b4, - 0x9e20735e8cb16382,0x55b46e5f5d5535b0, - 0xc5a890362fddbc62,0xeb2189f734aa831d, - 0xf712b443bbd52b7b,0xa5e9ec7501d523e4, - 0x9a6bb0aa55653b2d,0x47b233c92125366e, - 0xc1069cd4eabe89f8,0x999ec0bb696e840a, - 0xf148440a256e2c76,0xc00670ea43ca250d, - 0x96cd2a865764dbca,0x380406926a5e5728, - 0xbc807527ed3e12bc,0xc605083704f5ecf2, - 0xeba09271e88d976b,0xf7864a44c633682e, - 0x93445b8731587ea3,0x7ab3ee6afbe0211d, - 0xb8157268fdae9e4c,0x5960ea05bad82964, - 0xe61acf033d1a45df,0x6fb92487298e33bd, - 0x8fd0c16206306bab,0xa5d3b6d479f8e056, - 0xb3c4f1ba87bc8696,0x8f48a4899877186c, - 0xe0b62e2929aba83c,0x331acdabfe94de87, - 0x8c71dcd9ba0b4925,0x9ff0c08b7f1d0b14, - 0xaf8e5410288e1b6f,0x7ecf0ae5ee44dd9, - 0xdb71e91432b1a24a,0xc9e82cd9f69d6150, - 0x892731ac9faf056e,0xbe311c083a225cd2, - 0xab70fe17c79ac6ca,0x6dbd630a48aaf406, - 0xd64d3d9db981787d,0x92cbbccdad5b108, - 0x85f0468293f0eb4e,0x25bbf56008c58ea5, - 0xa76c582338ed2621,0xaf2af2b80af6f24e, - 0xd1476e2c07286faa,0x1af5af660db4aee1, - 0x82cca4db847945ca,0x50d98d9fc890ed4d, - 0xa37fce126597973c,0xe50ff107bab528a0, - 0xcc5fc196fefd7d0c,0x1e53ed49a96272c8, - 0xff77b1fcbebcdc4f,0x25e8e89c13bb0f7a, - 0x9faacf3df73609b1,0x77b191618c54e9ac, - 0xc795830d75038c1d,0xd59df5b9ef6a2417, - 0xf97ae3d0d2446f25,0x4b0573286b44ad1d, - 0x9becce62836ac577,0x4ee367f9430aec32, - 0xc2e801fb244576d5,0x229c41f793cda73f, - 0xf3a20279ed56d48a,0x6b43527578c1110f, - 0x9845418c345644d6,0x830a13896b78aaa9, - 0xbe5691ef416bd60c,0x23cc986bc656d553, - 0xedec366b11c6cb8f,0x2cbfbe86b7ec8aa8, - 0x94b3a202eb1c3f39,0x7bf7d71432f3d6a9, - 0xb9e08a83a5e34f07,0xdaf5ccd93fb0cc53, - 0xe858ad248f5c22c9,0xd1b3400f8f9cff68, - 0x91376c36d99995be,0x23100809b9c21fa1, - 0xb58547448ffffb2d,0xabd40a0c2832a78a, - 0xe2e69915b3fff9f9,0x16c90c8f323f516c, - 0x8dd01fad907ffc3b,0xae3da7d97f6792e3, - 0xb1442798f49ffb4a,0x99cd11cfdf41779c, - 0xdd95317f31c7fa1d,0x40405643d711d583, - 0x8a7d3eef7f1cfc52,0x482835ea666b2572, - 0xad1c8eab5ee43b66,0xda3243650005eecf, - 0xd863b256369d4a40,0x90bed43e40076a82, - 0x873e4f75e2224e68,0x5a7744a6e804a291, - 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0xb38d92d760ec4455,0x37c981dcc395a9ac, - 0xe070f78d3927556a,0x85bbe253f47b1417, - 0x8c469ab843b89562,0x93956d7478ccec8e, - 0xaf58416654a6babb,0x387ac8d1970027b2, - 0xdb2e51bfe9d0696a,0x6997b05fcc0319e, - 0x88fcf317f22241e2,0x441fece3bdf81f03, - 0xab3c2fddeeaad25a,0xd527e81cad7626c3, - 0xd60b3bd56a5586f1,0x8a71e223d8d3b074, - 0x85c7056562757456,0xf6872d5667844e49, - 0xa738c6bebb12d16c,0xb428f8ac016561db, - 0xd106f86e69d785c7,0xe13336d701beba52, - 0x82a45b450226b39c,0xecc0024661173473, - 0xa34d721642b06084,0x27f002d7f95d0190, - 0xcc20ce9bd35c78a5,0x31ec038df7b441f4, - 0xff290242c83396ce,0x7e67047175a15271, - 0x9f79a169bd203e41,0xf0062c6e984d386, - 0xc75809c42c684dd1,0x52c07b78a3e60868, - 0xf92e0c3537826145,0xa7709a56ccdf8a82, - 0x9bbcc7a142b17ccb,0x88a66076400bb691, - 0xc2abf989935ddbfe,0x6acff893d00ea435, - 0xf356f7ebf83552fe,0x583f6b8c4124d43, - 0x98165af37b2153de,0xc3727a337a8b704a, - 0xbe1bf1b059e9a8d6,0x744f18c0592e4c5c, - 0xeda2ee1c7064130c,0x1162def06f79df73, - 0x9485d4d1c63e8be7,0x8addcb5645ac2ba8, - 0xb9a74a0637ce2ee1,0x6d953e2bd7173692, - 0xe8111c87c5c1ba99,0xc8fa8db6ccdd0437, - 0x910ab1d4db9914a0,0x1d9c9892400a22a2, - 0xb54d5e4a127f59c8,0x2503beb6d00cab4b, - 0xe2a0b5dc971f303a,0x2e44ae64840fd61d, - 0x8da471a9de737e24,0x5ceaecfed289e5d2, - 0xb10d8e1456105dad,0x7425a83e872c5f47, - 0xdd50f1996b947518,0xd12f124e28f77719, - 0x8a5296ffe33cc92f,0x82bd6b70d99aaa6f, - 0xace73cbfdc0bfb7b,0x636cc64d1001550b, - 0xd8210befd30efa5a,0x3c47f7e05401aa4e, - 0x8714a775e3e95c78,0x65acfaec34810a71, - 0xa8d9d1535ce3b396,0x7f1839a741a14d0d, - 0xd31045a8341ca07c,0x1ede48111209a050, - 0x83ea2b892091e44d,0x934aed0aab460432, - 0xa4e4b66b68b65d60,0xf81da84d5617853f, - 0xce1de40642e3f4b9,0x36251260ab9d668e, - 0x80d2ae83e9ce78f3,0xc1d72b7c6b426019, - 0xa1075a24e4421730,0xb24cf65b8612f81f, - 0xc94930ae1d529cfc,0xdee033f26797b627, - 0xfb9b7cd9a4a7443c,0x169840ef017da3b1, - 0x9d412e0806e88aa5,0x8e1f289560ee864e, - 0xc491798a08a2ad4e,0xf1a6f2bab92a27e2, - 0xf5b5d7ec8acb58a2,0xae10af696774b1db, - 0x9991a6f3d6bf1765,0xacca6da1e0a8ef29, - 0xbff610b0cc6edd3f,0x17fd090a58d32af3, - 0xeff394dcff8a948e,0xddfc4b4cef07f5b0, - 0x95f83d0a1fb69cd9,0x4abdaf101564f98e, - 0xbb764c4ca7a4440f,0x9d6d1ad41abe37f1, - 0xea53df5fd18d5513,0x84c86189216dc5ed, - 0x92746b9be2f8552c,0x32fd3cf5b4e49bb4, - 0xb7118682dbb66a77,0x3fbc8c33221dc2a1, - 0xe4d5e82392a40515,0xfabaf3feaa5334a, - 0x8f05b1163ba6832d,0x29cb4d87f2a7400e, - 0xb2c71d5bca9023f8,0x743e20e9ef511012, - 0xdf78e4b2bd342cf6,0x914da9246b255416, - 0x8bab8eefb6409c1a,0x1ad089b6c2f7548e, - 0xae9672aba3d0c320,0xa184ac2473b529b1, - 0xda3c0f568cc4f3e8,0xc9e5d72d90a2741e, - 0x8865899617fb1871,0x7e2fa67c7a658892, - 0xaa7eebfb9df9de8d,0xddbb901b98feeab7, - 0xd51ea6fa85785631,0x552a74227f3ea565, - 0x8533285c936b35de,0xd53a88958f87275f, - 0xa67ff273b8460356,0x8a892abaf368f137, - 0xd01fef10a657842c,0x2d2b7569b0432d85, - 0x8213f56a67f6b29b,0x9c3b29620e29fc73, - 0xa298f2c501f45f42,0x8349f3ba91b47b8f, - 0xcb3f2f7642717713,0x241c70a936219a73, - 0xfe0efb53d30dd4d7,0xed238cd383aa0110, - 0x9ec95d1463e8a506,0xf4363804324a40aa, - 0xc67bb4597ce2ce48,0xb143c6053edcd0d5, - 0xf81aa16fdc1b81da,0xdd94b7868e94050a, - 0x9b10a4e5e9913128,0xca7cf2b4191c8326, - 0xc1d4ce1f63f57d72,0xfd1c2f611f63a3f0, - 0xf24a01a73cf2dccf,0xbc633b39673c8cec, - 0x976e41088617ca01,0xd5be0503e085d813, - 0xbd49d14aa79dbc82,0x4b2d8644d8a74e18, - 0xec9c459d51852ba2,0xddf8e7d60ed1219e, - 0x93e1ab8252f33b45,0xcabb90e5c942b503, - 0xb8da1662e7b00a17,0x3d6a751f3b936243, - 0xe7109bfba19c0c9d,0xcc512670a783ad4, - 0x906a617d450187e2,0x27fb2b80668b24c5, - 0xb484f9dc9641e9da,0xb1f9f660802dedf6, - 0xe1a63853bbd26451,0x5e7873f8a0396973, - 0x8d07e33455637eb2,0xdb0b487b6423e1e8, - 0xb049dc016abc5e5f,0x91ce1a9a3d2cda62, - 0xdc5c5301c56b75f7,0x7641a140cc7810fb, - 0x89b9b3e11b6329ba,0xa9e904c87fcb0a9d, - 0xac2820d9623bf429,0x546345fa9fbdcd44, - 0xd732290fbacaf133,0xa97c177947ad4095, - 0x867f59a9d4bed6c0,0x49ed8eabcccc485d, - 0xa81f301449ee8c70,0x5c68f256bfff5a74, - 0xd226fc195c6a2f8c,0x73832eec6fff3111, - 0x83585d8fd9c25db7,0xc831fd53c5ff7eab, - 0xa42e74f3d032f525,0xba3e7ca8b77f5e55, - 0xcd3a1230c43fb26f,0x28ce1bd2e55f35eb, - 0x80444b5e7aa7cf85,0x7980d163cf5b81b3, - 0xa0555e361951c366,0xd7e105bcc332621f, - 0xc86ab5c39fa63440,0x8dd9472bf3fefaa7, - 0xfa856334878fc150,0xb14f98f6f0feb951, - 0x9c935e00d4b9d8d2,0x6ed1bf9a569f33d3, - 0xc3b8358109e84f07,0xa862f80ec4700c8, - 0xf4a642e14c6262c8,0xcd27bb612758c0fa, - 0x98e7e9cccfbd7dbd,0x8038d51cb897789c, - 0xbf21e44003acdd2c,0xe0470a63e6bd56c3, - 0xeeea5d5004981478,0x1858ccfce06cac74, - 0x95527a5202df0ccb,0xf37801e0c43ebc8, - 0xbaa718e68396cffd,0xd30560258f54e6ba, - 0xe950df20247c83fd,0x47c6b82ef32a2069, - 0x91d28b7416cdd27e,0x4cdc331d57fa5441, - 0xb6472e511c81471d,0xe0133fe4adf8e952, - 0xe3d8f9e563a198e5,0x58180fddd97723a6, - 0x8e679c2f5e44ff8f,0x570f09eaa7ea7648, }; - + extern SIMDJSON_DLLIMPORTEXPORT const uint64_t power_of_five_128[]; } // namespace internal } // namespace simdjson -/* end file src/internal/numberparsing_tables.cpp */ -/* begin file src/internal/simdprune_tables.cpp */ + +#endif // SIMDJSON_INTERNAL_NUMBERPARSING_TABLES_H +/* end file simdjson/internal/numberparsing_tables.h */ + +// Precomputed powers of ten from 10^0 to 10^22. These +// can be represented exactly using the double type. +SIMDJSON_DLLIMPORTEXPORT const double simdjson::internal::power_of_ten[] = { + 1e0, 1e1, 1e2, 1e3, 1e4, 1e5, 1e6, 1e7, 1e8, 1e9, 1e10, 1e11, + 1e12, 1e13, 1e14, 1e15, 1e16, 1e17, 1e18, 1e19, 1e20, 1e21, 1e22 }; + +/** + * When mapping numbers from decimal to binary, + * we go from w * 10^q to m * 2^p but we have + * 10^q = 5^q * 2^q, so effectively + * we are trying to match + * w * 2^q * 5^q to m * 2^p. Thus the powers of two + * are not a concern since they can be represented + * exactly using the binary notation, only the powers of five + * affect the binary significand. + */ + + + // The truncated powers of five from 5^-342 all the way to 5^308 + // The mantissa is truncated to 128 bits, and + // never rounded up. Uses about 10KB. +SIMDJSON_DLLIMPORTEXPORT const uint64_t simdjson::internal::power_of_five_128[] = { + 0xeef453d6923bd65a,0x113faa2906a13b3f, + 0x9558b4661b6565f8,0x4ac7ca59a424c507, + 0xbaaee17fa23ebf76,0x5d79bcf00d2df649, + 0xe95a99df8ace6f53,0xf4d82c2c107973dc, + 0x91d8a02bb6c10594,0x79071b9b8a4be869, + 0xb64ec836a47146f9,0x9748e2826cdee284, + 0xe3e27a444d8d98b7,0xfd1b1b2308169b25, + 0x8e6d8c6ab0787f72,0xfe30f0f5e50e20f7, + 0xb208ef855c969f4f,0xbdbd2d335e51a935, + 0xde8b2b66b3bc4723,0xad2c788035e61382, + 0x8b16fb203055ac76,0x4c3bcb5021afcc31, + 0xaddcb9e83c6b1793,0xdf4abe242a1bbf3d, + 0xd953e8624b85dd78,0xd71d6dad34a2af0d, + 0x87d4713d6f33aa6b,0x8672648c40e5ad68, + 0xa9c98d8ccb009506,0x680efdaf511f18c2, + 0xd43bf0effdc0ba48,0x212bd1b2566def2, + 0x84a57695fe98746d,0x14bb630f7604b57, + 0xa5ced43b7e3e9188,0x419ea3bd35385e2d, + 0xcf42894a5dce35ea,0x52064cac828675b9, + 0x818995ce7aa0e1b2,0x7343efebd1940993, + 0xa1ebfb4219491a1f,0x1014ebe6c5f90bf8, + 0xca66fa129f9b60a6,0xd41a26e077774ef6, + 0xfd00b897478238d0,0x8920b098955522b4, + 0x9e20735e8cb16382,0x55b46e5f5d5535b0, + 0xc5a890362fddbc62,0xeb2189f734aa831d, + 0xf712b443bbd52b7b,0xa5e9ec7501d523e4, + 0x9a6bb0aa55653b2d,0x47b233c92125366e, + 0xc1069cd4eabe89f8,0x999ec0bb696e840a, + 0xf148440a256e2c76,0xc00670ea43ca250d, + 0x96cd2a865764dbca,0x380406926a5e5728, + 0xbc807527ed3e12bc,0xc605083704f5ecf2, + 0xeba09271e88d976b,0xf7864a44c633682e, + 0x93445b8731587ea3,0x7ab3ee6afbe0211d, + 0xb8157268fdae9e4c,0x5960ea05bad82964, + 0xe61acf033d1a45df,0x6fb92487298e33bd, + 0x8fd0c16206306bab,0xa5d3b6d479f8e056, + 0xb3c4f1ba87bc8696,0x8f48a4899877186c, + 0xe0b62e2929aba83c,0x331acdabfe94de87, + 0x8c71dcd9ba0b4925,0x9ff0c08b7f1d0b14, + 0xaf8e5410288e1b6f,0x7ecf0ae5ee44dd9, + 0xdb71e91432b1a24a,0xc9e82cd9f69d6150, + 0x892731ac9faf056e,0xbe311c083a225cd2, + 0xab70fe17c79ac6ca,0x6dbd630a48aaf406, + 0xd64d3d9db981787d,0x92cbbccdad5b108, + 0x85f0468293f0eb4e,0x25bbf56008c58ea5, + 0xa76c582338ed2621,0xaf2af2b80af6f24e, + 0xd1476e2c07286faa,0x1af5af660db4aee1, + 0x82cca4db847945ca,0x50d98d9fc890ed4d, + 0xa37fce126597973c,0xe50ff107bab528a0, + 0xcc5fc196fefd7d0c,0x1e53ed49a96272c8, + 0xff77b1fcbebcdc4f,0x25e8e89c13bb0f7a, + 0x9faacf3df73609b1,0x77b191618c54e9ac, + 0xc795830d75038c1d,0xd59df5b9ef6a2417, + 0xf97ae3d0d2446f25,0x4b0573286b44ad1d, + 0x9becce62836ac577,0x4ee367f9430aec32, + 0xc2e801fb244576d5,0x229c41f793cda73f, + 0xf3a20279ed56d48a,0x6b43527578c1110f, + 0x9845418c345644d6,0x830a13896b78aaa9, + 0xbe5691ef416bd60c,0x23cc986bc656d553, + 0xedec366b11c6cb8f,0x2cbfbe86b7ec8aa8, + 0x94b3a202eb1c3f39,0x7bf7d71432f3d6a9, + 0xb9e08a83a5e34f07,0xdaf5ccd93fb0cc53, + 0xe858ad248f5c22c9,0xd1b3400f8f9cff68, + 0x91376c36d99995be,0x23100809b9c21fa1, + 0xb58547448ffffb2d,0xabd40a0c2832a78a, + 0xe2e69915b3fff9f9,0x16c90c8f323f516c, + 0x8dd01fad907ffc3b,0xae3da7d97f6792e3, + 0xb1442798f49ffb4a,0x99cd11cfdf41779c, + 0xdd95317f31c7fa1d,0x40405643d711d583, + 0x8a7d3eef7f1cfc52,0x482835ea666b2572, + 0xad1c8eab5ee43b66,0xda3243650005eecf, + 0xd863b256369d4a40,0x90bed43e40076a82, + 0x873e4f75e2224e68,0x5a7744a6e804a291, + 0xa90de3535aaae202,0x711515d0a205cb36, + 0xd3515c2831559a83,0xd5a5b44ca873e03, + 0x8412d9991ed58091,0xe858790afe9486c2, + 0xa5178fff668ae0b6,0x626e974dbe39a872, + 0xce5d73ff402d98e3,0xfb0a3d212dc8128f, + 0x80fa687f881c7f8e,0x7ce66634bc9d0b99, + 0xa139029f6a239f72,0x1c1fffc1ebc44e80, + 0xc987434744ac874e,0xa327ffb266b56220, + 0xfbe9141915d7a922,0x4bf1ff9f0062baa8, + 0x9d71ac8fada6c9b5,0x6f773fc3603db4a9, + 0xc4ce17b399107c22,0xcb550fb4384d21d3, + 0xf6019da07f549b2b,0x7e2a53a146606a48, + 0x99c102844f94e0fb,0x2eda7444cbfc426d, + 0xc0314325637a1939,0xfa911155fefb5308, + 0xf03d93eebc589f88,0x793555ab7eba27ca, + 0x96267c7535b763b5,0x4bc1558b2f3458de, + 0xbbb01b9283253ca2,0x9eb1aaedfb016f16, + 0xea9c227723ee8bcb,0x465e15a979c1cadc, + 0x92a1958a7675175f,0xbfacd89ec191ec9, + 0xb749faed14125d36,0xcef980ec671f667b, + 0xe51c79a85916f484,0x82b7e12780e7401a, + 0x8f31cc0937ae58d2,0xd1b2ecb8b0908810, + 0xb2fe3f0b8599ef07,0x861fa7e6dcb4aa15, + 0xdfbdcece67006ac9,0x67a791e093e1d49a, + 0x8bd6a141006042bd,0xe0c8bb2c5c6d24e0, + 0xaecc49914078536d,0x58fae9f773886e18, + 0xda7f5bf590966848,0xaf39a475506a899e, + 0x888f99797a5e012d,0x6d8406c952429603, + 0xaab37fd7d8f58178,0xc8e5087ba6d33b83, + 0xd5605fcdcf32e1d6,0xfb1e4a9a90880a64, + 0x855c3be0a17fcd26,0x5cf2eea09a55067f, + 0xa6b34ad8c9dfc06f,0xf42faa48c0ea481e, + 0xd0601d8efc57b08b,0xf13b94daf124da26, + 0x823c12795db6ce57,0x76c53d08d6b70858, + 0xa2cb1717b52481ed,0x54768c4b0c64ca6e, + 0xcb7ddcdda26da268,0xa9942f5dcf7dfd09, + 0xfe5d54150b090b02,0xd3f93b35435d7c4c, + 0x9efa548d26e5a6e1,0xc47bc5014a1a6daf, + 0xc6b8e9b0709f109a,0x359ab6419ca1091b, + 0xf867241c8cc6d4c0,0xc30163d203c94b62, + 0x9b407691d7fc44f8,0x79e0de63425dcf1d, + 0xc21094364dfb5636,0x985915fc12f542e4, + 0xf294b943e17a2bc4,0x3e6f5b7b17b2939d, + 0x979cf3ca6cec5b5a,0xa705992ceecf9c42, + 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0x95d04aee3b80ece5,0xbba1f1d158724a12, + 0xbb445da9ca61281f,0x2a8a6e45ae8edc97, + 0xea1575143cf97226,0xf52d09d71a3293bd, + 0x924d692ca61be758,0x593c2626705f9c56, + 0xb6e0c377cfa2e12e,0x6f8b2fb00c77836c, + 0xe498f455c38b997a,0xb6dfb9c0f956447, + 0x8edf98b59a373fec,0x4724bd4189bd5eac, + 0xb2977ee300c50fe7,0x58edec91ec2cb657, + 0xdf3d5e9bc0f653e1,0x2f2967b66737e3ed, + 0x8b865b215899f46c,0xbd79e0d20082ee74, + 0xae67f1e9aec07187,0xecd8590680a3aa11, + 0xda01ee641a708de9,0xe80e6f4820cc9495, + 0x884134fe908658b2,0x3109058d147fdcdd, + 0xaa51823e34a7eede,0xbd4b46f0599fd415, + 0xd4e5e2cdc1d1ea96,0x6c9e18ac7007c91a, + 0x850fadc09923329e,0x3e2cf6bc604ddb0, + 0xa6539930bf6bff45,0x84db8346b786151c, + 0xcfe87f7cef46ff16,0xe612641865679a63, + 0x81f14fae158c5f6e,0x4fcb7e8f3f60c07e, + 0xa26da3999aef7749,0xe3be5e330f38f09d, + 0xcb090c8001ab551c,0x5cadf5bfd3072cc5, + 0xfdcb4fa002162a63,0x73d9732fc7c8f7f6, + 0x9e9f11c4014dda7e,0x2867e7fddcdd9afa, + 0xc646d63501a1511d,0xb281e1fd541501b8, + 0xf7d88bc24209a565,0x1f225a7ca91a4226, + 0x9ae757596946075f,0x3375788de9b06958, + 0xc1a12d2fc3978937,0x52d6b1641c83ae, + 0xf209787bb47d6b84,0xc0678c5dbd23a49a, + 0x9745eb4d50ce6332,0xf840b7ba963646e0, + 0xbd176620a501fbff,0xb650e5a93bc3d898, + 0xec5d3fa8ce427aff,0xa3e51f138ab4cebe, + 0x93ba47c980e98cdf,0xc66f336c36b10137, + 0xb8a8d9bbe123f017,0xb80b0047445d4184, + 0xe6d3102ad96cec1d,0xa60dc059157491e5, + 0x9043ea1ac7e41392,0x87c89837ad68db2f, + 0xb454e4a179dd1877,0x29babe4598c311fb, + 0xe16a1dc9d8545e94,0xf4296dd6fef3d67a, + 0x8ce2529e2734bb1d,0x1899e4a65f58660c, + 0xb01ae745b101e9e4,0x5ec05dcff72e7f8f, + 0xdc21a1171d42645d,0x76707543f4fa1f73, + 0x899504ae72497eba,0x6a06494a791c53a8, + 0xabfa45da0edbde69,0x487db9d17636892, + 0xd6f8d7509292d603,0x45a9d2845d3c42b6, + 0x865b86925b9bc5c2,0xb8a2392ba45a9b2, + 0xa7f26836f282b732,0x8e6cac7768d7141e, + 0xd1ef0244af2364ff,0x3207d795430cd926, + 0x8335616aed761f1f,0x7f44e6bd49e807b8, + 0xa402b9c5a8d3a6e7,0x5f16206c9c6209a6, + 0xcd036837130890a1,0x36dba887c37a8c0f, + 0x802221226be55a64,0xc2494954da2c9789, + 0xa02aa96b06deb0fd,0xf2db9baa10b7bd6c, + 0xc83553c5c8965d3d,0x6f92829494e5acc7, + 0xfa42a8b73abbf48c,0xcb772339ba1f17f9, + 0x9c69a97284b578d7,0xff2a760414536efb, + 0xc38413cf25e2d70d,0xfef5138519684aba, + 0xf46518c2ef5b8cd1,0x7eb258665fc25d69, + 0x98bf2f79d5993802,0xef2f773ffbd97a61, + 0xbeeefb584aff8603,0xaafb550ffacfd8fa, + 0xeeaaba2e5dbf6784,0x95ba2a53f983cf38, + 0x952ab45cfa97a0b2,0xdd945a747bf26183, + 0xba756174393d88df,0x94f971119aeef9e4, + 0xe912b9d1478ceb17,0x7a37cd5601aab85d, + 0x91abb422ccb812ee,0xac62e055c10ab33a, + 0xb616a12b7fe617aa,0x577b986b314d6009, + 0xe39c49765fdf9d94,0xed5a7e85fda0b80b, + 0x8e41ade9fbebc27d,0x14588f13be847307, + 0xb1d219647ae6b31c,0x596eb2d8ae258fc8, + 0xde469fbd99a05fe3,0x6fca5f8ed9aef3bb, + 0x8aec23d680043bee,0x25de7bb9480d5854, + 0xada72ccc20054ae9,0xaf561aa79a10ae6a, + 0xd910f7ff28069da4,0x1b2ba1518094da04, + 0x87aa9aff79042286,0x90fb44d2f05d0842, + 0xa99541bf57452b28,0x353a1607ac744a53, + 0xd3fa922f2d1675f2,0x42889b8997915ce8, + 0x847c9b5d7c2e09b7,0x69956135febada11, + 0xa59bc234db398c25,0x43fab9837e699095, + 0xcf02b2c21207ef2e,0x94f967e45e03f4bb, + 0x8161afb94b44f57d,0x1d1be0eebac278f5, + 0xa1ba1ba79e1632dc,0x6462d92a69731732, + 0xca28a291859bbf93,0x7d7b8f7503cfdcfe, + 0xfcb2cb35e702af78,0x5cda735244c3d43e, + 0x9defbf01b061adab,0x3a0888136afa64a7, + 0xc56baec21c7a1916,0x88aaa1845b8fdd0, + 0xf6c69a72a3989f5b,0x8aad549e57273d45, + 0x9a3c2087a63f6399,0x36ac54e2f678864b, + 0xc0cb28a98fcf3c7f,0x84576a1bb416a7dd, + 0xf0fdf2d3f3c30b9f,0x656d44a2a11c51d5, + 0x969eb7c47859e743,0x9f644ae5a4b1b325, + 0xbc4665b596706114,0x873d5d9f0dde1fee, + 0xeb57ff22fc0c7959,0xa90cb506d155a7ea, + 0x9316ff75dd87cbd8,0x9a7f12442d588f2, + 0xb7dcbf5354e9bece,0xc11ed6d538aeb2f, + 0xe5d3ef282a242e81,0x8f1668c8a86da5fa, + 0x8fa475791a569d10,0xf96e017d694487bc, + 0xb38d92d760ec4455,0x37c981dcc395a9ac, + 0xe070f78d3927556a,0x85bbe253f47b1417, + 0x8c469ab843b89562,0x93956d7478ccec8e, + 0xaf58416654a6babb,0x387ac8d1970027b2, + 0xdb2e51bfe9d0696a,0x6997b05fcc0319e, + 0x88fcf317f22241e2,0x441fece3bdf81f03, + 0xab3c2fddeeaad25a,0xd527e81cad7626c3, + 0xd60b3bd56a5586f1,0x8a71e223d8d3b074, + 0x85c7056562757456,0xf6872d5667844e49, + 0xa738c6bebb12d16c,0xb428f8ac016561db, + 0xd106f86e69d785c7,0xe13336d701beba52, + 0x82a45b450226b39c,0xecc0024661173473, + 0xa34d721642b06084,0x27f002d7f95d0190, + 0xcc20ce9bd35c78a5,0x31ec038df7b441f4, + 0xff290242c83396ce,0x7e67047175a15271, + 0x9f79a169bd203e41,0xf0062c6e984d386, + 0xc75809c42c684dd1,0x52c07b78a3e60868, + 0xf92e0c3537826145,0xa7709a56ccdf8a82, + 0x9bbcc7a142b17ccb,0x88a66076400bb691, + 0xc2abf989935ddbfe,0x6acff893d00ea435, + 0xf356f7ebf83552fe,0x583f6b8c4124d43, + 0x98165af37b2153de,0xc3727a337a8b704a, + 0xbe1bf1b059e9a8d6,0x744f18c0592e4c5c, + 0xeda2ee1c7064130c,0x1162def06f79df73, + 0x9485d4d1c63e8be7,0x8addcb5645ac2ba8, + 0xb9a74a0637ce2ee1,0x6d953e2bd7173692, + 0xe8111c87c5c1ba99,0xc8fa8db6ccdd0437, + 0x910ab1d4db9914a0,0x1d9c9892400a22a2, + 0xb54d5e4a127f59c8,0x2503beb6d00cab4b, + 0xe2a0b5dc971f303a,0x2e44ae64840fd61d, + 0x8da471a9de737e24,0x5ceaecfed289e5d2, + 0xb10d8e1456105dad,0x7425a83e872c5f47, + 0xdd50f1996b947518,0xd12f124e28f77719, + 0x8a5296ffe33cc92f,0x82bd6b70d99aaa6f, + 0xace73cbfdc0bfb7b,0x636cc64d1001550b, + 0xd8210befd30efa5a,0x3c47f7e05401aa4e, + 0x8714a775e3e95c78,0x65acfaec34810a71, + 0xa8d9d1535ce3b396,0x7f1839a741a14d0d, + 0xd31045a8341ca07c,0x1ede48111209a050, + 0x83ea2b892091e44d,0x934aed0aab460432, + 0xa4e4b66b68b65d60,0xf81da84d5617853f, + 0xce1de40642e3f4b9,0x36251260ab9d668e, + 0x80d2ae83e9ce78f3,0xc1d72b7c6b426019, + 0xa1075a24e4421730,0xb24cf65b8612f81f, + 0xc94930ae1d529cfc,0xdee033f26797b627, + 0xfb9b7cd9a4a7443c,0x169840ef017da3b1, + 0x9d412e0806e88aa5,0x8e1f289560ee864e, + 0xc491798a08a2ad4e,0xf1a6f2bab92a27e2, + 0xf5b5d7ec8acb58a2,0xae10af696774b1db, + 0x9991a6f3d6bf1765,0xacca6da1e0a8ef29, + 0xbff610b0cc6edd3f,0x17fd090a58d32af3, + 0xeff394dcff8a948e,0xddfc4b4cef07f5b0, + 0x95f83d0a1fb69cd9,0x4abdaf101564f98e, + 0xbb764c4ca7a4440f,0x9d6d1ad41abe37f1, + 0xea53df5fd18d5513,0x84c86189216dc5ed, + 0x92746b9be2f8552c,0x32fd3cf5b4e49bb4, + 0xb7118682dbb66a77,0x3fbc8c33221dc2a1, + 0xe4d5e82392a40515,0xfabaf3feaa5334a, + 0x8f05b1163ba6832d,0x29cb4d87f2a7400e, + 0xb2c71d5bca9023f8,0x743e20e9ef511012, + 0xdf78e4b2bd342cf6,0x914da9246b255416, + 0x8bab8eefb6409c1a,0x1ad089b6c2f7548e, + 0xae9672aba3d0c320,0xa184ac2473b529b1, + 0xda3c0f568cc4f3e8,0xc9e5d72d90a2741e, + 0x8865899617fb1871,0x7e2fa67c7a658892, + 0xaa7eebfb9df9de8d,0xddbb901b98feeab7, + 0xd51ea6fa85785631,0x552a74227f3ea565, + 0x8533285c936b35de,0xd53a88958f87275f, + 0xa67ff273b8460356,0x8a892abaf368f137, + 0xd01fef10a657842c,0x2d2b7569b0432d85, + 0x8213f56a67f6b29b,0x9c3b29620e29fc73, + 0xa298f2c501f45f42,0x8349f3ba91b47b8f, + 0xcb3f2f7642717713,0x241c70a936219a73, + 0xfe0efb53d30dd4d7,0xed238cd383aa0110, + 0x9ec95d1463e8a506,0xf4363804324a40aa, + 0xc67bb4597ce2ce48,0xb143c6053edcd0d5, + 0xf81aa16fdc1b81da,0xdd94b7868e94050a, + 0x9b10a4e5e9913128,0xca7cf2b4191c8326, + 0xc1d4ce1f63f57d72,0xfd1c2f611f63a3f0, + 0xf24a01a73cf2dccf,0xbc633b39673c8cec, + 0x976e41088617ca01,0xd5be0503e085d813, + 0xbd49d14aa79dbc82,0x4b2d8644d8a74e18, + 0xec9c459d51852ba2,0xddf8e7d60ed1219e, + 0x93e1ab8252f33b45,0xcabb90e5c942b503, + 0xb8da1662e7b00a17,0x3d6a751f3b936243, + 0xe7109bfba19c0c9d,0xcc512670a783ad4, + 0x906a617d450187e2,0x27fb2b80668b24c5, + 0xb484f9dc9641e9da,0xb1f9f660802dedf6, + 0xe1a63853bbd26451,0x5e7873f8a0396973, + 0x8d07e33455637eb2,0xdb0b487b6423e1e8, + 0xb049dc016abc5e5f,0x91ce1a9a3d2cda62, + 0xdc5c5301c56b75f7,0x7641a140cc7810fb, + 0x89b9b3e11b6329ba,0xa9e904c87fcb0a9d, + 0xac2820d9623bf429,0x546345fa9fbdcd44, + 0xd732290fbacaf133,0xa97c177947ad4095, + 0x867f59a9d4bed6c0,0x49ed8eabcccc485d, + 0xa81f301449ee8c70,0x5c68f256bfff5a74, + 0xd226fc195c6a2f8c,0x73832eec6fff3111, + 0x83585d8fd9c25db7,0xc831fd53c5ff7eab, + 0xa42e74f3d032f525,0xba3e7ca8b77f5e55, + 0xcd3a1230c43fb26f,0x28ce1bd2e55f35eb, + 0x80444b5e7aa7cf85,0x7980d163cf5b81b3, + 0xa0555e361951c366,0xd7e105bcc332621f, + 0xc86ab5c39fa63440,0x8dd9472bf3fefaa7, + 0xfa856334878fc150,0xb14f98f6f0feb951, + 0x9c935e00d4b9d8d2,0x6ed1bf9a569f33d3, + 0xc3b8358109e84f07,0xa862f80ec4700c8, + 0xf4a642e14c6262c8,0xcd27bb612758c0fa, + 0x98e7e9cccfbd7dbd,0x8038d51cb897789c, + 0xbf21e44003acdd2c,0xe0470a63e6bd56c3, + 0xeeea5d5004981478,0x1858ccfce06cac74, + 0x95527a5202df0ccb,0xf37801e0c43ebc8, + 0xbaa718e68396cffd,0xd30560258f54e6ba, + 0xe950df20247c83fd,0x47c6b82ef32a2069, + 0x91d28b7416cdd27e,0x4cdc331d57fa5441, + 0xb6472e511c81471d,0xe0133fe4adf8e952, + 0xe3d8f9e563a198e5,0x58180fddd97723a6, + 0x8e679c2f5e44ff8f,0x570f09eaa7ea7648, }; + +#endif // SIMDJSON_SRC_NUMBERPARSING_TABLES_CPP +/* end file internal/numberparsing_tables.cpp */ +/* including internal/simdprune_tables.cpp: #include */ +/* begin file internal/simdprune_tables.cpp */ +#ifndef SIMDJSON_SRC_SIMDPRUNE_TABLES_CPP +#define SIMDJSON_SRC_SIMDPRUNE_TABLES_CPP + +/* including simdjson/implementation_detection.h: #include */ +/* begin file simdjson/implementation_detection.h */ +#ifndef SIMDJSON_IMPLEMENTATION_DETECTION_H +#define SIMDJSON_IMPLEMENTATION_DETECTION_H + +/* skipped duplicate #include "simdjson/base.h" */ + +// 0 is reserved, because undefined SIMDJSON_IMPLEMENTATION equals 0 in preprocessor macros. +#define SIMDJSON_IMPLEMENTATION_ID_arm64 1 +#define SIMDJSON_IMPLEMENTATION_ID_fallback 2 +#define SIMDJSON_IMPLEMENTATION_ID_haswell 3 +#define SIMDJSON_IMPLEMENTATION_ID_icelake 4 +#define SIMDJSON_IMPLEMENTATION_ID_ppc64 5 +#define SIMDJSON_IMPLEMENTATION_ID_westmere 6 + +#define SIMDJSON_IMPLEMENTATION_ID_FOR(IMPL) SIMDJSON_CAT(SIMDJSON_IMPLEMENTATION_ID_, IMPL) +#define SIMDJSON_IMPLEMENTATION_ID SIMDJSON_IMPLEMENTATION_ID_FOR(SIMDJSON_IMPLEMENTATION) + +#define SIMDJSON_IMPLEMENTATION_IS(IMPL) SIMDJSON_IMPLEMENTATION_ID == SIMDJSON_IMPLEMENTATION_ID_FOR(IMPL) + +// +// First, figure out which implementations can be run. Doing it here makes it so we don't have to worry about the order +// in which we include them. +// + +#ifndef SIMDJSON_IMPLEMENTATION_ARM64 +#define SIMDJSON_IMPLEMENTATION_ARM64 (SIMDJSON_IS_ARM64) +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_ARM64 SIMDJSON_IMPLEMENTATION_ARM64 && SIMDJSON_IS_ARM64 + +// Default Icelake to on if this is x86-64. Even if we're not compiled for it, it could be selected +// at runtime. +#ifndef SIMDJSON_IMPLEMENTATION_ICELAKE +#define SIMDJSON_IMPLEMENTATION_ICELAKE ((SIMDJSON_IS_X86_64) && (SIMDJSON_AVX512_ALLOWED) && (SIMDJSON_COMPILER_SUPPORTS_VBMI2)) +#endif + +#ifdef _MSC_VER +// To see why (__BMI__) && (__PCLMUL__) && (__LZCNT__) are not part of this next line, see +// https://github.com/simdjson/simdjson/issues/1247 +#define SIMDJSON_CAN_ALWAYS_RUN_ICELAKE ((SIMDJSON_IMPLEMENTATION_ICELAKE) && (__AVX2__) && (__AVX512F__) && (__AVX512DQ__) && (__AVX512CD__) && (__AVX512BW__) && (__AVX512VL__) && (__AVX512VBMI2__)) +#else +#define SIMDJSON_CAN_ALWAYS_RUN_ICELAKE ((SIMDJSON_IMPLEMENTATION_ICELAKE) && (__AVX2__) && (__BMI__) && (__PCLMUL__) && (__LZCNT__) && (__AVX512F__) && (__AVX512DQ__) && (__AVX512CD__) && (__AVX512BW__) && (__AVX512VL__) && (__AVX512VBMI2__)) +#endif + +// Default Haswell to on if this is x86-64. Even if we're not compiled for it, it could be selected +// at runtime. +#ifndef SIMDJSON_IMPLEMENTATION_HASWELL +#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +// if icelake is always available, never enable haswell. +#define SIMDJSON_IMPLEMENTATION_HASWELL 0 +#else +#define SIMDJSON_IMPLEMENTATION_HASWELL SIMDJSON_IS_X86_64 +#endif +#endif +#ifdef _MSC_VER +// To see why (__BMI__) && (__PCLMUL__) && (__LZCNT__) are not part of this next line, see +// https://github.com/simdjson/simdjson/issues/1247 +#define SIMDJSON_CAN_ALWAYS_RUN_HASWELL ((SIMDJSON_IMPLEMENTATION_HASWELL) && (SIMDJSON_IS_X86_64) && (__AVX2__)) +#else +#define SIMDJSON_CAN_ALWAYS_RUN_HASWELL ((SIMDJSON_IMPLEMENTATION_HASWELL) && (SIMDJSON_IS_X86_64) && (__AVX2__) && (__BMI__) && (__PCLMUL__) && (__LZCNT__)) +#endif + +// Default Westmere to on if this is x86-64. +#ifndef SIMDJSON_IMPLEMENTATION_WESTMERE +#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE || SIMDJSON_CAN_ALWAYS_RUN_HASWELL +// if icelake or haswell are always available, never enable westmere. +#define SIMDJSON_IMPLEMENTATION_WESTMERE 0 +#else +#define SIMDJSON_IMPLEMENTATION_WESTMERE SIMDJSON_IS_X86_64 +#endif +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_WESTMERE (SIMDJSON_IMPLEMENTATION_WESTMERE && SIMDJSON_IS_X86_64 && __SSE4_2__ && __PCLMUL__) + +#ifndef SIMDJSON_IMPLEMENTATION_PPC64 +#define SIMDJSON_IMPLEMENTATION_PPC64 (SIMDJSON_IS_PPC64 && SIMDJSON_IS_PPC64_VMX) +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_PPC64 SIMDJSON_IMPLEMENTATION_PPC64 && SIMDJSON_IS_PPC64 && SIMDJSON_IS_PPC64_VMX + +// Default Fallback to on unless a builtin implementation has already been selected. +#ifndef SIMDJSON_IMPLEMENTATION_FALLBACK +#if SIMDJSON_CAN_ALWAYS_RUN_ARM64 || SIMDJSON_CAN_ALWAYS_RUN_ICELAKE || SIMDJSON_CAN_ALWAYS_RUN_HASWELL || SIMDJSON_CAN_ALWAYS_RUN_WESTMERE || SIMDJSON_CAN_ALWAYS_RUN_PPC64 +// if anything at all except fallback can always run, then disable fallback. +#define SIMDJSON_IMPLEMENTATION_FALLBACK 0 +#else +#define SIMDJSON_IMPLEMENTATION_FALLBACK 1 +#endif +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_FALLBACK SIMDJSON_IMPLEMENTATION_FALLBACK + +// Determine the best builtin implementation +#ifndef SIMDJSON_BUILTIN_IMPLEMENTATION + +#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +#define SIMDJSON_BUILTIN_IMPLEMENTATION icelake +#elif SIMDJSON_CAN_ALWAYS_RUN_HASWELL +#define SIMDJSON_BUILTIN_IMPLEMENTATION haswell +#elif SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +#define SIMDJSON_BUILTIN_IMPLEMENTATION westmere +#elif SIMDJSON_CAN_ALWAYS_RUN_ARM64 +#define SIMDJSON_BUILTIN_IMPLEMENTATION arm64 +#elif SIMDJSON_CAN_ALWAYS_RUN_PPC64 +#define SIMDJSON_BUILTIN_IMPLEMENTATION ppc64 +#elif SIMDJSON_CAN_ALWAYS_RUN_FALLBACK +#define SIMDJSON_BUILTIN_IMPLEMENTATION fallback +#else +#error "All possible implementations (including fallback) have been disabled! simdjson will not run." +#endif + +#endif // SIMDJSON_BUILTIN_IMPLEMENTATION + +#define SIMDJSON_BUILTIN_IMPLEMENTATION_ID SIMDJSON_IMPLEMENTATION_ID_FOR(SIMDJSON_BUILTIN_IMPLEMENTATION) +#define SIMDJSON_BUILTIN_IMPLEMENTATION_IS(IMPL) SIMDJSON_BUILTIN_IMPLEMENTATION_ID == SIMDJSON_IMPLEMENTATION_ID_FOR(IMPL) + +#endif // SIMDJSON_IMPLEMENTATION_DETECTION_H +/* end file simdjson/implementation_detection.h */ + #if SIMDJSON_IMPLEMENTATION_ARM64 || SIMDJSON_IMPLEMENTATION_ICELAKE || SIMDJSON_IMPLEMENTATION_HASWELL || SIMDJSON_IMPLEMENTATION_WESTMERE || SIMDJSON_IMPLEMENTATION_PPC64 #include @@ -2626,8 +5810,1108 @@ namespace simdjson { // table modified and copied from } // namespace simdjson #endif // SIMDJSON_IMPLEMENTATION_ARM64 || SIMDJSON_IMPLEMENTATION_ICELAKE || SIMDJSON_IMPLEMENTATION_HASWELL || SIMDJSON_IMPLEMENTATION_WESTMERE || SIMDJSON_IMPLEMENTATION_PPC64 -/* end file src/internal/simdprune_tables.cpp */ -/* begin file src/implementation.cpp */ + +#endif // SIMDJSON_SRC_SIMDPRUNE_TABLES_CPP +/* end file internal/simdprune_tables.cpp */ + +/* including simdjson/generic/dependencies.h: #include */ +/* begin file simdjson/generic/dependencies.h */ +#ifdef SIMDJSON_CONDITIONAL_INCLUDE +#error simdjson/generic/dependencies.h must be included before defining SIMDJSON_CONDITIONAL_INCLUDE! +#endif + +#ifndef SIMDJSON_GENERIC_DEPENDENCIES_H +#define SIMDJSON_GENERIC_DEPENDENCIES_H + +// Internal headers needed for generics. +// All includes referencing simdjson headers *not* under simdjson/generic must be here! +// Otherwise, amalgamation will fail. +/* skipped duplicate #include "simdjson/base.h" */ +/* including simdjson/implementation.h: #include "simdjson/implementation.h" */ +/* begin file simdjson/implementation.h */ +#ifndef SIMDJSON_IMPLEMENTATION_H +#define SIMDJSON_IMPLEMENTATION_H + +/* including simdjson/internal/atomic_ptr.h: #include "simdjson/internal/atomic_ptr.h" */ +/* begin file simdjson/internal/atomic_ptr.h */ +#ifndef SIMDJSON_INTERNAL_ATOMIC_PTR_H +#define SIMDJSON_INTERNAL_ATOMIC_PTR_H + +/* skipped duplicate #include "simdjson/base.h" */ +#include + +namespace simdjson { + namespace internal { + + template + class atomic_ptr { + public: + atomic_ptr(T* _ptr) : ptr{ _ptr } {} + + operator const T* () const { return ptr.load(); } + const T& operator*() const { return *ptr; } + const T* operator->() const { return ptr.load(); } + + operator T* () { return ptr.load(); } + T& operator*() { return *ptr; } + T* operator->() { return ptr.load(); } + atomic_ptr& operator=(T* _ptr) { ptr = _ptr; return *this; } + + private: + std::atomic ptr; + }; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_ATOMIC_PTR_H +/* end file simdjson/internal/atomic_ptr.h */ +/* including simdjson/internal/dom_parser_implementation.h: #include "simdjson/internal/dom_parser_implementation.h" */ +/* begin file simdjson/internal/dom_parser_implementation.h */ +#ifndef SIMDJSON_INTERNAL_DOM_PARSER_IMPLEMENTATION_H +#define SIMDJSON_INTERNAL_DOM_PARSER_IMPLEMENTATION_H + +/* skipped duplicate #include "simdjson/base.h" */ +/* skipped duplicate #include "simdjson/error.h" */ +#include + +namespace simdjson { + + namespace dom { + class document; + } // namespace dom + + /** + * This enum is used with the dom_parser_implementation::stage1 function. + * 1) The regular mode expects a fully formed JSON document. + * 2) The streaming_partial mode expects a possibly truncated + * input within a stream on JSON documents. + * 3) The stream_final mode allows us to truncate final + * unterminated strings. It is useful in conjunction with streaming_partial. + */ + enum class stage1_mode { regular, streaming_partial, streaming_final }; + + /** + * Returns true if mode == streaming_partial or mode == streaming_final + */ + inline bool is_streaming(stage1_mode mode) { + // performance note: it is probably faster to check that mode is different + // from regular than checking that it is either streaming_partial or streaming_final. + return (mode != stage1_mode::regular); + // return (mode == stage1_mode::streaming_partial || mode == stage1_mode::streaming_final); + } + + + namespace internal { + + + /** + * An implementation of simdjson's DOM parser for a particular CPU architecture. + * + * This class is expected to be accessed only by pointer, and never move in memory (though the + * pointer can move). + */ + class dom_parser_implementation { + public: + + /** + * @private For internal implementation use + * + * Run a full JSON parse on a single document (stage1 + stage2). + * + * Guaranteed only to be called when capacity > document length. + * + * Overridden by each implementation. + * + * @param buf The json document to parse. *MUST* be allocated up to len + SIMDJSON_PADDING bytes. + * @param len The length of the json document. + * @return The error code, or SUCCESS if there was no error. + */ + simdjson_warn_unused virtual error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept = 0; + + /** + * @private For internal implementation use + * + * Stage 1 of the document parser. + * + * Guaranteed only to be called when capacity > document length. + * + * Overridden by each implementation. + * + * @param buf The json document to parse. + * @param len The length of the json document. + * @param streaming Whether this is being called by parser::parse_many. + * @return The error code, or SUCCESS if there was no error. + */ + simdjson_warn_unused virtual error_code stage1(const uint8_t* buf, size_t len, stage1_mode streaming) noexcept = 0; + + /** + * @private For internal implementation use + * + * Stage 2 of the document parser. + * + * Called after stage1(). + * + * Overridden by each implementation. + * + * @param doc The document to output to. + * @return The error code, or SUCCESS if there was no error. + */ + simdjson_warn_unused virtual error_code stage2(dom::document& doc) noexcept = 0; + + /** + * @private For internal implementation use + * + * Stage 2 of the document parser for parser::parse_many. + * + * Guaranteed only to be called after stage1(). + * Overridden by each implementation. + * + * @param doc The document to output to. + * @return The error code, SUCCESS if there was no error, or EMPTY if all documents have been parsed. + */ + simdjson_warn_unused virtual error_code stage2_next(dom::document& doc) noexcept = 0; + + /** + * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + * + * Overridden by each implementation. + * + * @param str pointer to the beginning of a valid UTF-8 JSON string, must end with an unescaped quote. + * @param dst pointer to a destination buffer, it must point a region in memory of sufficient size. + * @param allow_replacement whether we allow a replacement character when the UTF-8 contains unmatched surrogate pairs. + * @return end of the of the written region (exclusive) or nullptr in case of error. + */ + simdjson_warn_unused virtual uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept = 0; + + /** + * Unescape a NON-valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + * + * Overridden by each implementation. + * + * @param str pointer to the beginning of a possibly invalid UTF-8 JSON string, must end with an unescaped quote. + * @param dst pointer to a destination buffer, it must point a region in memory of sufficient size. + * @return end of the of the written region (exclusive) or nullptr in case of error. + */ + simdjson_warn_unused virtual uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept = 0; + + /** + * Change the capacity of this parser. + * + * The capacity can never exceed SIMDJSON_MAXSIZE_BYTES (e.g., 4 GB) + * and an CAPACITY error is returned if it is attempted. + * + * Generally used for reallocation. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. + * @return The error code, or SUCCESS if there was no error. + */ + virtual error_code set_capacity(size_t capacity) noexcept = 0; + + /** + * Change the max depth of this parser. + * + * Generally used for reallocation. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. + * @return The error code, or SUCCESS if there was no error. + */ + virtual error_code set_max_depth(size_t max_depth) noexcept = 0; + + /** + * Deallocate this parser. + */ + virtual ~dom_parser_implementation() = default; + + /** Number of structural indices passed from stage 1 to stage 2 */ + uint32_t n_structural_indexes{ 0 }; + /** Structural indices passed from stage 1 to stage 2 */ + std::unique_ptr structural_indexes{}; + /** Next structural index to parse */ + uint32_t next_structural_index{ 0 }; + + /** + * The largest document this parser can support without reallocating. + * + * @return Current capacity, in bytes. + */ + simdjson_inline size_t capacity() const noexcept; + + /** + * The maximum level of nested object and arrays supported by this parser. + * + * @return Maximum depth, in bytes. + */ + simdjson_inline size_t max_depth() const noexcept; + + /** + * Ensure this parser has enough memory to process JSON documents up to `capacity` bytes in length + * and `max_depth` depth. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. Defaults to DEFAULT_MAX_DEPTH. + * @return The error, if there is one. + */ + simdjson_warn_unused inline error_code allocate(size_t capacity, size_t max_depth) noexcept; + + + protected: + /** + * The maximum document length this parser supports. + * + * Buffers are large enough to handle any document up to this length. + */ + size_t _capacity{ 0 }; + + /** + * The maximum depth (number of nested objects and arrays) supported by this parser. + * + * Defaults to DEFAULT_MAX_DEPTH. + */ + size_t _max_depth{ 0 }; + + // Declaring these so that subclasses can use them to implement their constructors. + simdjson_inline dom_parser_implementation() noexcept; + simdjson_inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + simdjson_inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + + simdjson_inline dom_parser_implementation(const dom_parser_implementation&) noexcept = delete; + simdjson_inline dom_parser_implementation& operator=(const dom_parser_implementation& other) noexcept = delete; + }; // class dom_parser_implementation + + simdjson_inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + simdjson_inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + simdjson_inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + simdjson_inline size_t dom_parser_implementation::capacity() const noexcept { + return _capacity; + } + + simdjson_inline size_t dom_parser_implementation::max_depth() const noexcept { + return _max_depth; + } + + simdjson_warn_unused + inline error_code dom_parser_implementation::allocate(size_t capacity, size_t max_depth) noexcept { + if (this->max_depth() != max_depth) { + error_code err = set_max_depth(max_depth); + if (err) { return err; } + } + if (_capacity != capacity) { + error_code err = set_capacity(capacity); + if (err) { return err; } + } + return SUCCESS; + } + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/internal/dom_parser_implementation.h */ + +#include + +namespace simdjson { + + /** + * Validate the UTF-8 string. + * + * @param buf the string to validate. + * @param len the length of the string in bytes. + * @return true if the string is valid UTF-8. + */ + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) noexcept; + /** + * Validate the UTF-8 string. + * + * @param sv the string_view to validate. + * @return true if the string is valid UTF-8. + */ + simdjson_inline simdjson_warn_unused bool validate_utf8(const std::string_view sv) noexcept { + return validate_utf8(sv.data(), sv.size()); + } + + /** + * Validate the UTF-8 string. + * + * @param p the string to validate. + * @return true if the string is valid UTF-8. + */ + simdjson_inline simdjson_warn_unused bool validate_utf8(const std::string& s) noexcept { + return validate_utf8(s.data(), s.size()); + } + + /** + * An implementation of simdjson for a particular CPU architecture. + * + * Also used to maintain the currently active implementation. The active implementation is + * automatically initialized on first use to the most advanced implementation supported by the host. + */ + class implementation { + public: + + /** + * The name of this implementation. + * + * const implementation *impl = simdjson::get_active_implementation(); + * cout << "simdjson is optimized for " << impl->name() << "(" << impl->description() << ")" << endl; + * + * @return the name of the implementation, e.g. "haswell", "westmere", "arm64". + */ + virtual const std::string& name() const { return _name; } + + /** + * The description of this implementation. + * + * const implementation *impl = simdjson::get_active_implementation(); + * cout << "simdjson is optimized for " << impl->name() << "(" << impl->description() << ")" << endl; + * + * @return the description of the implementation, e.g. "Intel/AMD AVX2", "Intel/AMD SSE4.2", "ARM NEON". + */ + virtual const std::string& description() const { return _description; } + + /** + * The instruction sets this implementation is compiled against + * and the current CPU match. This function may poll the current CPU/system + * and should therefore not be called too often if performance is a concern. + * + * @return true if the implementation can be safely used on the current system (determined at runtime). + */ + bool supported_by_runtime_system() const; + + /** + * @private For internal implementation use + * + * The instruction sets this implementation is compiled against. + * + * @return a mask of all required `internal::instruction_set::` values. + */ + virtual uint32_t required_instruction_sets() const { return _required_instruction_sets; } + + /** + * @private For internal implementation use + * + * const implementation *impl = simdjson::get_active_implementation(); + * cout << "simdjson is optimized for " << impl->name() << "(" << impl->description() << ")" << endl; + * + * @param capacity The largest document that will be passed to the parser. + * @param max_depth The maximum JSON object/array nesting this parser is expected to handle. + * @param dst The place to put the resulting parser implementation. + * @return the error code, or SUCCESS if there was no error. + */ + virtual error_code create_dom_parser_implementation( + size_t capacity, + size_t max_depth, + std::unique_ptr& dst + ) const noexcept = 0; + + /** + * @private For internal implementation use + * + * Minify the input string assuming that it represents a JSON string, does not parse or validate. + * + * Overridden by each implementation. + * + * @param buf the json document to minify. + * @param len the length of the json document. + * @param dst the buffer to write the minified document to. *MUST* be allocated up to len + SIMDJSON_PADDING bytes. + * @param dst_len the number of bytes written. Output only. + * @return the error code, or SUCCESS if there was no error. + */ + simdjson_warn_unused virtual error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept = 0; + + + /** + * Validate the UTF-8 string. + * + * Overridden by each implementation. + * + * @param buf the string to validate. + * @param len the length of the string in bytes. + * @return true if and only if the string is valid UTF-8. + */ + simdjson_warn_unused virtual bool validate_utf8(const char* buf, size_t len) const noexcept = 0; + + protected: + /** @private Construct an implementation with the given name and description. For subclasses. */ + simdjson_inline implementation( + std::string_view name, + std::string_view description, + uint32_t required_instruction_sets + ) : + _name(name), + _description(description), + _required_instruction_sets(required_instruction_sets) + { + } + virtual ~implementation() = default; + + private: + /** + * The name of this implementation. + */ + const std::string _name; + + /** + * The description of this implementation. + */ + const std::string _description; + + /** + * Instruction sets required for this implementation. + */ + const uint32_t _required_instruction_sets; + }; + + /** @private */ + namespace internal { + + /** + * The list of available implementations compiled into simdjson. + */ + class available_implementation_list { + public: + /** Get the list of available implementations compiled into simdjson */ + simdjson_inline available_implementation_list() {} + /** Number of implementations */ + size_t size() const noexcept; + /** STL const begin() iterator */ + const implementation* const* begin() const noexcept; + /** STL const end() iterator */ + const implementation* const* end() const noexcept; + + /** + * Get the implementation with the given name. + * + * Case sensitive. + * + * const implementation *impl = simdjson::get_available_implementations()["westmere"]; + * if (!impl) { exit(1); } + * if (!imp->supported_by_runtime_system()) { exit(1); } + * simdjson::get_active_implementation() = impl; + * + * @param name the implementation to find, e.g. "westmere", "haswell", "arm64" + * @return the implementation, or nullptr if the parse failed. + */ + const implementation* operator[](const std::string_view& name) const noexcept { + for (const implementation* impl : *this) { + if (impl->name() == name) { return impl; } + } + return nullptr; + } + + /** + * Detect the most advanced implementation supported by the current host. + * + * This is used to initialize the implementation on startup. + * + * const implementation *impl = simdjson::available_implementation::detect_best_supported(); + * simdjson::get_active_implementation() = impl; + * + * @return the most advanced supported implementation for the current host, or an + * implementation that returns UNSUPPORTED_ARCHITECTURE if there is no supported + * implementation. Will never return nullptr. + */ + const implementation* detect_best_supported() const noexcept; + }; + + } // namespace internal + + /** + * The list of available implementations compiled into simdjson. + */ + extern SIMDJSON_DLLIMPORTEXPORT const internal::available_implementation_list& get_available_implementations(); + + /** + * The active implementation. + * + * Automatically initialized on first use to the most advanced implementation supported by this hardware. + */ + extern SIMDJSON_DLLIMPORTEXPORT internal::atomic_ptr& get_active_implementation(); + +} // namespace simdjson + +#endif // SIMDJSON_IMPLEMENTATION_H +/* end file simdjson/implementation.h */ +/* skipped duplicate #include "simdjson/implementation_detection.h" */ +/* including simdjson/internal/instruction_set.h: #include "simdjson/internal/instruction_set.h" */ +/* begin file simdjson/internal/instruction_set.h */ +/* From +https://github.com/endorno/pytorch/blob/master/torch/lib/TH/generic/simd/simd.h +Highly modified. + +Copyright (c) 2016- Facebook, Inc (Adam Paszke) +Copyright (c) 2014- Facebook, Inc (Soumith Chintala) +Copyright (c) 2011-2014 Idiap Research Institute (Ronan Collobert) +Copyright (c) 2012-2014 Deepmind Technologies (Koray Kavukcuoglu) +Copyright (c) 2011-2012 NEC Laboratories America (Koray Kavukcuoglu) +Copyright (c) 2011-2013 NYU (Clement Farabet) +Copyright (c) 2006-2010 NEC Laboratories America (Ronan Collobert, Leon Bottou, +Iain Melvin, Jason Weston) Copyright (c) 2006 Idiap Research Institute +(Samy Bengio) Copyright (c) 2001-2004 Idiap Research Institute (Ronan Collobert, +Samy Bengio, Johnny Mariethoz) + +All rights reserved. + +Redistribution and use in source and binary forms, with or without +modification, are permitted provided that the following conditions are met: + +1. Redistributions of source code must retain the above copyright + notice, this list of conditions and the following disclaimer. + +2. Redistributions in binary form must reproduce the above copyright + notice, this list of conditions and the following disclaimer in the + documentation and/or other materials provided with the distribution. + +3. Neither the names of Facebook, Deepmind Technologies, NYU, NEC Laboratories +America and IDIAP Research Institute nor the names of its contributors may be + used to endorse or promote products derived from this software without + specific prior written permission. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" +AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE +IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE +ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE +LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR +CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF +SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS +INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN +CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) +ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE +POSSIBILITY OF SUCH DAMAGE. +*/ + +#ifndef SIMDJSON_INTERNAL_INSTRUCTION_SET_H +#define SIMDJSON_INTERNAL_INSTRUCTION_SET_H + +namespace simdjson { + namespace internal { + + enum instruction_set { + DEFAULT = 0x0, + NEON = 0x1, + AVX2 = 0x4, + SSE42 = 0x8, + PCLMULQDQ = 0x10, + BMI1 = 0x20, + BMI2 = 0x40, + ALTIVEC = 0x80, + AVX512F = 0x100, + AVX512DQ = 0x200, + AVX512IFMA = 0x400, + AVX512PF = 0x800, + AVX512ER = 0x1000, + AVX512CD = 0x2000, + AVX512BW = 0x4000, + AVX512VL = 0x8000, + AVX512VBMI2 = 0x10000 + }; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_INSTRUCTION_SET_H +/* end file simdjson/internal/instruction_set.h */ +/* skipped duplicate #include "simdjson/internal/dom_parser_implementation.h" */ +/* skipped duplicate #include "simdjson/internal/jsoncharutils_tables.h" */ +/* skipped duplicate #include "simdjson/internal/numberparsing_tables.h" */ +/* including simdjson/internal/simdprune_tables.h: #include "simdjson/internal/simdprune_tables.h" */ +/* begin file simdjson/internal/simdprune_tables.h */ +#ifndef SIMDJSON_INTERNAL_SIMDPRUNE_TABLES_H +#define SIMDJSON_INTERNAL_SIMDPRUNE_TABLES_H + +/* skipped duplicate #include "simdjson/base.h" */ + +#include + +namespace simdjson { // table modified and copied from + namespace internal { // http://graphics.stanford.edu/~seander/bithacks.html#CountBitsSetTable + + extern SIMDJSON_DLLIMPORTEXPORT const unsigned char BitsSetTable256mul2[256]; + + extern SIMDJSON_DLLIMPORTEXPORT const uint8_t pshufb_combine_table[272]; + + // 256 * 8 bytes = 2kB, easily fits in cache. + extern SIMDJSON_DLLIMPORTEXPORT const uint64_t thintable_epi8[256]; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_SIMDPRUNE_TABLES_H +/* end file simdjson/internal/simdprune_tables.h */ + +#endif // SIMDJSON_GENERIC_DEPENDENCIES_H +/* end file simdjson/generic/dependencies.h */ +/* including generic/dependencies.h: #include */ +/* begin file generic/dependencies.h */ +#ifdef SIMDJSON_CONDITIONAL_INCLUDE +#error generic/dependencies.h must be included before defining SIMDJSON_CONDITIONAL_INCLUDE! +#endif + +#ifndef SIMDJSON_SRC_GENERIC_DEPENDENCIES_H +#define SIMDJSON_SRC_GENERIC_DEPENDENCIES_H + +/* skipped duplicate #include */ + +#endif // SIMDJSON_SRC_GENERIC_DEPENDENCIES_H +/* end file generic/dependencies.h */ +/* including generic/stage1/dependencies.h: #include */ +/* begin file generic/stage1/dependencies.h */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_DEPENDENCIES_H +#define SIMDJSON_SRC_GENERIC_STAGE1_DEPENDENCIES_H + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_DEPENDENCIES_H +/* end file generic/stage1/dependencies.h */ +/* including generic/stage2/dependencies.h: #include */ +/* begin file generic/stage2/dependencies.h */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_DEPENDENCIES_H +#define SIMDJSON_SRC_GENERIC_STAGE2_DEPENDENCIES_H + +/* including simdjson/dom/document.h: #include */ +/* begin file simdjson/dom/document.h */ +#ifndef SIMDJSON_DOM_DOCUMENT_H +#define SIMDJSON_DOM_DOCUMENT_H + +/* including simdjson/dom/base.h: #include "simdjson/dom/base.h" */ +/* begin file simdjson/dom/base.h */ +#ifndef SIMDJSON_DOM_BASE_H +#define SIMDJSON_DOM_BASE_H + +/* skipped duplicate #include "simdjson/base.h" */ + +namespace simdjson { + + /** + * @brief A DOM API on top of the simdjson parser. + */ + namespace dom { + + /** The default batch size for parser.parse_many() and parser.load_many() */ + static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; + /** + * Some adversary might try to set the batch size to 0 or 1, which might cause problems. + * We set a minimum of 32B since anything else is highly likely to be an error. In practice, + * most users will want a much larger batch size. + * + * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON + * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. + */ + static constexpr size_t MINIMAL_BATCH_SIZE = 32; + + /** + * It is wasteful to allocate memory for tiny documents (e.g., 4 bytes). + */ + static constexpr size_t MINIMAL_DOCUMENT_CAPACITY = 32; + + class array; + class document; + class document_stream; + class element; + class key_value_pair; + class object; + class parser; + +#ifdef SIMDJSON_THREADS_ENABLED + struct stage1_worker; +#endif // SIMDJSON_THREADS_ENABLED + + } // namespace dom + + namespace internal { + + template + class string_builder; + class tape_ref; + + } // namespace internal + +} // namespace simdjson + +#endif // SIMDJSON_DOM_BASE_H +/* end file simdjson/dom/base.h */ + +#include + +namespace simdjson { + namespace dom { + + /** + * A parsed JSON document. + * + * This class cannot be copied, only moved, to avoid unintended allocations. + */ + class document { + public: + /** + * Create a document container with zero capacity. + * + * The parser will allocate capacity as needed. + */ + document() noexcept = default; + ~document() noexcept = default; + + /** + * Take another document's buffers. + * + * @param other The document to take. Its capacity is zeroed and it is invalidated. + */ + document(document&& other) noexcept = default; + /** @private */ + document(const document&) = delete; // Disallow copying + /** + * Take another document's buffers. + * + * @param other The document to take. Its capacity is zeroed. + */ + document& operator=(document&& other) noexcept = default; + /** @private */ + document& operator=(const document&) = delete; // Disallow copying + + /** + * Get the root element of this document as a JSON array. + */ + element root() const noexcept; + + /** + * @private Dump the raw tape for debugging. + * + * @param os the stream to output to. + * @return false if the tape is likely wrong (e.g., you did not parse a valid JSON). + */ + bool dump_raw_tape(std::ostream& os) const noexcept; + + /** @private Structural values. */ + std::unique_ptr tape{}; + + /** @private String values. + * + * Should be at least byte_capacity. + */ + std::unique_ptr string_buf{}; + /** @private Allocate memory to support + * input JSON documents of up to len bytes. + * + * When calling this function, you lose + * all the data. + * + * The memory allocation is strict: you + * can you use this function to increase + * or lower the amount of allocated memory. + * Passsing zero clears the memory. + */ + error_code allocate(size_t len) noexcept; + /** @private Capacity in bytes, in terms + * of how many bytes of input JSON we can + * support. + */ + size_t capacity() const noexcept; + + + private: + size_t allocated_capacity{ 0 }; + friend class parser; + }; // class document + + } // namespace dom +} // namespace simdjson + +#endif // SIMDJSON_DOM_DOCUMENT_H +/* end file simdjson/dom/document.h */ +/* including simdjson/internal/tape_type.h: #include */ +/* begin file simdjson/internal/tape_type.h */ +#ifndef SIMDJSON_INTERNAL_TAPE_TYPE_H +#define SIMDJSON_INTERNAL_TAPE_TYPE_H + +namespace simdjson { + namespace internal { + + /** + * The possible types in the tape. + */ + enum class tape_type { + ROOT = 'r', + START_ARRAY = '[', + START_OBJECT = '{', + END_ARRAY = ']', + END_OBJECT = '}', + STRING = '"', + INT64 = 'l', + UINT64 = 'u', + DOUBLE = 'd', + TRUE_VALUE = 't', + FALSE_VALUE = 'f', + NULL_VALUE = 'n' + }; // enum class tape_type + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_TAPE_TYPE_H +/* end file simdjson/internal/tape_type.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_DEPENDENCIES_H +/* end file generic/stage2/dependencies.h */ + +/* including implementation.cpp: #include */ +/* begin file implementation.cpp */ +#ifndef SIMDJSON_SRC_IMPLEMENTATION_CPP +#define SIMDJSON_SRC_IMPLEMENTATION_CPP + +/* skipped duplicate #include */ +/* skipped duplicate #include */ +/* skipped duplicate #include */ +/* including internal/isadetection.h: #include */ +/* begin file internal/isadetection.h */ +/* From +https://github.com/endorno/pytorch/blob/master/torch/lib/TH/generic/simd/simd.h +Highly modified. + +Copyright (c) 2016- Facebook, Inc (Adam Paszke) +Copyright (c) 2014- Facebook, Inc (Soumith Chintala) +Copyright (c) 2011-2014 Idiap Research Institute (Ronan Collobert) +Copyright (c) 2012-2014 Deepmind Technologies (Koray Kavukcuoglu) +Copyright (c) 2011-2012 NEC Laboratories America (Koray Kavukcuoglu) +Copyright (c) 2011-2013 NYU (Clement Farabet) +Copyright (c) 2006-2010 NEC Laboratories America (Ronan Collobert, Leon Bottou, +Iain Melvin, Jason Weston) Copyright (c) 2006 Idiap Research Institute +(Samy Bengio) Copyright (c) 2001-2004 Idiap Research Institute (Ronan Collobert, +Samy Bengio, Johnny Mariethoz) + +All rights reserved. + +Redistribution and use in source and binary forms, with or without +modification, are permitted provided that the following conditions are met: + +1. Redistributions of source code must retain the above copyright + notice, this list of conditions and the following disclaimer. + +2. Redistributions in binary form must reproduce the above copyright + notice, this list of conditions and the following disclaimer in the + documentation and/or other materials provided with the distribution. + +3. Neither the names of Facebook, Deepmind Technologies, NYU, NEC Laboratories +America and IDIAP Research Institute nor the names of its contributors may be + used to endorse or promote products derived from this software without + specific prior written permission. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" +AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE +IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE +ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE +LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR +CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF +SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS +INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN +CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) +ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE +POSSIBILITY OF SUCH DAMAGE. +*/ + +#ifndef SIMDJSON_INTERNAL_ISADETECTION_H +#define SIMDJSON_INTERNAL_ISADETECTION_H + +/* skipped duplicate #include "simdjson/internal/instruction_set.h" */ + +#include +#include +#if defined(_MSC_VER) +#include +#elif defined(HAVE_GCC_GET_CPUID) && defined(USE_GCC_GET_CPUID) +#include +#endif + +namespace simdjson { + namespace internal { + +#if defined(__PPC64__) + + static inline uint32_t detect_supported_architectures() { + return instruction_set::ALTIVEC; + } + +#elif defined(__aarch64__) || defined(_M_ARM64) + + static inline uint32_t detect_supported_architectures() { + return instruction_set::NEON; + } + +#elif defined(__x86_64__) || defined(_M_AMD64) // x64 + + + namespace { + // Can be found on Intel ISA Reference for CPUID + constexpr uint32_t cpuid_avx2_bit = 1 << 5; ///< @private Bit 5 of EBX for EAX=0x7 + constexpr uint32_t cpuid_bmi1_bit = 1 << 3; ///< @private bit 3 of EBX for EAX=0x7 + constexpr uint32_t cpuid_bmi2_bit = 1 << 8; ///< @private bit 8 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512f_bit = 1 << 16; ///< @private bit 16 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512dq_bit = 1 << 17; ///< @private bit 17 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512ifma_bit = 1 << 21; ///< @private bit 21 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512pf_bit = 1 << 26; ///< @private bit 26 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512er_bit = 1 << 27; ///< @private bit 27 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512cd_bit = 1 << 28; ///< @private bit 28 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512bw_bit = 1 << 30; ///< @private bit 30 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512vl_bit = 1U << 31; ///< @private bit 31 of EBX for EAX=0x7 + constexpr uint32_t cpuid_avx512vbmi2_bit = 1 << 6; ///< @private bit 6 of ECX for EAX=0x7 + constexpr uint64_t cpuid_avx256_saved = uint64_t(1) << 2; ///< @private bit 2 = AVX + constexpr uint64_t cpuid_avx512_saved = uint64_t(7) << 5; ///< @private bits 5,6,7 = opmask, ZMM_hi256, hi16_ZMM + constexpr uint32_t cpuid_sse42_bit = 1 << 20; ///< @private bit 20 of ECX for EAX=0x1 + constexpr uint32_t cpuid_osxsave = (uint32_t(1) << 26) | (uint32_t(1) << 27); ///< @private bits 26+27 of ECX for EAX=0x1 + constexpr uint32_t cpuid_pclmulqdq_bit = 1 << 1; ///< @private bit 1 of ECX for EAX=0x1 + } + + + + static inline void cpuid(uint32_t* eax, uint32_t* ebx, uint32_t* ecx, + uint32_t* edx) { +#if defined(_MSC_VER) + int cpu_info[4]; + __cpuidex(cpu_info, *eax, *ecx); + *eax = cpu_info[0]; + *ebx = cpu_info[1]; + *ecx = cpu_info[2]; + *edx = cpu_info[3]; +#elif defined(HAVE_GCC_GET_CPUID) && defined(USE_GCC_GET_CPUID) + uint32_t level = *eax; + __get_cpuid(level, eax, ebx, ecx, edx); +#else + uint32_t a = *eax, b, c = *ecx, d; + asm volatile("cpuid\n\t" : "+a"(a), "=b"(b), "+c"(c), "=d"(d)); + *eax = a; + *ebx = b; + *ecx = c; + *edx = d; +#endif + } + + + static inline uint64_t xgetbv() { +#if defined(_MSC_VER) + return _xgetbv(0); +#else + uint32_t xcr0_lo, xcr0_hi; + asm volatile("xgetbv\n\t" : "=a" (xcr0_lo), "=d" (xcr0_hi) : "c" (0)); + return xcr0_lo | (uint64_t(xcr0_hi) << 32); +#endif + } + + static inline uint32_t detect_supported_architectures() { + uint32_t eax, ebx, ecx, edx; + uint32_t host_isa = 0x0; + + // EBX for EAX=0x1 + eax = 0x1; + ecx = 0x0; + cpuid(&eax, &ebx, &ecx, &edx); + + if (ecx & cpuid_sse42_bit) { + host_isa |= instruction_set::SSE42; + } + else { + return host_isa; // everything after is redundant + } + + if (ecx & cpuid_pclmulqdq_bit) { + host_isa |= instruction_set::PCLMULQDQ; + } + + + if ((ecx & cpuid_osxsave) != cpuid_osxsave) { + return host_isa; + } + + // xgetbv for checking if the OS saves registers + uint64_t xcr0 = xgetbv(); + + if ((xcr0 & cpuid_avx256_saved) == 0) { + return host_isa; + } + + // ECX for EAX=0x7 + eax = 0x7; + ecx = 0x0; + cpuid(&eax, &ebx, &ecx, &edx); + if (ebx & cpuid_avx2_bit) { + host_isa |= instruction_set::AVX2; + } + if (ebx & cpuid_bmi1_bit) { + host_isa |= instruction_set::BMI1; + } + + if (ebx & cpuid_bmi2_bit) { + host_isa |= instruction_set::BMI2; + } + + if (!((xcr0 & cpuid_avx512_saved) == cpuid_avx512_saved)) { + return host_isa; + } + + if (ebx & cpuid_avx512f_bit) { + host_isa |= instruction_set::AVX512F; + } + + if (ebx & cpuid_avx512dq_bit) { + host_isa |= instruction_set::AVX512DQ; + } + + if (ebx & cpuid_avx512ifma_bit) { + host_isa |= instruction_set::AVX512IFMA; + } + + if (ebx & cpuid_avx512pf_bit) { + host_isa |= instruction_set::AVX512PF; + } + + if (ebx & cpuid_avx512er_bit) { + host_isa |= instruction_set::AVX512ER; + } + + if (ebx & cpuid_avx512cd_bit) { + host_isa |= instruction_set::AVX512CD; + } + + if (ebx & cpuid_avx512bw_bit) { + host_isa |= instruction_set::AVX512BW; + } + + if (ebx & cpuid_avx512vl_bit) { + host_isa |= instruction_set::AVX512VL; + } + + if (ecx & cpuid_avx512vbmi2_bit) { + host_isa |= instruction_set::AVX512VBMI2; + } + + return host_isa; + } +#else // fallback + + + static inline uint32_t detect_supported_architectures() { + return instruction_set::DEFAULT; + } + + +#endif // end SIMD extension detection code + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_ISADETECTION_H +/* end file internal/isadetection.h */ + #include namespace simdjson { @@ -2638,48 +6922,314 @@ namespace simdjson { return ((supported_instruction_sets & required_instruction_sets) == required_instruction_sets); } - namespace internal { +} // namespace simdjson - // Static array of known implementations. We're hoping these get baked into the executable - // without requiring a static initializer. +/* defining SIMDJSON_CONDITIONAL_INCLUDE */ +#define SIMDJSON_CONDITIONAL_INCLUDE -#if SIMDJSON_IMPLEMENTATION_ICELAKE - static const icelake::implementation* get_icelake_singleton() { - static const icelake::implementation icelake_singleton{}; - return &icelake_singleton; - } -#endif -#if SIMDJSON_IMPLEMENTATION_HASWELL - static const haswell::implementation* get_haswell_singleton() { - static const haswell::implementation haswell_singleton{}; - return &haswell_singleton; - } -#endif -#if SIMDJSON_IMPLEMENTATION_WESTMERE - static const westmere::implementation* get_westmere_singleton() { - static const westmere::implementation westmere_singleton{}; - return &westmere_singleton; - } -#endif // SIMDJSON_IMPLEMENTATION_WESTMERE #if SIMDJSON_IMPLEMENTATION_ARM64 +/* including simdjson/arm64/implementation.h: #include */ +/* begin file simdjson/arm64/implementation.h */ +#ifndef SIMDJSON_ARM64_IMPLEMENTATION_H +#define SIMDJSON_ARM64_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation("arm64", "ARM NEON", internal::instruction_set::NEON) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_IMPLEMENTATION_H +/* end file simdjson/arm64/implementation.h */ +namespace simdjson { + namespace internal { static const arm64::implementation* get_arm64_singleton() { static const arm64::implementation arm64_singleton{}; return &arm64_singleton; } + } // namespace internal +} // namespace simdjson #endif // SIMDJSON_IMPLEMENTATION_ARM64 -#if SIMDJSON_IMPLEMENTATION_PPC64 - static const ppc64::implementation* get_ppc64_singleton() { - static const ppc64::implementation ppc64_singleton{}; - return &ppc64_singleton; - } -#endif // SIMDJSON_IMPLEMENTATION_PPC64 + #if SIMDJSON_IMPLEMENTATION_FALLBACK +/* including simdjson/fallback/implementation.h: #include */ +/* begin file simdjson/fallback/implementation.h */ +#ifndef SIMDJSON_FALLBACK_IMPLEMENTATION_H +#define SIMDJSON_FALLBACK_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "fallback", + "Generic fallback implementation", + 0 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_IMPLEMENTATION_H +/* end file simdjson/fallback/implementation.h */ +namespace simdjson { + namespace internal { static const fallback::implementation* get_fallback_singleton() { static const fallback::implementation fallback_singleton{}; return &fallback_singleton; } + } // namespace internal +} // namespace simdjson #endif // SIMDJSON_IMPLEMENTATION_FALLBACK + +#if SIMDJSON_IMPLEMENTATION_HASWELL +/* including simdjson/haswell/implementation.h: #include */ +/* begin file simdjson/haswell/implementation.h */ +#ifndef SIMDJSON_HASWELL_IMPLEMENTATION_H +#define SIMDJSON_HASWELL_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL +namespace simdjson { + namespace haswell { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "haswell", + "Intel/AMD AVX2", + internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_IMPLEMENTATION_H +/* end file simdjson/haswell/implementation.h */ +namespace simdjson { + namespace internal { + static const haswell::implementation* get_haswell_singleton() { + static const haswell::implementation haswell_singleton{}; + return &haswell_singleton; + } + } // namespace internal +} // namespace simdjson +#endif + +#if SIMDJSON_IMPLEMENTATION_ICELAKE +/* including simdjson/icelake/implementation.h: #include */ +/* begin file simdjson/icelake/implementation.h */ +#ifndef SIMDJSON_ICELAKE_IMPLEMENTATION_H +#define SIMDJSON_ICELAKE_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE +namespace simdjson { + namespace icelake { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "icelake", + "Intel/AMD AVX512", + internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 | internal::instruction_set::AVX512F | internal::instruction_set::AVX512DQ | internal::instruction_set::AVX512CD | internal::instruction_set::AVX512BW | internal::instruction_set::AVX512VL | internal::instruction_set::AVX512VBMI2 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_IMPLEMENTATION_H +/* end file simdjson/icelake/implementation.h */ +namespace simdjson { + namespace internal { + static const icelake::implementation* get_icelake_singleton() { + static const icelake::implementation icelake_singleton{}; + return &icelake_singleton; + } + } // namespace internal +} // namespace simdjson +#endif + +#if SIMDJSON_IMPLEMENTATION_PPC64 +/* including simdjson/ppc64/implementation.h: #include */ +/* begin file simdjson/ppc64/implementation.h */ +#ifndef SIMDJSON_PPC64_IMPLEMENTATION_H +#define SIMDJSON_PPC64_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + /** + * Implementation for ALTIVEC (PPC64). + */ + namespace ppc64 { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() + : simdjson::implementation("ppc64", "PPC64 ALTIVEC", + internal::instruction_set::ALTIVEC) {} + + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, size_t max_length, + std::unique_ptr& dst) + const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, + uint8_t* dst, + size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, + size_t len) const noexcept final; + }; + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_IMPLEMENTATION_H +/* end file simdjson/ppc64/implementation.h */ +namespace simdjson { + namespace internal { + static const ppc64::implementation* get_ppc64_singleton() { + static const ppc64::implementation ppc64_singleton{}; + return &ppc64_singleton; + } + } // namespace internal +} // namespace simdjson +#endif // SIMDJSON_IMPLEMENTATION_PPC64 + +#if SIMDJSON_IMPLEMENTATION_WESTMERE +/* including simdjson/westmere/implementation.h: #include */ +/* begin file simdjson/westmere/implementation.h */ +#ifndef SIMDJSON_WESTMERE_IMPLEMENTATION_H +#define SIMDJSON_WESTMERE_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + namespace westmere { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation("westmere", "Intel/AMD SSE4.2", internal::instruction_set::SSE42 | internal::instruction_set::PCLMULQDQ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_IMPLEMENTATION_H +/* end file simdjson/westmere/implementation.h */ +namespace simdjson { + namespace internal { + static const simdjson::westmere::implementation* get_westmere_singleton() { + static const simdjson::westmere::implementation westmere_singleton{}; + return &westmere_singleton; + } + } // namespace internal +} // namespace simdjson +#endif // SIMDJSON_IMPLEMENTATION_WESTMERE + +/* undefining SIMDJSON_CONDITIONAL_INCLUDE */ +#undef SIMDJSON_CONDITIONAL_INCLUDE + +namespace simdjson { + namespace internal { + + // Static array of known implementations. We're hoping these get baked into the executable + // without requiring a static initializer. + /** * @private Detects best supported implementation on first use, and sets it */ @@ -2824,55 +7374,3632 @@ namespace simdjson { return builtin_impl; } - } // namespace simdjson -/* end file src/implementation.cpp */ + +#endif // SIMDJSON_SRC_IMPLEMENTATION_CPP +/* end file implementation.cpp */ + +/* defining SIMDJSON_CONDITIONAL_INCLUDE */ +#define SIMDJSON_CONDITIONAL_INCLUDE #if SIMDJSON_IMPLEMENTATION_ARM64 -/* begin file src/arm64/implementation.cpp */ -/* begin file include/simdjson/arm64/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "arm64" -// #define SIMDJSON_IMPLEMENTATION arm64 -/* end file include/simdjson/arm64/begin.h */ +/* including arm64.cpp: #include */ +/* begin file arm64.cpp */ +#ifndef SIMDJSON_SRC_ARM64_CPP +#define SIMDJSON_SRC_ARM64_CPP + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* including simdjson/arm64.h: #include */ +/* begin file simdjson/arm64.h */ +#ifndef SIMDJSON_ARM64_H +#define SIMDJSON_ARM64_H + +/* including simdjson/arm64/begin.h: #include "simdjson/arm64/begin.h" */ +/* begin file simdjson/arm64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "arm64" */ +#define SIMDJSON_IMPLEMENTATION arm64 +/* including simdjson/arm64/base.h: #include "simdjson/arm64/base.h" */ +/* begin file simdjson/arm64/base.h */ +#ifndef SIMDJSON_ARM64_BASE_H +#define SIMDJSON_ARM64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for NEON (ARMv8). + */ + namespace arm64 { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_BASE_H +/* end file simdjson/arm64/base.h */ +/* including simdjson/arm64/intrinsics.h: #include "simdjson/arm64/intrinsics.h" */ +/* begin file simdjson/arm64/intrinsics.h */ +#ifndef SIMDJSON_ARM64_INTRINSICS_H +#define SIMDJSON_ARM64_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This should be the correct header whether +// you use visual studio or other compilers. +#include + +static_assert(sizeof(uint8x16_t) <= simdjson::SIMDJSON_PADDING, "insufficient padding for arm64"); + +#endif // SIMDJSON_ARM64_INTRINSICS_H +/* end file simdjson/arm64/intrinsics.h */ +/* including simdjson/arm64/bitmanipulation.h: #include "simdjson/arm64/bitmanipulation.h" */ +/* begin file simdjson/arm64/bitmanipulation.h */ +#ifndef SIMDJSON_ARM64_BITMANIPULATION_H +#define SIMDJSON_ARM64_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int count_ones(uint64_t input_num) { + return vaddv_u8(vcnt_u8(vcreate_u8(input_num))); + } + + +#if defined(__GNUC__) // catches clang and gcc + /** + * ARM has a fast 64-bit "bit reversal function" that is handy. However, + * it is not generally available as an intrinsic function under Visual + * Studio (though this might be changing). Even under clang/gcc, we + * apparently need to invoke inline assembly. + */ + /* + * We use SIMDJSON_PREFER_REVERSE_BITS as a hint that algorithms that + * work well with bit reversal may use it. + */ +#define SIMDJSON_PREFER_REVERSE_BITS 1 + + /* reverse the bits */ + simdjson_inline uint64_t reverse_bits(uint64_t input_num) { + uint64_t rev_bits; + __asm("rbit %0, %1" : "=r"(rev_bits) : "r"(input_num)); + return rev_bits; + } + + /** + * Flips bit at index 63 - lz. Thus if you have 'leading_zeroes' leading zeroes, + * then this will set to zero the leading bit. It is possible for leading_zeroes to be + * greating or equal to 63 in which case we trigger undefined behavior, but the output + * of such undefined behavior is never used. + **/ + SIMDJSON_NO_SANITIZE_UNDEFINED + simdjson_inline uint64_t zero_leading_bit(uint64_t rev_bits, int leading_zeroes) { + return rev_bits ^ (uint64_t(0x8000000000000000) >> leading_zeroes); + } + +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, uint64_t* result) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + * result = value1 + value2; + return *result < value1; +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_BITMANIPULATION_H +/* end file simdjson/arm64/bitmanipulation.h */ +/* including simdjson/arm64/bitmask.h: #include "simdjson/arm64/bitmask.h" */ +/* begin file simdjson/arm64/bitmask.h */ +#ifndef SIMDJSON_ARM64_BITMASK_H +#define SIMDJSON_ARM64_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(uint64_t bitmask) { + ///////////// + // We could do this with PMULL, but it is apparently slow. + // + //#ifdef __ARM_FEATURE_CRYPTO // some ARM processors lack this extension + //return vmull_p64(-1ULL, bitmask); + //#else + // Analysis by @sebpop: + // When diffing the assembly for src/stage1_find_marks.cpp I see that the eors are all spread out + // in between other vector code, so effectively the extra cycles of the sequence do not matter + // because the GPR units are idle otherwise and the critical path is on the FP side. + // Also the PMULL requires two extra fmovs: GPR->FP (3 cycles in N1, 5 cycles in A72 ) + // and FP->GPR (2 cycles on N1 and 5 cycles on A72.) + /////////// + bitmask ^= bitmask << 1; + bitmask ^= bitmask << 2; + bitmask ^= bitmask << 4; + bitmask ^= bitmask << 8; + bitmask ^= bitmask << 16; + bitmask ^= bitmask << 32; + return bitmask; + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif +/* end file simdjson/arm64/bitmask.h */ +/* including simdjson/arm64/numberparsing_defs.h: #include "simdjson/arm64/numberparsing_defs.h" */ +/* begin file simdjson/arm64/numberparsing_defs.h */ +#ifndef SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +#define SIMDJSON_ARM64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if _M_ARM64 +// __umulh requires intrin.h +#include +#endif // _M_ARM64 + +namespace simdjson { + namespace arm64 { + namespace numberparsing { + + // we don't have SSE, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace arm64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +/* end file simdjson/arm64/numberparsing_defs.h */ +/* including simdjson/arm64/simd.h: #include "simdjson/arm64/simd.h" */ +/* begin file simdjson/arm64/simd.h */ +#ifndef SIMDJSON_ARM64_SIMD_H +#define SIMDJSON_ARM64_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + namespace simd { + +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + namespace { + // Start of private section with Visual Studio workaround + + +#ifndef simdjson_make_uint8x16_t +#define simdjson_make_uint8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + uint8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x16_t +#define simdjson_make_int8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + int8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_s8(array); \ + }()) +#endif + +#ifndef simdjson_make_uint8x8_t +#define simdjson_make_uint8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x8_t +#define simdjson_make_int8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_s8(array); \ + }()) +#endif +#ifndef simdjson_make_uint16x8_t +#define simdjson_make_uint16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_u16(array); \ + }()) +#endif +#ifndef simdjson_make_int16x8_t +#define simdjson_make_int16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_s16(array); \ + }()) +#endif + +// End of private section with Visual Studio workaround + } // namespace +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + + + template + struct simd8; + + // + // Base class of simd8 and simd8, both of which use uint8x16_t internally. + // + template> + struct base_u8 { + uint8x16_t value; + static const int SIZE = sizeof(value); + + // Conversion from/to SIMD register + simdjson_inline base_u8(const uint8x16_t _value) : value(_value) {} + simdjson_inline operator const uint8x16_t& () const { return this->value; } + simdjson_inline operator uint8x16_t& () { return this->value; } + + // Bit operations + simdjson_inline simd8 operator|(const simd8 other) const { return vorrq_u8(*this, other); } + simdjson_inline simd8 operator&(const simd8 other) const { return vandq_u8(*this, other); } + simdjson_inline simd8 operator^(const simd8 other) const { return veorq_u8(*this, other); } + simdjson_inline simd8 bit_andnot(const simd8 other) const { return vbicq_u8(*this, other); } + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + simdjson_inline simd8& operator|=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline simd8& operator&=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline simd8& operator^=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast ^ other; return *this_cast; } + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return vceqq_u8(lhs, rhs); } + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return vextq_u8(prev_chunk, *this, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base_u8 { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + static simdjson_inline simd8 splat(bool _value) { return vmovq_n_u8(uint8_t(-(!!_value))); } + + simdjson_inline simd8(const uint8x16_t _value) : base_u8(_value) {} + // False constructor + simdjson_inline simd8() : simd8(vdupq_n_u8(0)) {} + // Splat constructor + simdjson_inline simd8(bool _value) : simd8(splat(_value)) {} + + // We return uint32_t instead of uint16_t because that seems to be more efficient for most + // purposes (cutting it down to uint16_t costs performance in some compilers). + simdjson_inline uint32_t to_bitmask() const { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + const uint8x16_t bit_mask = simdjson_make_uint8x16_t(0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80); +#else + const uint8x16_t bit_mask = { 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 }; +#endif + auto minput = *this & bit_mask; + uint8x16_t tmp = vpaddq_u8(minput, minput); + tmp = vpaddq_u8(tmp, tmp); + tmp = vpaddq_u8(tmp, tmp); + return vgetq_lane_u16(vreinterpretq_u16_u8(tmp), 0); + } + simdjson_inline bool any() const { return vmaxvq_u8(*this) != 0; } + }; + + // Unsigned bytes + template<> + struct simd8 : base_u8 { + static simdjson_inline uint8x16_t splat(uint8_t _value) { return vmovq_n_u8(_value); } + static simdjson_inline uint8x16_t zero() { return vdupq_n_u8(0); } + static simdjson_inline uint8x16_t load(const uint8_t* values) { return vld1q_u8(values); } + + simdjson_inline simd8(const uint8x16_t _value) : base_u8(_value) {} + // Zero constructor + simdjson_inline simd8() : simd8(zero()) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[16]) : simd8(load(values)) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Member-by-member initialization +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(simdjson_make_uint8x16_t( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} +#else + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(uint8x16_t{ + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10,v11,v12,v13,v14,v15 + }) {} +#endif + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Store to array + simdjson_inline void store(uint8_t dst[16]) const { return vst1q_u8(dst, *this); } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return vqaddq_u8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return vqsubq_u8(*this, other); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return vaddq_u8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return vsubq_u8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *this; } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *this; } + + // Order-specific operations + simdjson_inline uint8_t max_val() const { return vmaxvq_u8(*this); } + simdjson_inline uint8_t min_val() const { return vminvq_u8(*this); } + simdjson_inline simd8 max_val(const simd8 other) const { return vmaxq_u8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return vminq_u8(*this, other); } + simdjson_inline simd8 operator<=(const simd8 other) const { return vcleq_u8(*this, other); } + simdjson_inline simd8 operator>=(const simd8 other) const { return vcgeq_u8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return vcltq_u8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return vcgtq_u8(*this, other); } + // Same as >, but instead of guaranteeing all 1's == true, false = 0 and true = nonzero. For ARM, returns all 1's. + simdjson_inline simd8 gt_bits(const simd8 other) const { return simd8(*this > other); } + // Same as <, but instead of guaranteeing all 1's == true, false = 0 and true = nonzero. For ARM, returns all 1's. + simdjson_inline simd8 lt_bits(const simd8 other) const { return simd8(*this < other); } + + // Bit-specific operations + simdjson_inline simd8 any_bits_set(simd8 bits) const { return vtstq_u8(*this, bits); } + simdjson_inline bool any_bits_set_anywhere() const { return this->max_val() != 0; } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return (*this & bits).any_bits_set_anywhere(); } + template + simdjson_inline simd8 shr() const { return vshrq_n_u8(*this, N); } + template + simdjson_inline simd8 shl() const { return vshlq_n_u8(*this, N); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return lookup_table.apply_lookup_16_to(*this); + } + + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint16_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + uint64x2_t shufmask64 = { thintable_epi8[mask1], thintable_epi8[mask2] }; + uint8x16_t shufmask = vreinterpretq_u8_u64(shufmask64); + // we increment by 0x08 the second half of the mask +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + uint8x16_t inc = simdjson_make_uint8x16_t(0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); +#else + uint8x16_t inc = { 0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; +#endif + shufmask = vaddq_u8(shufmask, inc); + // this is the version "nearly pruned" + uint8x16_t pruned = vqtbl1q_u8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + uint8x16_t compactmask = vld1q_u8(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + uint8x16_t answer = vqtbl1q_u8(pruned, compactmask); + vst1q_u8(reinterpret_cast(output), answer); + } + + // Copies all bytes corresponding to a 0 in the low half of the mask (interpreted as a + // bitset) to output1, then those corresponding to a 0 in the high half to output2. + template + simdjson_inline void compress_halves(uint16_t mask, L* output1, L* output2) const { + using internal::thintable_epi8; + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + uint8x8_t compactmask1 = vcreate_u8(thintable_epi8[mask1]); + uint8x8_t compactmask2 = vcreate_u8(thintable_epi8[mask2]); + // we increment by 0x08 the second half of the mask +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + uint8x8_t inc = simdjson_make_uint8x8_t(0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); +#else + uint8x8_t inc = { 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; +#endif + compactmask2 = vadd_u8(compactmask2, inc); + // store each result (with the second store possibly overlapping the first) + vst1_u8((uint8_t*)output1, vqtbl1_u8(*this, compactmask1)); + vst1_u8((uint8_t*)output2, vqtbl1_u8(*this, compactmask2)); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + + template + simdjson_inline simd8 apply_lookup_16_to(const simd8 original) { + return vqtbl1q_u8(*this, simd8(original)); + } + }; + + // Signed bytes + template<> + struct simd8 { + int8x16_t value; + + static simdjson_inline simd8 splat(int8_t _value) { return vmovq_n_s8(_value); } + static simdjson_inline simd8 zero() { return vdupq_n_s8(0); } + static simdjson_inline simd8 load(const int8_t values[16]) { return vld1q_s8(values); } + + // Conversion from/to SIMD register + simdjson_inline simd8(const int8x16_t _value) : value{ _value } {} + simdjson_inline operator const int8x16_t& () const { return this->value; } + simdjson_inline operator int8x16_t& () { return this->value; } + + // Zero constructor + simdjson_inline simd8() : simd8(zero()) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(simdjson_make_int8x16_t( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} +#else + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(int8x16_t{ + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10,v11,v12,v13,v14,v15 + }) {} +#endif + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Store to array + simdjson_inline void store(int8_t dst[16]) const { return vst1q_s8(dst, *this); } + + // Explicit conversion to/from unsigned + // + // Under Visual Studio/ARM64 uint8x16_t and int8x16_t are apparently the same type. + // In theory, we could check this occurrence with std::same_as and std::enabled_if but it is C++14 + // and relatively ugly and hard to read. +#ifndef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline explicit simd8(const uint8x16_t other) : simd8(vreinterpretq_s8_u8(other)) {} +#endif + simdjson_inline explicit operator simd8() const { return vreinterpretq_u8_s8(this->value); } + + // Math + simdjson_inline simd8 operator+(const simd8 other) const { return vaddq_s8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return vsubq_s8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *this; } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *this; } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return vmaxq_s8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return vminq_s8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return vcgtq_s8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return vcltq_s8(*this, other); } + simdjson_inline simd8 operator==(const simd8 other) const { return vceqq_s8(*this, other); } + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return vextq_s8(prev_chunk, *this, 16 - N); + } + + // Perform a lookup assuming no value is larger than 16 + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return lookup_table.apply_lookup_16_to(*this); + } + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + + template + simdjson_inline simd8 apply_lookup_16_to(const simd8 original) { + return vqtbl1q_s8(*this, simd8(original)); + } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "ARM kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + uint64_t popcounts = vget_lane_u64(vreinterpret_u64_u8(vcnt_u8(vcreate_u8(~mask))), 0); + // compute the prefix sum of the popcounts of each byte + uint64_t offsets = popcounts * 0x0101010101010101; + this->chunks[0].compress_halves(uint16_t(mask), output, &output[popcounts & 0xFF]); + this->chunks[1].compress_halves(uint16_t(mask >> 16), &output[(offsets >> 8) & 0xFF], &output[(offsets >> 16) & 0xFF]); + this->chunks[2].compress_halves(uint16_t(mask >> 32), &output[(offsets >> 24) & 0xFF], &output[(offsets >> 32) & 0xFF]); + this->chunks[3].compress_halves(uint16_t(mask >> 48), &output[(offsets >> 40) & 0xFF], &output[(offsets >> 48) & 0xFF]); + return offsets >> 56; + } + + simdjson_inline uint64_t to_bitmask() const { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + const uint8x16_t bit_mask = simdjson_make_uint8x16_t( + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 + ); +#else + const uint8x16_t bit_mask = { + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 + }; +#endif + // Add each of the elements next to each other, successively, to stuff each 8 byte mask into one. + uint8x16_t sum0 = vpaddq_u8(this->chunks[0] & bit_mask, this->chunks[1] & bit_mask); + uint8x16_t sum1 = vpaddq_u8(this->chunks[2] & bit_mask, this->chunks[3] & bit_mask); + sum0 = vpaddq_u8(sum0, sum1); + sum0 = vpaddq_u8(sum0, sum0); + return vgetq_lane_u64(vreinterpretq_u64_u8(sum0), 0); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_SIMD_H +/* end file simdjson/arm64/simd.h */ +/* including simdjson/arm64/stringparsing_defs.h: #include "simdjson/arm64/stringparsing_defs.h" */ +/* begin file simdjson/arm64/stringparsing_defs.h */ +#ifndef SIMDJSON_ARM64_STRINGPARSING_DEFS_H +#define SIMDJSON_ARM64_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + sizeof(v0)); + v0.store(dst); + v1.store(dst + sizeof(v0)); + + // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on ARM; therefore, we + // smash them together into a 64-byte mask and get the bitmask from there. + uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_STRINGPARSING_DEFS_H +/* end file simdjson/arm64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/arm64/begin.h */ +/* including simdjson/generic/amalgamated.h for arm64: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for arm64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for arm64: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for arm64 */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { - simdjson_warn_unused error_code implementation::create_dom_parser_implementation( - size_t capacity, - size_t max_depth, - std::unique_ptr& dst - ) const noexcept { - dst.reset(new (std::nothrow) dom_parser_implementation()); - if (!dst) { return MEMALLOC; } - if (auto err = dst->set_capacity(capacity)) - return err; - if (auto err = dst->set_max_depth(max_depth)) - return err; + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for arm64 */ +/* including simdjson/generic/jsoncharutils.h for arm64: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for arm64 */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + namespace jsoncharutils { + + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for arm64 */ +/* including simdjson/generic/atomparsing.h for arm64: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace arm64 { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for arm64 */ +/* including simdjson/generic/dom_parser_implementation.h for arm64: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for arm64 */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container + + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); + + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; + + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; + + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; + + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + namespace arm64 { + + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; + } + + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; return SUCCESS; } } // namespace arm64 } // namespace simdjson -/* begin file include/simdjson/arm64/end.h */ -/* end file include/simdjson/arm64/end.h */ -/* end file src/arm64/implementation.cpp */ -/* begin file src/arm64/dom_parser_implementation.cpp */ -/* begin file include/simdjson/arm64/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "arm64" -// #define SIMDJSON_IMPLEMENTATION arm64 -/* end file include/simdjson/arm64/begin.h */ +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for arm64 */ +/* including simdjson/generic/implementation_simdjson_result_base.h for arm64: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for arm64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); + + +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for arm64 */ +/* including simdjson/generic/numberparsing.h for arm64: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for arm64 */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace arm64 { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing // -// Stage 1 +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. // +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for arm64 */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for arm64: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for arm64 */ +/* end file simdjson/generic/amalgamated.h for arm64 */ +/* including simdjson/arm64/end.h: #include "simdjson/arm64/end.h" */ +/* begin file simdjson/arm64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "arm64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/arm64/end.h */ + +#endif // SIMDJSON_ARM64_H +/* end file simdjson/arm64.h */ +/* including simdjson/arm64/implementation.h: #include */ +/* begin file simdjson/arm64/implementation.h */ +#ifndef SIMDJSON_ARM64_IMPLEMENTATION_H +#define SIMDJSON_ARM64_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation("arm64", "ARM NEON", internal::instruction_set::NEON) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_IMPLEMENTATION_H +/* end file simdjson/arm64/implementation.h */ + +/* including simdjson/arm64/begin.h: #include */ +/* begin file simdjson/arm64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "arm64" */ +#define SIMDJSON_IMPLEMENTATION arm64 +/* including simdjson/arm64/base.h: #include "simdjson/arm64/base.h" */ +/* begin file simdjson/arm64/base.h */ +#ifndef SIMDJSON_ARM64_BASE_H +#define SIMDJSON_ARM64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for NEON (ARMv8). + */ + namespace arm64 { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_BASE_H +/* end file simdjson/arm64/base.h */ +/* including simdjson/arm64/intrinsics.h: #include "simdjson/arm64/intrinsics.h" */ +/* begin file simdjson/arm64/intrinsics.h */ +#ifndef SIMDJSON_ARM64_INTRINSICS_H +#define SIMDJSON_ARM64_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This should be the correct header whether +// you use visual studio or other compilers. +#include + +static_assert(sizeof(uint8x16_t) <= simdjson::SIMDJSON_PADDING, "insufficient padding for arm64"); + +#endif // SIMDJSON_ARM64_INTRINSICS_H +/* end file simdjson/arm64/intrinsics.h */ +/* including simdjson/arm64/bitmanipulation.h: #include "simdjson/arm64/bitmanipulation.h" */ +/* begin file simdjson/arm64/bitmanipulation.h */ +#ifndef SIMDJSON_ARM64_BITMANIPULATION_H +#define SIMDJSON_ARM64_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int count_ones(uint64_t input_num) { + return vaddv_u8(vcnt_u8(vcreate_u8(input_num))); + } + + +#if defined(__GNUC__) // catches clang and gcc + /** + * ARM has a fast 64-bit "bit reversal function" that is handy. However, + * it is not generally available as an intrinsic function under Visual + * Studio (though this might be changing). Even under clang/gcc, we + * apparently need to invoke inline assembly. + */ + /* + * We use SIMDJSON_PREFER_REVERSE_BITS as a hint that algorithms that + * work well with bit reversal may use it. + */ +#define SIMDJSON_PREFER_REVERSE_BITS 1 + + /* reverse the bits */ + simdjson_inline uint64_t reverse_bits(uint64_t input_num) { + uint64_t rev_bits; + __asm("rbit %0, %1" : "=r"(rev_bits) : "r"(input_num)); + return rev_bits; + } + + /** + * Flips bit at index 63 - lz. Thus if you have 'leading_zeroes' leading zeroes, + * then this will set to zero the leading bit. It is possible for leading_zeroes to be + * greating or equal to 63 in which case we trigger undefined behavior, but the output + * of such undefined behavior is never used. + **/ + SIMDJSON_NO_SANITIZE_UNDEFINED + simdjson_inline uint64_t zero_leading_bit(uint64_t rev_bits, int leading_zeroes) { + return rev_bits ^ (uint64_t(0x8000000000000000) >> leading_zeroes); + } + +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, uint64_t* result) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + * result = value1 + value2; + return *result < value1; +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_BITMANIPULATION_H +/* end file simdjson/arm64/bitmanipulation.h */ +/* including simdjson/arm64/bitmask.h: #include "simdjson/arm64/bitmask.h" */ +/* begin file simdjson/arm64/bitmask.h */ +#ifndef SIMDJSON_ARM64_BITMASK_H +#define SIMDJSON_ARM64_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(uint64_t bitmask) { + ///////////// + // We could do this with PMULL, but it is apparently slow. + // + //#ifdef __ARM_FEATURE_CRYPTO // some ARM processors lack this extension + //return vmull_p64(-1ULL, bitmask); + //#else + // Analysis by @sebpop: + // When diffing the assembly for src/stage1_find_marks.cpp I see that the eors are all spread out + // in between other vector code, so effectively the extra cycles of the sequence do not matter + // because the GPR units are idle otherwise and the critical path is on the FP side. + // Also the PMULL requires two extra fmovs: GPR->FP (3 cycles in N1, 5 cycles in A72 ) + // and FP->GPR (2 cycles on N1 and 5 cycles on A72.) + /////////// + bitmask ^= bitmask << 1; + bitmask ^= bitmask << 2; + bitmask ^= bitmask << 4; + bitmask ^= bitmask << 8; + bitmask ^= bitmask << 16; + bitmask ^= bitmask << 32; + return bitmask; + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif +/* end file simdjson/arm64/bitmask.h */ +/* including simdjson/arm64/numberparsing_defs.h: #include "simdjson/arm64/numberparsing_defs.h" */ +/* begin file simdjson/arm64/numberparsing_defs.h */ +#ifndef SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +#define SIMDJSON_ARM64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if _M_ARM64 +// __umulh requires intrin.h +#include +#endif // _M_ARM64 + +namespace simdjson { + namespace arm64 { + namespace numberparsing { + + // we don't have SSE, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace arm64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +/* end file simdjson/arm64/numberparsing_defs.h */ +/* including simdjson/arm64/simd.h: #include "simdjson/arm64/simd.h" */ +/* begin file simdjson/arm64/simd.h */ +#ifndef SIMDJSON_ARM64_SIMD_H +#define SIMDJSON_ARM64_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + namespace simd { + +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + namespace { + // Start of private section with Visual Studio workaround + + +#ifndef simdjson_make_uint8x16_t +#define simdjson_make_uint8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + uint8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x16_t +#define simdjson_make_int8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + int8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_s8(array); \ + }()) +#endif + +#ifndef simdjson_make_uint8x8_t +#define simdjson_make_uint8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x8_t +#define simdjson_make_int8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_s8(array); \ + }()) +#endif +#ifndef simdjson_make_uint16x8_t +#define simdjson_make_uint16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_u16(array); \ + }()) +#endif +#ifndef simdjson_make_int16x8_t +#define simdjson_make_int16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_s16(array); \ + }()) +#endif + +// End of private section with Visual Studio workaround + } // namespace +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + + + template + struct simd8; + + // + // Base class of simd8 and simd8, both of which use uint8x16_t internally. + // + template> + struct base_u8 { + uint8x16_t value; + static const int SIZE = sizeof(value); + + // Conversion from/to SIMD register + simdjson_inline base_u8(const uint8x16_t _value) : value(_value) {} + simdjson_inline operator const uint8x16_t& () const { return this->value; } + simdjson_inline operator uint8x16_t& () { return this->value; } + + // Bit operations + simdjson_inline simd8 operator|(const simd8 other) const { return vorrq_u8(*this, other); } + simdjson_inline simd8 operator&(const simd8 other) const { return vandq_u8(*this, other); } + simdjson_inline simd8 operator^(const simd8 other) const { return veorq_u8(*this, other); } + simdjson_inline simd8 bit_andnot(const simd8 other) const { return vbicq_u8(*this, other); } + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + simdjson_inline simd8& operator|=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline simd8& operator&=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline simd8& operator^=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast ^ other; return *this_cast; } + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return vceqq_u8(lhs, rhs); } + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return vextq_u8(prev_chunk, *this, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base_u8 { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + static simdjson_inline simd8 splat(bool _value) { return vmovq_n_u8(uint8_t(-(!!_value))); } + + simdjson_inline simd8(const uint8x16_t _value) : base_u8(_value) {} + // False constructor + simdjson_inline simd8() : simd8(vdupq_n_u8(0)) {} + // Splat constructor + simdjson_inline simd8(bool _value) : simd8(splat(_value)) {} + + // We return uint32_t instead of uint16_t because that seems to be more efficient for most + // purposes (cutting it down to uint16_t costs performance in some compilers). + simdjson_inline uint32_t to_bitmask() const { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + const uint8x16_t bit_mask = simdjson_make_uint8x16_t(0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80); +#else + const uint8x16_t bit_mask = { 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 }; +#endif + auto minput = *this & bit_mask; + uint8x16_t tmp = vpaddq_u8(minput, minput); + tmp = vpaddq_u8(tmp, tmp); + tmp = vpaddq_u8(tmp, tmp); + return vgetq_lane_u16(vreinterpretq_u16_u8(tmp), 0); + } + simdjson_inline bool any() const { return vmaxvq_u8(*this) != 0; } + }; + + // Unsigned bytes + template<> + struct simd8 : base_u8 { + static simdjson_inline uint8x16_t splat(uint8_t _value) { return vmovq_n_u8(_value); } + static simdjson_inline uint8x16_t zero() { return vdupq_n_u8(0); } + static simdjson_inline uint8x16_t load(const uint8_t* values) { return vld1q_u8(values); } + + simdjson_inline simd8(const uint8x16_t _value) : base_u8(_value) {} + // Zero constructor + simdjson_inline simd8() : simd8(zero()) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[16]) : simd8(load(values)) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Member-by-member initialization +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(simdjson_make_uint8x16_t( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} +#else + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(uint8x16_t{ + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10,v11,v12,v13,v14,v15 + }) {} +#endif + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Store to array + simdjson_inline void store(uint8_t dst[16]) const { return vst1q_u8(dst, *this); } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return vqaddq_u8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return vqsubq_u8(*this, other); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return vaddq_u8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return vsubq_u8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *this; } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *this; } + + // Order-specific operations + simdjson_inline uint8_t max_val() const { return vmaxvq_u8(*this); } + simdjson_inline uint8_t min_val() const { return vminvq_u8(*this); } + simdjson_inline simd8 max_val(const simd8 other) const { return vmaxq_u8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return vminq_u8(*this, other); } + simdjson_inline simd8 operator<=(const simd8 other) const { return vcleq_u8(*this, other); } + simdjson_inline simd8 operator>=(const simd8 other) const { return vcgeq_u8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return vcltq_u8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return vcgtq_u8(*this, other); } + // Same as >, but instead of guaranteeing all 1's == true, false = 0 and true = nonzero. For ARM, returns all 1's. + simdjson_inline simd8 gt_bits(const simd8 other) const { return simd8(*this > other); } + // Same as <, but instead of guaranteeing all 1's == true, false = 0 and true = nonzero. For ARM, returns all 1's. + simdjson_inline simd8 lt_bits(const simd8 other) const { return simd8(*this < other); } + + // Bit-specific operations + simdjson_inline simd8 any_bits_set(simd8 bits) const { return vtstq_u8(*this, bits); } + simdjson_inline bool any_bits_set_anywhere() const { return this->max_val() != 0; } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return (*this & bits).any_bits_set_anywhere(); } + template + simdjson_inline simd8 shr() const { return vshrq_n_u8(*this, N); } + template + simdjson_inline simd8 shl() const { return vshlq_n_u8(*this, N); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return lookup_table.apply_lookup_16_to(*this); + } + + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint16_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + uint64x2_t shufmask64 = { thintable_epi8[mask1], thintable_epi8[mask2] }; + uint8x16_t shufmask = vreinterpretq_u8_u64(shufmask64); + // we increment by 0x08 the second half of the mask +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + uint8x16_t inc = simdjson_make_uint8x16_t(0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); +#else + uint8x16_t inc = { 0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; +#endif + shufmask = vaddq_u8(shufmask, inc); + // this is the version "nearly pruned" + uint8x16_t pruned = vqtbl1q_u8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + uint8x16_t compactmask = vld1q_u8(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + uint8x16_t answer = vqtbl1q_u8(pruned, compactmask); + vst1q_u8(reinterpret_cast(output), answer); + } + + // Copies all bytes corresponding to a 0 in the low half of the mask (interpreted as a + // bitset) to output1, then those corresponding to a 0 in the high half to output2. + template + simdjson_inline void compress_halves(uint16_t mask, L* output1, L* output2) const { + using internal::thintable_epi8; + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + uint8x8_t compactmask1 = vcreate_u8(thintable_epi8[mask1]); + uint8x8_t compactmask2 = vcreate_u8(thintable_epi8[mask2]); + // we increment by 0x08 the second half of the mask +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + uint8x8_t inc = simdjson_make_uint8x8_t(0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); +#else + uint8x8_t inc = { 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; +#endif + compactmask2 = vadd_u8(compactmask2, inc); + // store each result (with the second store possibly overlapping the first) + vst1_u8((uint8_t*)output1, vqtbl1_u8(*this, compactmask1)); + vst1_u8((uint8_t*)output2, vqtbl1_u8(*this, compactmask2)); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + + template + simdjson_inline simd8 apply_lookup_16_to(const simd8 original) { + return vqtbl1q_u8(*this, simd8(original)); + } + }; + + // Signed bytes + template<> + struct simd8 { + int8x16_t value; + + static simdjson_inline simd8 splat(int8_t _value) { return vmovq_n_s8(_value); } + static simdjson_inline simd8 zero() { return vdupq_n_s8(0); } + static simdjson_inline simd8 load(const int8_t values[16]) { return vld1q_s8(values); } + + // Conversion from/to SIMD register + simdjson_inline simd8(const int8x16_t _value) : value{ _value } {} + simdjson_inline operator const int8x16_t& () const { return this->value; } + simdjson_inline operator int8x16_t& () { return this->value; } + + // Zero constructor + simdjson_inline simd8() : simd8(zero()) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(simdjson_make_int8x16_t( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} +#else + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(int8x16_t{ + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10,v11,v12,v13,v14,v15 + }) {} +#endif + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Store to array + simdjson_inline void store(int8_t dst[16]) const { return vst1q_s8(dst, *this); } + + // Explicit conversion to/from unsigned + // + // Under Visual Studio/ARM64 uint8x16_t and int8x16_t are apparently the same type. + // In theory, we could check this occurrence with std::same_as and std::enabled_if but it is C++14 + // and relatively ugly and hard to read. +#ifndef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline explicit simd8(const uint8x16_t other) : simd8(vreinterpretq_s8_u8(other)) {} +#endif + simdjson_inline explicit operator simd8() const { return vreinterpretq_u8_s8(this->value); } + + // Math + simdjson_inline simd8 operator+(const simd8 other) const { return vaddq_s8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return vsubq_s8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *this; } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *this; } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return vmaxq_s8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return vminq_s8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return vcgtq_s8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return vcltq_s8(*this, other); } + simdjson_inline simd8 operator==(const simd8 other) const { return vceqq_s8(*this, other); } + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return vextq_s8(prev_chunk, *this, 16 - N); + } + + // Perform a lookup assuming no value is larger than 16 + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return lookup_table.apply_lookup_16_to(*this); + } + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + + template + simdjson_inline simd8 apply_lookup_16_to(const simd8 original) { + return vqtbl1q_s8(*this, simd8(original)); + } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "ARM kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + uint64_t popcounts = vget_lane_u64(vreinterpret_u64_u8(vcnt_u8(vcreate_u8(~mask))), 0); + // compute the prefix sum of the popcounts of each byte + uint64_t offsets = popcounts * 0x0101010101010101; + this->chunks[0].compress_halves(uint16_t(mask), output, &output[popcounts & 0xFF]); + this->chunks[1].compress_halves(uint16_t(mask >> 16), &output[(offsets >> 8) & 0xFF], &output[(offsets >> 16) & 0xFF]); + this->chunks[2].compress_halves(uint16_t(mask >> 32), &output[(offsets >> 24) & 0xFF], &output[(offsets >> 32) & 0xFF]); + this->chunks[3].compress_halves(uint16_t(mask >> 48), &output[(offsets >> 40) & 0xFF], &output[(offsets >> 48) & 0xFF]); + return offsets >> 56; + } + + simdjson_inline uint64_t to_bitmask() const { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + const uint8x16_t bit_mask = simdjson_make_uint8x16_t( + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 + ); +#else + const uint8x16_t bit_mask = { + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 + }; +#endif + // Add each of the elements next to each other, successively, to stuff each 8 byte mask into one. + uint8x16_t sum0 = vpaddq_u8(this->chunks[0] & bit_mask, this->chunks[1] & bit_mask); + uint8x16_t sum1 = vpaddq_u8(this->chunks[2] & bit_mask, this->chunks[3] & bit_mask); + sum0 = vpaddq_u8(sum0, sum1); + sum0 = vpaddq_u8(sum0, sum0); + return vgetq_lane_u64(vreinterpretq_u64_u8(sum0), 0); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_SIMD_H +/* end file simdjson/arm64/simd.h */ +/* including simdjson/arm64/stringparsing_defs.h: #include "simdjson/arm64/stringparsing_defs.h" */ +/* begin file simdjson/arm64/stringparsing_defs.h */ +#ifndef SIMDJSON_ARM64_STRINGPARSING_DEFS_H +#define SIMDJSON_ARM64_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace arm64 { namespace { using namespace simd; + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + sizeof(v0)); + v0.store(dst); + v1.store(dst + sizeof(v0)); + + // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on ARM; therefore, we + // smash them together into a 64-byte mask and get the bitmask from there. + uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_STRINGPARSING_DEFS_H +/* end file simdjson/arm64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/arm64/begin.h */ +/* including generic/amalgamated.h for arm64: #include */ +/* begin file generic/amalgamated.h for arm64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_SRC_GENERIC_DEPENDENCIES_H) +#error generic/dependencies.h must be included before generic/amalgamated.h! +#endif + +/* including generic/base.h for arm64: #include */ +/* begin file generic/base.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + struct json_character_block; + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_BASE_H +/* end file generic/base.h for arm64 */ +/* including generic/dom_parser_implementation.h for arm64: #include */ +/* begin file generic/dom_parser_implementation.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// Interface a dom parser implementation must fulfill +namespace simdjson { + namespace arm64 { + namespace { + + simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3); + simdjson_inline bool is_ascii(const simd8x64& input); + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file generic/dom_parser_implementation.h for arm64 */ +/* including generic/json_character_block.h for arm64: #include */ +/* begin file generic/json_character_block.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + struct json_character_block { static simdjson_inline json_character_block classify(const simd::simd8x64& in); @@ -2884,88 +11011,439 @@ namespace simdjson { uint64_t _op; }; - simdjson_inline json_character_block json_character_block::classify(const simd::simd8x64& in) { - // Functional programming causes trouble with Visual Studio. - // Keeping this version in comments since it is much nicer: - // auto v = in.map([&](simd8 chunk) { - // auto nib_lo = chunk & 0xf; - // auto nib_hi = chunk.shr<4>(); - // auto shuf_lo = nib_lo.lookup_16(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0); - // auto shuf_hi = nib_hi.lookup_16(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0); - // return shuf_lo & shuf_hi; - // }); - const simd8 table1(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0); - const simd8 table2(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0); + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson - simd8x64 v( - (in.chunks[0] & 0xf).lookup_16(table1) & (in.chunks[0].shr<4>()).lookup_16(table2), - (in.chunks[1] & 0xf).lookup_16(table1) & (in.chunks[1].shr<4>()).lookup_16(table2), - (in.chunks[2] & 0xf).lookup_16(table1) & (in.chunks[2].shr<4>()).lookup_16(table2), - (in.chunks[3] & 0xf).lookup_16(table1) & (in.chunks[3].shr<4>()).lookup_16(table2) - ); +#endif // SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H +/* end file generic/json_character_block.h for arm64 */ +/* end file generic/amalgamated.h for arm64 */ +/* including generic/stage1/amalgamated.h for arm64: #include */ +/* begin file generic/stage1/amalgamated.h for arm64 */ +// Stuff other things depend on +/* including generic/stage1/base.h for arm64: #include */ +/* begin file generic/stage1/base.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BASE_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ - // We compute whitespace and op separately. If the code later only use one or the - // other, given the fact that all functions are aggressively inlined, we can - // hope that useless computations will be omitted. This is namely case when - // minifying (we only need whitespace). *However* if we only need spaces, - // it is likely that we will still compute 'v' above with two lookup_16: one - // could do it a bit cheaper. This is in contrast with the x64 implementations - // where we can, efficiently, do the white space and structural matching - // separately. One reason for this difference is that on ARM NEON, the table - // lookups either zero or leave unchanged the characters exceeding 0xF whereas - // on x64, the equivalent instruction (pshufb) automatically applies a mask, - // ignoring the 4 most significant bits. Thus the x64 implementation is - // optimized differently. This being said, if you use this code strictly - // just for minification (or just to identify the structural characters), - // there is a small untaken optimization opportunity here. We deliberately - // do not pick it up. +namespace simdjson { + namespace arm64 { + namespace { + namespace stage1 { - uint64_t op = simd8x64( - v.chunks[0].any_bits_set(0x7), - v.chunks[1].any_bits_set(0x7), - v.chunks[2].any_bits_set(0x7), - v.chunks[3].any_bits_set(0x7) - ).to_bitmask(); + class bit_indexer; + template + struct buf_block_reader; + struct json_block; + class json_minifier; + class json_scanner; + struct json_string_block; + class json_string_scanner; + class json_structural_indexer; - uint64_t whitespace = simd8x64( - v.chunks[0].any_bits_set(0x18), - v.chunks[1].any_bits_set(0x18), - v.chunks[2].any_bits_set(0x18), - v.chunks[3].any_bits_set(0x18) - ).to_bitmask(); + } // namespace stage1 - return { whitespace, op }; - } + namespace utf8_validation { + struct utf8_checker; + } // namespace utf8_validation - simdjson_inline bool is_ascii(const simd8x64& input) { - simd8 bits = input.reduce_or(); - return bits.max_val() < 0x80u; - } - - simdjson_unused simdjson_inline simd8 must_be_continuation(const simd8 prev1, const simd8 prev2, const simd8 prev3) { - simd8 is_second_byte = prev1 >= uint8_t(0xc0u); - simd8 is_third_byte = prev2 >= uint8_t(0xe0u); - simd8 is_fourth_byte = prev3 >= uint8_t(0xf0u); - // Use ^ instead of | for is_*_byte, because ^ is commutative, and the caller is using ^ as well. - // This will work fine because we only have to report errors for cases with 0-1 lead bytes. - // Multiple lead bytes implies 2 overlapping multibyte characters, and if that happens, there is - // guaranteed to be at least *one* lead byte that is part of only 1 other multibyte character. - // The error will be detected there. - return is_second_byte ^ is_third_byte ^ is_fourth_byte; - } - - simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3) { - simd8 is_third_byte = prev2 >= uint8_t(0xe0u); - simd8 is_fourth_byte = prev3 >= uint8_t(0xf0u); - return is_third_byte ^ is_fourth_byte; - } + using utf8_validation::utf8_checker; } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */ +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BASE_H +/* end file generic/stage1/base.h for arm64 */ +/* including generic/stage1/buf_block_reader.h for arm64: #include */ +/* begin file generic/stage1/buf_block_reader.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace arm64 { + namespace { + namespace stage1 { + + // Walks through a buffer in block-sized increments, loading the last part with spaces + template + struct buf_block_reader { + public: + simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); + simdjson_inline size_t block_index(); + simdjson_inline bool has_full_block() const; + simdjson_inline const uint8_t* full_block() const; + /** + * Get the last block, padded with spaces. + * + * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this + * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there + * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. + * + * @return the number of effective characters in the last block. + */ + simdjson_inline size_t get_remainder(uint8_t* dst) const; + simdjson_inline void advance(); + private: + const uint8_t* buf; + const size_t len; + const size_t lenminusstep; + size_t idx; + }; + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text_64(const uint8_t* text) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < sizeof(simd8x64); i++) { + buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text(const simd8x64& in) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] < ' ') { buf[i] = '_'; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_input_text(const simd8x64& in, uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] <= ' ') { buf[i] = '_'; } + if (!(mask & (size_t(1) << i))) { buf[i] = ' '; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_mask(uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < 64; i++) { + buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; + } + buf[64] = '\0'; + return buf; + } + + template + simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} + + template + simdjson_inline size_t buf_block_reader::block_index() { return idx; } + + template + simdjson_inline bool buf_block_reader::has_full_block() const { + return idx < lenminusstep; + } + + template + simdjson_inline const uint8_t* buf_block_reader::full_block() const { + return &buf[idx]; + } + + template + simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { + if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers + std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. + std::memcpy(dst, buf + idx, len - idx); + return len - idx; + } + + template + simdjson_inline void buf_block_reader::advance() { + idx += STEP_SIZE; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H +/* end file generic/stage1/buf_block_reader.h for arm64 */ +/* including generic/stage1/json_escape_scanner.h for arm64: #include */ +/* begin file generic/stage1/json_escape_scanner.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + namespace stage1 { + + /** + * Scans for escape characters in JSON, taking care with multiple backslashes (\\n vs. \n). + */ + struct json_escape_scanner { + /** The actual escape characters (the backslashes themselves). */ + uint64_t next_is_escaped = 0ULL; + + struct escaped_and_escape { + /** + * Mask of escaped characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 0100100010100101000 + * n \ \ n \ \ + * ``` + */ + uint64_t escaped; + /** + * Mask of escape characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 1001000101001010001 + * \ \ \ \ \ \ \ + * ``` + */ + uint64_t escape; + }; + + /** + * Get a mask of both escape and escaped characters (the characters following a backslash). + * + * @param potential_escape A mask of the character that can escape others (but could be + * escaped itself). e.g. block.eq('\\') + */ + simdjson_really_inline escaped_and_escape next(uint64_t backslash) noexcept { + +#if !SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT + if (!backslash) { return { next_escaped_without_backslashes(), 0 }; } +#endif + + // | | Mask (shows characters instead of 1's) | Depth | Instructions | + // |--------------------------------|----------------------------------------|-------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | | | + // | | ` even odd even odd odd` | | | + // | potential_escape | ` \ \\\ \\\ \\\\ \\\\ \\\` | 1 | 1 (backslash & ~first_is_escaped) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 5 | 5 (next_escape_and_terminal_code()) + // | escaped | `\ \ n \ n \ \ \ \ \ ` X | 6 | 7 (escape_and_terminal_code ^ (potential_escape | first_is_escaped)) + // | escape | ` \ \ \ \ \ \ \ \ \ \` | 6 | 8 (escape_and_terminal_code & backslash) + // | first_is_escaped | `\ ` | 7 (*) | 9 (escape >> 63) () + // (*) this is not needed until the next iteration + uint64_t escape_and_terminal_code = next_escape_and_terminal_code(backslash & ~this->next_is_escaped); + uint64_t escaped = escape_and_terminal_code ^ (backslash | this->next_is_escaped); + uint64_t escape = escape_and_terminal_code & backslash; + this->next_is_escaped = escape >> 63; + return { escaped, escape }; + } + + private: + static constexpr const uint64_t ODD_BITS = 0xAAAAAAAAAAAAAAAAULL; + + simdjson_really_inline uint64_t next_escaped_without_backslashes() noexcept { + uint64_t escaped = this->next_is_escaped; + this->next_is_escaped = 0; + return escaped; + } + + /** + * Returns a mask of the next escape characters (masking out escaped backslashes), along with + * any non-backslash escape codes. + * + * \n \\n \\\n \\\\n returns: + * \n \ \ \n \ \ + * 11 100 1011 10100 + * + * You are expected to mask out the first bit yourself if the previous block had a trailing + * escape. + * + * & the result with potential_escape to get just the escape characters. + * ^ the result with (potential_escape | first_is_escaped) to get escaped characters. + */ + static simdjson_really_inline uint64_t next_escape_and_terminal_code(uint64_t potential_escape) noexcept { + // If we were to just shift and mask out any odd bits, we'd actually get a *half* right answer: + // any even-aligned backslash runs would be correct! Odd-aligned backslash runs would be + // inverted (\\\ would be 010 instead of 101). + // + // ``` + // string: | ____\\\\_\\\\_____ | + // maybe_escaped | ODD | \ \ \ \ | + // even-aligned ^^^ ^^^^ odd-aligned + // ``` + // + // Taking that into account, our basic strategy is: + // + // 1. Use subtraction to produce a mask with 1's for even-aligned runs and 0's for + // odd-aligned runs. + // 2. XOR all odd bits, which masks out the odd bits in even-aligned runs, and brings IN the + // odd bits in odd-aligned runs. + // 3. & with backslash to clean up any stray bits. + // runs are set to 0, and then XORing with "odd": + // + // | | Mask (shows characters instead of 1's) | Instructions | + // |--------------------------------|----------------------------------------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | + // | | ` even odd even odd odd` | + // | maybe_escaped | ` n \\n \\n \\\_ \\\_ \\` X | 1 (potential_escape << 1) + // | maybe_escaped_and_odd | ` \n_ \\n _ \\\n_ _ \\\__ _\\\_ \\\` | 1 (maybe_escaped | odd) + // | even_series_codes_and_odd | ` n_\\\ _ n_ _\\\\ _ _ ` | 1 (maybe_escaped_and_odd - potential_escape) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 1 (^ odd) + // + + // Escaped characters are characters following an escape. + uint64_t maybe_escaped = potential_escape << 1; + + // To distinguish odd from even escape sequences, therefore, we turn on any *starting* + // escapes that are on an odd byte. (We actually bring in all odd bits, for speed.) + // - Odd runs of backslashes are 0000, and the code at the end ("n" in \n or \\n) is 1. + // - Odd runs of backslashes are 1111, and the code at the end ("n" in \n or \\n) is 0. + // - All other odd bytes are 1, and even bytes are 0. + uint64_t maybe_escaped_and_odd_bits = maybe_escaped | ODD_BITS; + uint64_t even_series_codes_and_odd_bits = maybe_escaped_and_odd_bits - potential_escape; + + // Now we flip all odd bytes back with xor. This: + // - Makes odd runs of backslashes go from 0000 to 1010 + // - Makes even runs of backslashes go from 1111 to 1010 + // - Sets actually-escaped codes to 1 (the n in \n and \\n: \n = 11, \\n = 100) + // - Resets all other bytes to 0 + return even_series_codes_and_odd_bits ^ ODD_BITS; + } + }; + + } // namespace stage1 + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_escape_scanner.h for arm64 */ +/* including generic/stage1/json_string_scanner.h for arm64: #include */ +/* begin file generic/stage1/json_string_scanner.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + namespace stage1 { + + struct json_string_block { + // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 + simdjson_really_inline json_string_block(uint64_t escaped, uint64_t quote, uint64_t in_string) : + _escaped(escaped), _quote(quote), _in_string(in_string) {} + + // Escaped characters (characters following an escape() character) + simdjson_really_inline uint64_t escaped() const { return _escaped; } + // Real (non-backslashed) quotes + simdjson_really_inline uint64_t quote() const { return _quote; } + // Only characters inside the string (not including the quotes) + simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } + // Tail of string (everything except the start quote) + simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; } + + // escaped characters (backslashed--does not include the hex characters after \u) + uint64_t _escaped; + // real quotes (non-escaped ones) + uint64_t _quote; + // string characters (includes start quote but not end quote) + uint64_t _in_string; + }; + + // Scans blocks for string characters, storing the state necessary to do so + class json_string_scanner { + public: + simdjson_really_inline json_string_block next(const simd::simd8x64& in); + // Returns either UNCLOSED_STRING or SUCCESS + simdjson_really_inline error_code finish(); + + private: + // Scans for escape characters + json_escape_scanner escape_scanner{}; + // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). + uint64_t prev_in_string = 0ULL; + }; + + // + // Return a mask of all string characters plus end quotes. + // + // prev_escaped is overflow saying whether the next character is escaped. + // prev_in_string is overflow saying whether we're still in a string. + // + // Backslash sequences outside of quotes will be detected in stage 2. + // + simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { + const uint64_t backslash = in.eq('\\'); + const uint64_t escaped = escape_scanner.next(backslash).escaped; + const uint64_t quote = in.eq('"') & ~escaped; + + // + // prefix_xor flips on bits inside the string (and flips off the end quote). + // + // Then we xor with prev_in_string: if we were in a string already, its effect is flipped + // (characters inside strings are outside, and characters outside strings are inside). + // + const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; + + // + // Check if we're still in a string at the end of the box so the next block will know + // + prev_in_string = uint64_t(static_cast(in_string) >> 63); + + // Use ^ to turn the beginning quote off, and the end quote on. + + // We are returning a function-local object so either we get a move constructor + // or we get copy elision. + return json_string_block(escaped, quote, in_string); + } + + simdjson_really_inline error_code json_string_scanner::finish() { + if (prev_in_string) { + return UNCLOSED_STRING; + } + return SUCCESS; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_string_scanner.h for arm64 */ +/* including generic/stage1/utf8_lookup4_algorithm.h for arm64: #include */ +/* begin file generic/stage1/utf8_lookup4_algorithm.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace arm64 { namespace { @@ -3130,14 +11608,6 @@ namespace simdjson { this->error |= this->prev_incomplete; } -#ifndef SIMDJSON_IF_CONSTEXPR -#if SIMDJSON_CPLUSPLUS17 -#define SIMDJSON_IF_CONSTEXPR if constexpr -#else -#define SIMDJSON_IF_CONSTEXPR if -#endif -#endif - simdjson_inline void check_next_input(const simd8x64& input) { if (simdjson_likely(is_ascii(input))) { this->error |= this->prev_incomplete; @@ -3152,17 +11622,17 @@ namespace simdjson { this->check_utf8_bytes(input.chunks[0], this->prev_input_block); } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - } + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 4) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - this->check_utf8_bytes(input.chunks[2], input.chunks[1]); - this->check_utf8_bytes(input.chunks[3], input.chunks[2]); - } - this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); - this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + this->check_utf8_bytes(input.chunks[2], input.chunks[1]); + this->check_utf8_bytes(input.chunks[3], input.chunks[2]); + } + this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); + this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; } } // do not forget to call check_eof! @@ -3173,268 +11643,23 @@ else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { }; // struct utf8_checker } // namespace utf8_validation - using utf8_validation::utf8_checker; - } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage1/utf8_lookup4_algorithm.h */ -/* begin file src/generic/stage1/json_structural_indexer.h */ -// This file contains the common code every implementation uses in stage1 -// It is intended to be included multiple times and compiled multiple times -// We assume the file in which it is included already includes -// "simdjson/stage1.h" (this simplifies amalgation) -/* begin file src/generic/stage1/buf_block_reader.h */ -namespace simdjson { - namespace arm64 { - namespace { +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H +/* end file generic/stage1/utf8_lookup4_algorithm.h for arm64 */ +/* including generic/stage1/json_scanner.h for arm64: #include */ +/* begin file generic/stage1/json_scanner.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H - // Walks through a buffer in block-sized increments, loading the last part with spaces - template - struct buf_block_reader { - public: - simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); - simdjson_inline size_t block_index(); - simdjson_inline bool has_full_block() const; - simdjson_inline const uint8_t* full_block() const; - /** - * Get the last block, padded with spaces. - * - * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this - * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there - * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. - * - * @return the number of effective characters in the last block. - */ - simdjson_inline size_t get_remainder(uint8_t* dst) const; - simdjson_inline void advance(); - private: - const uint8_t* buf; - const size_t len; - const size_t lenminusstep; - size_t idx; - }; +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text_64(const uint8_t* text) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < sizeof(simd8x64); i++) { - buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text(const simd8x64& in) { - static char buf[sizeof(simd8x64) + 1]; - in.store(reinterpret_cast(buf)); - for (size_t i = 0; i < sizeof(simd8x64); i++) { - if (buf[i] < ' ') { buf[i] = '_'; } - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - simdjson_unused static char* format_mask(uint64_t mask) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < 64; i++) { - buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; - } - buf[64] = '\0'; - return buf; - } - - template - simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} - - template - simdjson_inline size_t buf_block_reader::block_index() { return idx; } - - template - simdjson_inline bool buf_block_reader::has_full_block() const { - return idx < lenminusstep; - } - - template - simdjson_inline const uint8_t* buf_block_reader::full_block() const { - return &buf[idx]; - } - - template - simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { - if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers - std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. - std::memcpy(dst, buf + idx, len - idx); - return len - idx; - } - - template - simdjson_inline void buf_block_reader::advance() { - idx += STEP_SIZE; - } - - } // unnamed namespace - } // namespace arm64 -} // namespace simdjson -/* end file src/generic/stage1/buf_block_reader.h */ -/* begin file src/generic/stage1/json_string_scanner.h */ -namespace simdjson { - namespace arm64 { - namespace { - namespace stage1 { - - struct json_string_block { - // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 - simdjson_inline json_string_block(uint64_t backslash, uint64_t escaped, uint64_t quote, uint64_t in_string) : - _backslash(backslash), _escaped(escaped), _quote(quote), _in_string(in_string) {} - - // Escaped characters (characters following an escape() character) - simdjson_inline uint64_t escaped() const { return _escaped; } - // Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \) - simdjson_inline uint64_t escape() const { return _backslash & ~_escaped; } - // Real (non-backslashed) quotes - simdjson_inline uint64_t quote() const { return _quote; } - // Start quotes of strings - simdjson_inline uint64_t string_start() const { return _quote & _in_string; } - // End quotes of strings - simdjson_inline uint64_t string_end() const { return _quote & ~_in_string; } - // Only characters inside the string (not including the quotes) - simdjson_inline uint64_t string_content() const { return _in_string & ~_quote; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } - // Tail of string (everything except the start quote) - simdjson_inline uint64_t string_tail() const { return _in_string ^ _quote; } - - // backslash characters - uint64_t _backslash; - // escaped characters (backslashed--does not include the hex characters after \u) - uint64_t _escaped; - // real quotes (non-backslashed ones) - uint64_t _quote; - // string characters (includes start quote but not end quote) - uint64_t _in_string; - }; - - // Scans blocks for string characters, storing the state necessary to do so - class json_string_scanner { - public: - simdjson_inline json_string_block next(const simd::simd8x64& in); - // Returns either UNCLOSED_STRING or SUCCESS - simdjson_inline error_code finish(); - - private: - // Intended to be defined by the implementation - simdjson_inline uint64_t find_escaped(uint64_t escape); - simdjson_inline uint64_t find_escaped_branchless(uint64_t escape); - - // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). - uint64_t prev_in_string = 0ULL; - // Whether the first character of the next iteration is escaped. - uint64_t prev_escaped = 0ULL; - }; - - // - // Finds escaped characters (characters following \). - // - // Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively). - // - // Does this by: - // - Shift the escape mask to get potentially escaped characters (characters after backslashes). - // - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not) - // - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not) - // - // To distinguish between escaped sequences starting on even/odd bits, it finds the start of all - // escape sequences, filters out the ones that start on even bits, and adds that to the mask of - // escape sequences. This causes the addition to clear out the sequences starting on odd bits (since - // the start bit causes a carry), and leaves even-bit sequences alone. - // - // Example: - // - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape - // odd_starts | x | x x x | escape & ~even_bits & ~follows_escape - // even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later - // invert_mask | | cxxx c xx c| even_seq << 1 - // follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit - // escaped | x | x x x x x x x x | - // desired | x | x x x x x x x x | - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // - simdjson_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) { - // If there was overflow, pretend the first character isn't a backslash - backslash &= ~prev_escaped; - uint64_t follows_escape = backslash << 1 | prev_escaped; - - // Get sequences starting on even bits by clearing out the odd series using + - const uint64_t even_bits = 0x5555555555555555ULL; - uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape; - uint64_t sequences_starting_on_even_bits; - prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits); - uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes. - - // Mask every other backslashed character as an escaped character - // Flip the mask for sequences that start on even bits, to correct them - return (even_bits ^ invert_mask) & follows_escape; - } - - // - // Return a mask of all string characters plus end quotes. - // - // prev_escaped is overflow saying whether the next character is escaped. - // prev_in_string is overflow saying whether we're still in a string. - // - // Backslash sequences outside of quotes will be detected in stage 2. - // - simdjson_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { - const uint64_t backslash = in.eq('\\'); - const uint64_t escaped = find_escaped(backslash); - const uint64_t quote = in.eq('"') & ~escaped; - - // - // prefix_xor flips on bits inside the string (and flips off the end quote). - // - // Then we xor with prev_in_string: if we were in a string already, its effect is flipped - // (characters inside strings are outside, and characters outside strings are inside). - // - const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; - - // - // Check if we're still in a string at the end of the box so the next block will know - // - // right shift of a signed value expected to be well-defined and standard - // compliant as of C++20, John Regher from Utah U. says this is fine code - // - prev_in_string = uint64_t(static_cast(in_string) >> 63); - - // Use ^ to turn the beginning quote off, and the end quote on. - - // We are returning a function-local object so either we get a move constructor - // or we get copy elision. - return json_string_block( - backslash, - escaped, - quote, - in_string - ); - } - - simdjson_inline error_code json_string_scanner::finish() { - if (prev_in_string) { - return UNCLOSED_STRING; - } - return SUCCESS; - } - - } // namespace stage1 - } // unnamed namespace - } // namespace arm64 -} // namespace simdjson -/* end file src/generic/stage1/json_string_scanner.h */ -/* begin file src/generic/stage1/json_scanner.h */ namespace simdjson { namespace arm64 { namespace { @@ -3592,8 +11817,130 @@ namespace simdjson { } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage1/json_scanner.h */ -/* begin file src/generic/stage1/json_minifier.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H +/* end file generic/stage1/json_scanner.h for arm64 */ + +// All other declarations +/* including generic/stage1/find_next_document_index.h for arm64: #include */ +/* begin file generic/stage1/find_next_document_index.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + namespace stage1 { + + /** + * This algorithm is used to quickly identify the last structural position that + * makes up a complete document. + * + * It does this by going backwards and finding the last *document boundary* (a + * place where one value follows another without a comma between them). If the + * last document (the characters after the boundary) has an equal number of + * start and end brackets, it is considered complete. + * + * Simply put, we iterate over the structural characters, starting from + * the end. We consider that we found the end of a JSON document when the + * first element of the pair is NOT one of these characters: '{' '[' ':' ',' + * and when the second element is NOT one of these characters: '}' ']' ':' ','. + * + * This simple comparison works most of the time, but it does not cover cases + * where the batch's structural indexes contain a perfect amount of documents. + * In such a case, we do not have access to the structural index which follows + * the last document, therefore, we do not have access to the second element in + * the pair, and that means we cannot identify the last document. To fix this + * issue, we keep a count of the open and closed curly/square braces we found + * while searching for the pair. When we find a pair AND the count of open and + * closed curly/square braces is the same, we know that we just passed a + * complete document, therefore the last json buffer location is the end of the + * batch. + */ + simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { + // Variant: do not count separately, just figure out depth + if (parser.n_structural_indexes == 0) { return 0; } + auto arr_cnt = 0; + auto obj_cnt = 0; + for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { + auto idxb = parser.structural_indexes[i]; + switch (parser.buf[idxb]) { + case ':': + case ',': + continue; + case '}': + obj_cnt--; + continue; + case ']': + arr_cnt--; + continue; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + auto idxa = parser.structural_indexes[i - 1]; + switch (parser.buf[idxa]) { + case '{': + case '[': + case ':': + case ',': + continue; + } + // Last document is complete, so the next document will appear after! + if (!arr_cnt && !obj_cnt) { + return parser.n_structural_indexes; + } + // Last document is incomplete; mark the document at i + 1 as the next one + return i; + } + // If we made it to the end, we want to finish counting to see if we have a full document. + switch (parser.buf[parser.structural_indexes[0]]) { + case '}': + obj_cnt--; + break; + case ']': + arr_cnt--; + break; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + if (!arr_cnt && !obj_cnt) { + // We have a complete document. + return parser.n_structural_indexes; + } + return 0; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H +/* end file generic/stage1/find_next_document_index.h for arm64 */ +/* including generic/stage1/json_minifier.h for arm64: #include */ +/* begin file generic/stage1/json_minifier.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + // This file contains the common code every implementation uses in stage1 // It is intended to be included multiple times and compiled multiple times // We assume the file in which it is included already includes @@ -3687,102 +12034,28 @@ namespace simdjson { } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage1/json_minifier.h */ -/* begin file src/generic/stage1/find_next_document_index.h */ -namespace simdjson { - namespace arm64 { - namespace { - /** - * This algorithm is used to quickly identify the last structural position that - * makes up a complete document. - * - * It does this by going backwards and finding the last *document boundary* (a - * place where one value follows another without a comma between them). If the - * last document (the characters after the boundary) has an equal number of - * start and end brackets, it is considered complete. - * - * Simply put, we iterate over the structural characters, starting from - * the end. We consider that we found the end of a JSON document when the - * first element of the pair is NOT one of these characters: '{' '[' ':' ',' - * and when the second element is NOT one of these characters: '}' ']' ':' ','. - * - * This simple comparison works most of the time, but it does not cover cases - * where the batch's structural indexes contain a perfect amount of documents. - * In such a case, we do not have access to the structural index which follows - * the last document, therefore, we do not have access to the second element in - * the pair, and that means we cannot identify the last document. To fix this - * issue, we keep a count of the open and closed curly/square braces we found - * while searching for the pair. When we find a pair AND the count of open and - * closed curly/square braces is the same, we know that we just passed a - * complete document, therefore the last json buffer location is the end of the - * batch. - */ - simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { - // Variant: do not count separately, just figure out depth - if (parser.n_structural_indexes == 0) { return 0; } - auto arr_cnt = 0; - auto obj_cnt = 0; - for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { - auto idxb = parser.structural_indexes[i]; - switch (parser.buf[idxb]) { - case ':': - case ',': - continue; - case '}': - obj_cnt--; - continue; - case ']': - arr_cnt--; - continue; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - auto idxa = parser.structural_indexes[i - 1]; - switch (parser.buf[idxa]) { - case '{': - case '[': - case ':': - case ',': - continue; - } - // Last document is complete, so the next document will appear after! - if (!arr_cnt && !obj_cnt) { - return parser.n_structural_indexes; - } - // Last document is incomplete; mark the document at i + 1 as the next one - return i; - } - // If we made it to the end, we want to finish counting to see if we have a full document. - switch (parser.buf[parser.structural_indexes[0]]) { - case '}': - obj_cnt--; - break; - case ']': - arr_cnt--; - break; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - if (!arr_cnt && !obj_cnt) { - // We have a complete document. - return parser.n_structural_indexes; - } - return 0; - } +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H +/* end file generic/stage1/json_minifier.h for arm64 */ +/* including generic/stage1/json_structural_indexer.h for arm64: #include */ +/* begin file generic/stage1/json_structural_indexer.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H - } // unnamed namespace - } // namespace arm64 -} // namespace simdjson -/* end file src/generic/stage1/find_next_document_index.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses in stage1 +// It is intended to be included multiple times and compiled multiple times +// We assume the file in which it is included already includes +// "simdjson/stage1.h" (this simplifies amalgation) namespace simdjson { namespace arm64 { @@ -3795,15 +12068,67 @@ namespace simdjson { simdjson_inline bit_indexer(uint32_t* index_buf) : tail(index_buf) {} +#if SIMDJSON_PREFER_REVERSE_BITS + /** + * ARM lacks a fast trailing zero instruction, but it has a fast + * bit reversal instruction and a fast leading zero instruction. + * Thus it may be profitable to reverse the bits (once) and then + * to rely on a sequence of instructions that call the leading + * zero instruction. + * + * Performance notes: + * The chosen routine is not optimal in terms of data dependency + * since zero_leading_bit might require two instructions. However, + * it tends to minimize the total number of instructions which is + * beneficial. + */ + simdjson_inline void write_index(uint32_t idx, uint64_t& rev_bits, int i) { + int lz = leading_zeroes(rev_bits); + this->tail[i] = static_cast(idx) + lz; + rev_bits = zero_leading_bit(rev_bits, lz); + } +#else + /** + * Under recent x64 systems, we often have both a fast trailing zero + * instruction and a fast 'clear-lower-bit' instruction so the following + * algorithm can be competitive. + */ + + simdjson_inline void write_index(uint32_t idx, uint64_t& bits, int i) { + this->tail[i] = idx + trailing_zeroes(bits); + bits = clear_lowest_bit(bits); + } +#endif // SIMDJSON_PREFER_REVERSE_BITS + + template + simdjson_inline int write_indexes(uint32_t idx, uint64_t& bits) { + write_index(idx, bits, START); + SIMDJSON_IF_CONSTEXPR(N > 1) { + write_indexes<(N - 1 > 0 ? START + 1 : START), (N - 1 >= 0 ? N - 1 : 1)>(idx, bits); + } + return START + N; + } + + template + simdjson_inline int write_indexes_stepped(uint32_t idx, uint64_t& bits, int cnt) { + write_indexes(idx, bits); + SIMDJSON_IF_CONSTEXPR((START + STEP) < END) { + if (simdjson_unlikely((START + STEP) < cnt)) { + write_indexes_stepped<(START + STEP < END ? START + STEP : END), END, STEP>(idx, bits, cnt); + } + } + return ((END - START) % STEP) == 0 ? END : (END - START) - ((END - START) % STEP) + STEP; + } + // flatten out values in 'bits' assuming that they are are to have values of idx // plus their position in the bitvector, and store these indexes at // base_ptr[base] incrementing base as we go // will potentially store extra values beyond end of valid bits, so base_ptr // needs to be large enough to handle this // - // If the kernel sets SIMDJSON_CUSTOM_BIT_INDEXER, then it will provide its own - // version of the code. -#ifdef SIMDJSON_CUSTOM_BIT_INDEXER + // If the kernel sets SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER, then it + // will provide its own version of the code. +#ifdef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER simdjson_inline void write(uint32_t idx, uint64_t bits); #else simdjson_inline void write(uint32_t idx, uint64_t bits) { @@ -3812,93 +12137,31 @@ namespace simdjson { // it helps tremendously. if (bits == 0) return; -#if SIMDJSON_PREFER_REVERSE_BITS - /** - * ARM lacks a fast trailing zero instruction, but it has a fast - * bit reversal instruction and a fast leading zero instruction. - * Thus it may be profitable to reverse the bits (once) and then - * to rely on a sequence of instructions that call the leading - * zero instruction. - * - * Performance notes: - * The chosen routine is not optimal in terms of data dependency - * since zero_leading_bit might require two instructions. However, - * it tends to minimize the total number of instructions which is - * beneficial. - */ - uint64_t rev_bits = reverse_bits(bits); int cnt = static_cast(count_ones(bits)); - int i = 0; - // Do the first 8 all together - for (; i < 8; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - i = 8; - for (; i < 16; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } +#if SIMDJSON_PREFER_REVERSE_BITS + bits = reverse_bits(bits); +#endif +#ifdef SIMDJSON_STRUCTURAL_INDEXER_STEP + static constexpr const int STEP = SIMDJSON_STRUCTURAL_INDEXER_STEP; +#else + static constexpr const int STEP = 4; +#endif + static constexpr const int STEP_UNTIL = 24; - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - i = 16; - while (rev_bits != 0) { - int lz = leading_zeroes(rev_bits); - this->tail[i++] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); + write_indexes_stepped<0, STEP_UNTIL, STEP>(idx, bits, cnt); + SIMDJSON_IF_CONSTEXPR(STEP_UNTIL < 64) { + if (simdjson_unlikely(STEP_UNTIL < cnt)) { + for (int i = STEP_UNTIL; i < cnt; i++) { + write_index(idx, bits, i); } } } - this->tail += cnt; -#else // SIMDJSON_PREFER_REVERSE_BITS - /** - * Under recent x64 systems, we often have both a fast trailing zero - * instruction and a fast 'clear-lower-bit' instruction so the following - * algorithm can be competitive. - */ - - int cnt = static_cast(count_ones(bits)); - // Do the first 8 all together - for (int i = 0; i < 8; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - for (int i = 8; i < 16; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - int i = 16; - do { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - i++; - } while (i < cnt); - } - } this->tail += cnt; -#endif } -#endif // SIMDJSON_CUSTOM_BIT_INDEXER +#endif // SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER }; @@ -4131,8 +12394,23 @@ namespace simdjson { } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage1/json_structural_indexer.h */ -/* begin file src/generic/stage1/utf8_validator.h */ + +// Clear CUSTOM_BIT_INDEXER so other implementations can set it if they need to. +#undef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H +/* end file generic/stage1/json_structural_indexer.h for arm64 */ +/* including generic/stage1/utf8_validator.h for arm64: #include */ +/* begin file generic/stage1/utf8_validator.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace arm64 { namespace { @@ -4167,262 +12445,171 @@ namespace simdjson { } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage1/utf8_validator.h */ -// -// Stage 2 -// +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H +/* end file generic/stage1/utf8_validator.h for arm64 */ +/* end file generic/stage1/amalgamated.h for arm64 */ +/* including generic/stage2/amalgamated.h for arm64: #include */ +/* begin file generic/stage2/amalgamated.h for arm64 */ +// Stuff other things depend on +/* including generic/stage2/base.h for arm64: #include */ +/* begin file generic/stage2/base.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_BASE_H -/* begin file src/generic/stage2/stringparsing.h */ -// This file contains the common code every implementation uses -// It is intended to be included multiple times and compiled multiple times +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { namespace { - /// @private - namespace stringparsing { + namespace stage2 { - // begin copypasta - // These chars yield themselves: " \ / - // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab - // u not handled in this table as it's complex - static const uint8_t escape_map[256] = { - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + class json_iterator; + class structural_iterator; + struct tape_builder; + struct tape_writer; - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. - 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. - 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - }; - - // handle a unicode codepoint - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, - uint8_t** dst_ptr, bool allow_replacement) { - // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) - constexpr uint32_t substitution_code_point = 0xfffd; - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - - // We have already checked that the high surrogate is valid and - // (code_point - 0xd800) < 1024. - // - // Check that code_point_2 is in the range 0xdc00..0xdfff - // and that code_point_2 was parsed from valid hex. - uint32_t low_bit = code_point_2 - 0xdc00; - if (low_bit >> 10) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - - } - } - else if (code_point >= 0xdc00 && code_point <= 0xdfff) { - // If we encounter a low surrogate (not preceded by a high surrogate) - // then we have an error. - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - // handle a unicode codepoint using the wobbly convention - // https://simonsapin.github.io/wtf-8/ - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, - uint8_t** dst_ptr) { - // It is not ideal that this function is nearly identical to handle_unicode_codepoint. - // - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - uint32_t low_bit = code_point_2 - 0xdc00; - if ((low_bit >> 10) == 0) { - code_point = - (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - } - } - - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - /** - * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There - * must be an unescaped quote terminating the string. It returns the final output - * position as pointer. In case of error (e.g., the string has bad escaped codes), - * then null_nullptrptr is returned. It is assumed that the output buffer is large - * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + - * SIMDJSON_PADDING bytes. - */ - simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { - // It is not ideal that this function is nearly identical to parse_string. - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint_wobbly(&src, &dst)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - } // namespace stringparsing + } // namespace stage2 } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage2/stringparsing.h */ -/* begin file src/generic/stage2/tape_builder.h */ -/* begin file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_BASE_H +/* end file generic/stage2/base.h for arm64 */ +/* including generic/stage2/tape_writer.h for arm64: #include */ +/* begin file generic/stage2/tape_writer.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace arm64 { + namespace { + namespace stage2 { + + struct tape_writer { + /** The next place to write to tape */ + uint64_t* next_tape_loc; + + /** Write a signed 64-bit value to tape. */ + simdjson_inline void append_s64(int64_t value) noexcept; + + /** Write an unsigned 64-bit value to tape. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + + /** Write a double value to tape. */ + simdjson_inline void append_double(double value) noexcept; + + /** + * Append a tape entry (an 8-bit type,and 56 bits worth of value). + */ + simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; + + /** + * Skip the current tape entry without writing. + * + * Used to skip the start of the container, since we'll come back later to fill it in when the + * container ends. + */ + simdjson_inline void skip() noexcept; + + /** + * Skip the number of tape entries necessary to write a large u64 or i64. + */ + simdjson_inline void skip_large_integer() noexcept; + + /** + * Skip the number of tape entries necessary to write a double. + */ + simdjson_inline void skip_double() noexcept; + + /** + * Write a value to a known location on tape. + * + * Used to go back and write out the start of a container after the container ends. + */ + simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; + + private: + /** + * Append both the tape entry, and a supplementary value following it. Used for types that need + * all 64 bits, such as double and uint64_t. + */ + template + simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; + }; // struct tape_writer + + simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { + append2(0, value, internal::tape_type::INT64); + } + + simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { + append(0, internal::tape_type::UINT64); + *next_tape_loc = value; + next_tape_loc++; + } + + /** Write a double value to tape. */ + simdjson_inline void tape_writer::append_double(double value) noexcept { + append2(0, value, internal::tape_type::DOUBLE); + } + + simdjson_inline void tape_writer::skip() noexcept { + next_tape_loc++; + } + + simdjson_inline void tape_writer::skip_large_integer() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::skip_double() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { + *next_tape_loc = val | ((uint64_t(char(t))) << 56); + next_tape_loc++; + } + + template + simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { + append(val, t); + static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); + memcpy(next_tape_loc, &val2, sizeof(val2)); + next_tape_loc++; + } + + simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { + tape_loc = val | ((uint64_t(char(t))) << 56); + } + + } // namespace stage2 + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H +/* end file generic/stage2/tape_writer.h for arm64 */ +/* including generic/stage2/logger.h for arm64: #include */ +/* begin file generic/stage2/logger.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + + // This is for an internal-only stage 2 specific logger. // Set LOG_ENABLED = true to log what stage 2 is doing! namespace simdjson { @@ -4513,7 +12700,21 @@ namespace simdjson { } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H +/* end file generic/stage2/logger.h for arm64 */ + +// All other declarations +/* including generic/stage2/json_iterator.h for arm64: #include */ +/* begin file generic/stage2/json_iterator.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { @@ -4811,15 +13012,18 @@ namespace simdjson { } template simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { + // Use the fact that most scalars are going to be either strings or numbers. + if (*value == '"') { + return visitor.visit_string(*this, value); + } + else if (((*value - '0') < 10) || (*value == '-')) { + return visitor.visit_number(*this, value); + } + // true, false, null are uncommon. switch (*value) { - case '"': return visitor.visit_string(*this, value); case 't': return visitor.visit_true_atom(*this, value); case 'f': return visitor.visit_false_atom(*this, value); case 'n': return visitor.visit_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_number(*this, value); default: log_error("Non-value found when value was expected!"); return TAPE_ERROR; @@ -4830,114 +13034,346 @@ namespace simdjson { } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H +/* end file generic/stage2/json_iterator.h for arm64 */ +/* including generic/stage2/stringparsing.h for arm64: #include */ +/* begin file generic/stage2/stringparsing.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses +// It is intended to be included multiple times and compiled multiple times + +namespace simdjson { + namespace arm64 { + namespace { + /// @private + namespace stringparsing { + + // begin copypasta + // These chars yield themselves: " \ / + // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab + // u not handled in this table as it's complex + static const uint8_t escape_map[256] = { + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. + 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. + 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + }; + + // handle a unicode codepoint + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, + uint8_t** dst_ptr, bool allow_replacement) { + // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) + constexpr uint32_t substitution_code_point = 0xfffd; + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + + // We have already checked that the high surrogate is valid and + // (code_point - 0xd800) < 1024. + // + // Check that code_point_2 is in the range 0xdc00..0xdfff + // and that code_point_2 was parsed from valid hex. + uint32_t low_bit = code_point_2 - 0xdc00; + if (low_bit >> 10) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + + } + } + else if (code_point >= 0xdc00 && code_point <= 0xdfff) { + // If we encounter a low surrogate (not preceded by a high surrogate) + // then we have an error. + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + // handle a unicode codepoint using the wobbly convention + // https://simonsapin.github.io/wtf-8/ + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, + uint8_t** dst_ptr) { + // It is not ideal that this function is nearly identical to handle_unicode_codepoint. + // + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + uint32_t low_bit = code_point_2 - 0xdc00; + if ((low_bit >> 10) == 0) { + code_point = + (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + } + } + + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + /** + * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + */ + simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { + // It is not ideal that this function is nearly identical to parse_string. + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint_wobbly(&src, &dst)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + } // namespace stringparsing + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H +/* end file generic/stage2/stringparsing.h for arm64 */ +/* including generic/stage2/structural_iterator.h for arm64: #include */ +/* begin file generic/stage2/structural_iterator.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace arm64 { namespace { namespace stage2 { - struct tape_writer { - /** The next place to write to tape */ - uint64_t* next_tape_loc; + class structural_iterator { + public: + const uint8_t* const buf; + uint32_t* next_structural; + dom_parser_implementation& dom_parser; - /** Write a signed 64-bit value to tape. */ - simdjson_inline void append_s64(int64_t value) noexcept; + // Start a structural + simdjson_inline structural_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) + : buf{ _dom_parser.buf }, + next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, + dom_parser{ _dom_parser } { + } + // Get the buffer position of the current structural character + simdjson_inline const uint8_t* current() { + return &buf[*(next_structural - 1)]; + } + // Get the current structural character + simdjson_inline char current_char() { + return buf[*(next_structural - 1)]; + } + // Get the next structural character without advancing + simdjson_inline char peek_next_char() { + return buf[*next_structural]; + } + simdjson_inline const uint8_t* peek() { + return &buf[*next_structural]; + } + simdjson_inline const uint8_t* advance() { + return &buf[*(next_structural++)]; + } + simdjson_inline char advance_char() { + return buf[*(next_structural++)]; + } + simdjson_inline size_t remaining_len() { + return dom_parser.len - *(next_structural - 1); + } - /** Write an unsigned 64-bit value to tape. */ - simdjson_inline void append_u64(uint64_t value) noexcept; - - /** Write a double value to tape. */ - simdjson_inline void append_double(double value) noexcept; - - /** - * Append a tape entry (an 8-bit type,and 56 bits worth of value). - */ - simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; - - /** - * Skip the current tape entry without writing. - * - * Used to skip the start of the container, since we'll come back later to fill it in when the - * container ends. - */ - simdjson_inline void skip() noexcept; - - /** - * Skip the number of tape entries necessary to write a large u64 or i64. - */ - simdjson_inline void skip_large_integer() noexcept; - - /** - * Skip the number of tape entries necessary to write a double. - */ - simdjson_inline void skip_double() noexcept; - - /** - * Write a value to a known location on tape. - * - * Used to go back and write out the start of a container after the container ends. - */ - simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; - - private: - /** - * Append both the tape entry, and a supplementary value following it. Used for types that need - * all 64 bits, such as double and uint64_t. - */ - template - simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; - }; // struct number_writer - - simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { - append2(0, value, internal::tape_type::INT64); - } - - simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { - append(0, internal::tape_type::UINT64); - *next_tape_loc = value; - next_tape_loc++; - } - - /** Write a double value to tape. */ - simdjson_inline void tape_writer::append_double(double value) noexcept { - append2(0, value, internal::tape_type::DOUBLE); - } - - simdjson_inline void tape_writer::skip() noexcept { - next_tape_loc++; - } - - simdjson_inline void tape_writer::skip_large_integer() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::skip_double() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { - *next_tape_loc = val | ((uint64_t(char(t))) << 56); - next_tape_loc++; - } - - template - simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { - append(val, t); - static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); - memcpy(next_tape_loc, &val2, sizeof(val2)); - next_tape_loc++; - } - - simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { - tape_loc = val | ((uint64_t(char(t))) << 56); - } + simdjson_inline bool at_end() { + return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; + } + simdjson_inline bool at_beginning() { + return next_structural == dom_parser.structural_indexes.get(); + } + }; } // namespace stage2 } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H +/* end file generic/stage2/structural_iterator.h for arm64 */ +/* including generic/stage2/tape_builder.h for arm64: #include */ +/* begin file generic/stage2/tape_builder.h for arm64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace arm64 { @@ -5019,7 +13455,7 @@ namespace simdjson { simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; simdjson_inline void on_end_string(uint8_t* dst) noexcept; - }; // class tape_builder + }; // struct tape_builder template simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( @@ -5219,25 +13655,125 @@ namespace simdjson { } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file src/generic/stage2/tape_builder.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H +/* end file generic/stage2/tape_builder.h for arm64 */ +/* end file generic/stage2/amalgamated.h for arm64 */ + +// +// Stage 1 +// +namespace simdjson { + namespace arm64 { + + simdjson_warn_unused error_code implementation::create_dom_parser_implementation( + size_t capacity, + size_t max_depth, + std::unique_ptr& dst + ) const noexcept { + dst.reset(new (std::nothrow) dom_parser_implementation()); + if (!dst) { return MEMALLOC; } + if (auto err = dst->set_capacity(capacity)) + return err; + if (auto err = dst->set_max_depth(max_depth)) + return err; + return SUCCESS; + } + + namespace { + + using namespace simd; + + simdjson_inline json_character_block json_character_block::classify(const simd::simd8x64& in) { + // Functional programming causes trouble with Visual Studio. + // Keeping this version in comments since it is much nicer: + // auto v = in.map([&](simd8 chunk) { + // auto nib_lo = chunk & 0xf; + // auto nib_hi = chunk.shr<4>(); + // auto shuf_lo = nib_lo.lookup_16(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0); + // auto shuf_hi = nib_hi.lookup_16(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0); + // return shuf_lo & shuf_hi; + // }); + const simd8 table1(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0); + const simd8 table2(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0); + + simd8x64 v( + (in.chunks[0] & 0xf).lookup_16(table1) & (in.chunks[0].shr<4>()).lookup_16(table2), + (in.chunks[1] & 0xf).lookup_16(table1) & (in.chunks[1].shr<4>()).lookup_16(table2), + (in.chunks[2] & 0xf).lookup_16(table1) & (in.chunks[2].shr<4>()).lookup_16(table2), + (in.chunks[3] & 0xf).lookup_16(table1) & (in.chunks[3].shr<4>()).lookup_16(table2) + ); + + + // We compute whitespace and op separately. If the code later only use one or the + // other, given the fact that all functions are aggressively inlined, we can + // hope that useless computations will be omitted. This is namely case when + // minifying (we only need whitespace). *However* if we only need spaces, + // it is likely that we will still compute 'v' above with two lookup_16: one + // could do it a bit cheaper. This is in contrast with the x64 implementations + // where we can, efficiently, do the white space and structural matching + // separately. One reason for this difference is that on ARM NEON, the table + // lookups either zero or leave unchanged the characters exceeding 0xF whereas + // on x64, the equivalent instruction (pshufb) automatically applies a mask, + // ignoring the 4 most significant bits. Thus the x64 implementation is + // optimized differently. This being said, if you use this code strictly + // just for minification (or just to identify the structural characters), + // there is a small untaken optimization opportunity here. We deliberately + // do not pick it up. + + uint64_t op = simd8x64( + v.chunks[0].any_bits_set(0x7), + v.chunks[1].any_bits_set(0x7), + v.chunks[2].any_bits_set(0x7), + v.chunks[3].any_bits_set(0x7) + ).to_bitmask(); + + uint64_t whitespace = simd8x64( + v.chunks[0].any_bits_set(0x18), + v.chunks[1].any_bits_set(0x18), + v.chunks[2].any_bits_set(0x18), + v.chunks[3].any_bits_set(0x18) + ).to_bitmask(); + + return { whitespace, op }; + } + + simdjson_inline bool is_ascii(const simd8x64& input) { + simd8 bits = input.reduce_or(); + return bits.max_val() < 0x80u; + } + + simdjson_unused simdjson_inline simd8 must_be_continuation(const simd8 prev1, const simd8 prev2, const simd8 prev3) { + simd8 is_second_byte = prev1 >= uint8_t(0xc0u); + simd8 is_third_byte = prev2 >= uint8_t(0xe0u); + simd8 is_fourth_byte = prev3 >= uint8_t(0xf0u); + // Use ^ instead of | for is_*_byte, because ^ is commutative, and the caller is using ^ as well. + // This will work fine because we only have to report errors for cases with 0-1 lead bytes. + // Multiple lead bytes implies 2 overlapping multibyte characters, and if that happens, there is + // guaranteed to be at least *one* lead byte that is part of only 1 other multibyte character. + // The error will be detected there. + return is_second_byte ^ is_third_byte ^ is_fourth_byte; + } + + simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3) { + simd8 is_third_byte = prev2 >= uint8_t(0xe0u); + simd8 is_fourth_byte = prev3 >= uint8_t(0xf0u); + return is_third_byte ^ is_fourth_byte; + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +// +// Stage 2 +// // // Implementation-specific overrides // namespace simdjson { namespace arm64 { - namespace { - namespace stage1 { - - simdjson_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) { - // On ARM, we don't short-circuit this if there are no backslashes, because the branch gives us no - // benefit and therefore makes things worse. - // if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; } - return find_escaped_branchless(backslash); - } - - } // namespace stage1 - } // unnamed namespace simdjson_warn_unused error_code implementation::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept { return arm64::stage1::json_minifier::minify<64>(buf, len, dst, dst_len); @@ -5278,16 +13814,3551 @@ namespace simdjson { } // namespace arm64 } // namespace simdjson -/* begin file include/simdjson/arm64/end.h */ -/* end file include/simdjson/arm64/end.h */ -/* end file src/arm64/dom_parser_implementation.cpp */ +/* including simdjson/arm64/end.h: #include */ +/* begin file simdjson/arm64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "arm64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/arm64/end.h */ + +#endif // SIMDJSON_SRC_ARM64_CPP +/* end file arm64.cpp */ #endif #if SIMDJSON_IMPLEMENTATION_FALLBACK -/* begin file src/fallback/implementation.cpp */ -/* begin file include/simdjson/fallback/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "fallback" -// #define SIMDJSON_IMPLEMENTATION fallback -/* end file include/simdjson/fallback/begin.h */ +/* including fallback.cpp: #include */ +/* begin file fallback.cpp */ +#ifndef SIMDJSON_SRC_FALLBACK_CPP +#define SIMDJSON_SRC_FALLBACK_CPP + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* including simdjson/fallback.h: #include */ +/* begin file simdjson/fallback.h */ +#ifndef SIMDJSON_FALLBACK_H +#define SIMDJSON_FALLBACK_H + +/* including simdjson/fallback/begin.h: #include "simdjson/fallback/begin.h" */ +/* begin file simdjson/fallback/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "fallback" */ +#define SIMDJSON_IMPLEMENTATION fallback +/* including simdjson/fallback/base.h: #include "simdjson/fallback/base.h" */ +/* begin file simdjson/fallback/base.h */ +#ifndef SIMDJSON_FALLBACK_BASE_H +#define SIMDJSON_FALLBACK_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Fallback implementation (runs on any machine). + */ + namespace fallback { + + class implementation; + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_BASE_H +/* end file simdjson/fallback/base.h */ +/* including simdjson/fallback/bitmanipulation.h: #include "simdjson/fallback/bitmanipulation.h" */ +/* begin file simdjson/fallback/bitmanipulation.h */ +#ifndef SIMDJSON_FALLBACK_BITMANIPULATION_H +#define SIMDJSON_FALLBACK_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + +#if defined(_MSC_VER) && !defined(_M_ARM64) && !defined(_M_X64) + static inline unsigned char _BitScanForward64(unsigned long* ret, uint64_t x) { + unsigned long x0 = (unsigned long)x, top, bottom; + _BitScanForward(&top, (unsigned long)(x >> 32)); + _BitScanForward(&bottom, x0); + *ret = x0 ? bottom : 32 + top; + return x != 0; + } + static unsigned char _BitScanReverse64(unsigned long* ret, uint64_t x) { + unsigned long x1 = (unsigned long)(x >> 32), top, bottom; + _BitScanReverse(&top, x1); + _BitScanReverse(&bottom, (unsigned long)x); + *ret = x1 ? top + 32 : bottom; + return x != 0; + } +#endif + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#ifdef _MSC_VER + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// _MSC_VER + } + + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_BITMANIPULATION_H +/* end file simdjson/fallback/bitmanipulation.h */ +/* including simdjson/fallback/stringparsing_defs.h: #include "simdjson/fallback/stringparsing_defs.h" */ +/* begin file simdjson/fallback/stringparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +#define SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 1; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return c == '"'; } + simdjson_inline bool has_backslash() { return c == '\\'; } + simdjson_inline int quote_index() { return c == '"' ? 0 : 1; } + simdjson_inline int backslash_index() { return c == '\\' ? 0 : 1; } + + uint8_t c; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // store to dest unconditionally - we can overwrite the bits we don't like later + dst[0] = src[0]; + return { src[0] }; + } + + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +/* end file simdjson/fallback/stringparsing_defs.h */ +/* including simdjson/fallback/numberparsing_defs.h: #include "simdjson/fallback/numberparsing_defs.h" */ +/* begin file simdjson/fallback/numberparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +#define SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#ifdef JSON_TEST_NUMBERS // for unit testing +void found_invalid_number(const uint8_t* buf); +void found_integer(int64_t result, const uint8_t* buf); +void found_unsigned_integer(uint64_t result, const uint8_t* buf); +void found_float(double result, const uint8_t* buf); +#endif + +namespace simdjson { + namespace fallback { + namespace numberparsing { + + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const char* chars) { + uint64_t val; + memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + return parse_eight_digits_unrolled(reinterpret_cast(chars)); + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace fallback +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +/* end file simdjson/fallback/numberparsing_defs.h */ +/* end file simdjson/fallback/begin.h */ +/* including simdjson/generic/amalgamated.h for fallback: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for fallback */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for fallback: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for fallback */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for fallback */ +/* including simdjson/generic/jsoncharutils.h for fallback: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for fallback */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + namespace jsoncharutils { + + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for fallback */ +/* including simdjson/generic/atomparsing.h for fallback: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for fallback */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace fallback { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for fallback */ +/* including simdjson/generic/dom_parser_implementation.h for fallback: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for fallback */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container + + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); + + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; + + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; + + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; + + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + namespace fallback { + + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; + } + + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for fallback */ +/* including simdjson/generic/implementation_simdjson_result_base.h for fallback: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for fallback */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); + + +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for fallback */ +/* including simdjson/generic/numberparsing.h for fallback: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for fallback */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace fallback { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing +// +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. +// +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for fallback */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for fallback: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for fallback */ +/* end file simdjson/generic/amalgamated.h for fallback */ +/* including simdjson/fallback/end.h: #include "simdjson/fallback/end.h" */ +/* begin file simdjson/fallback/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* undefining SIMDJSON_IMPLEMENTATION from "fallback" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/fallback/end.h */ + +#endif // SIMDJSON_FALLBACK_H +/* end file simdjson/fallback.h */ +/* including simdjson/fallback/implementation.h: #include */ +/* begin file simdjson/fallback/implementation.h */ +#ifndef SIMDJSON_FALLBACK_IMPLEMENTATION_H +#define SIMDJSON_FALLBACK_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "fallback", + "Generic fallback implementation", + 0 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_IMPLEMENTATION_H +/* end file simdjson/fallback/implementation.h */ + +/* including simdjson/fallback/begin.h: #include */ +/* begin file simdjson/fallback/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "fallback" */ +#define SIMDJSON_IMPLEMENTATION fallback +/* including simdjson/fallback/base.h: #include "simdjson/fallback/base.h" */ +/* begin file simdjson/fallback/base.h */ +#ifndef SIMDJSON_FALLBACK_BASE_H +#define SIMDJSON_FALLBACK_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Fallback implementation (runs on any machine). + */ + namespace fallback { + + class implementation; + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_BASE_H +/* end file simdjson/fallback/base.h */ +/* including simdjson/fallback/bitmanipulation.h: #include "simdjson/fallback/bitmanipulation.h" */ +/* begin file simdjson/fallback/bitmanipulation.h */ +#ifndef SIMDJSON_FALLBACK_BITMANIPULATION_H +#define SIMDJSON_FALLBACK_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + +#if defined(_MSC_VER) && !defined(_M_ARM64) && !defined(_M_X64) + static inline unsigned char _BitScanForward64(unsigned long* ret, uint64_t x) { + unsigned long x0 = (unsigned long)x, top, bottom; + _BitScanForward(&top, (unsigned long)(x >> 32)); + _BitScanForward(&bottom, x0); + *ret = x0 ? bottom : 32 + top; + return x != 0; + } + static unsigned char _BitScanReverse64(unsigned long* ret, uint64_t x) { + unsigned long x1 = (unsigned long)(x >> 32), top, bottom; + _BitScanReverse(&top, x1); + _BitScanReverse(&bottom, (unsigned long)x); + *ret = x1 ? top + 32 : bottom; + return x != 0; + } +#endif + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#ifdef _MSC_VER + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// _MSC_VER + } + + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_BITMANIPULATION_H +/* end file simdjson/fallback/bitmanipulation.h */ +/* including simdjson/fallback/stringparsing_defs.h: #include "simdjson/fallback/stringparsing_defs.h" */ +/* begin file simdjson/fallback/stringparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +#define SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 1; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return c == '"'; } + simdjson_inline bool has_backslash() { return c == '\\'; } + simdjson_inline int quote_index() { return c == '"' ? 0 : 1; } + simdjson_inline int backslash_index() { return c == '\\' ? 0 : 1; } + + uint8_t c; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // store to dest unconditionally - we can overwrite the bits we don't like later + dst[0] = src[0]; + return { src[0] }; + } + + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +/* end file simdjson/fallback/stringparsing_defs.h */ +/* including simdjson/fallback/numberparsing_defs.h: #include "simdjson/fallback/numberparsing_defs.h" */ +/* begin file simdjson/fallback/numberparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +#define SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#ifdef JSON_TEST_NUMBERS // for unit testing +void found_invalid_number(const uint8_t* buf); +void found_integer(int64_t result, const uint8_t* buf); +void found_unsigned_integer(uint64_t result, const uint8_t* buf); +void found_float(double result, const uint8_t* buf); +#endif + +namespace simdjson { + namespace fallback { + namespace numberparsing { + + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const char* chars) { + uint64_t val; + memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + return parse_eight_digits_unrolled(reinterpret_cast(chars)); + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace fallback +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +/* end file simdjson/fallback/numberparsing_defs.h */ +/* end file simdjson/fallback/begin.h */ +/* including generic/stage1/find_next_document_index.h for fallback: #include */ +/* begin file generic/stage1/find_next_document_index.h for fallback */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + namespace stage1 { + + /** + * This algorithm is used to quickly identify the last structural position that + * makes up a complete document. + * + * It does this by going backwards and finding the last *document boundary* (a + * place where one value follows another without a comma between them). If the + * last document (the characters after the boundary) has an equal number of + * start and end brackets, it is considered complete. + * + * Simply put, we iterate over the structural characters, starting from + * the end. We consider that we found the end of a JSON document when the + * first element of the pair is NOT one of these characters: '{' '[' ':' ',' + * and when the second element is NOT one of these characters: '}' ']' ':' ','. + * + * This simple comparison works most of the time, but it does not cover cases + * where the batch's structural indexes contain a perfect amount of documents. + * In such a case, we do not have access to the structural index which follows + * the last document, therefore, we do not have access to the second element in + * the pair, and that means we cannot identify the last document. To fix this + * issue, we keep a count of the open and closed curly/square braces we found + * while searching for the pair. When we find a pair AND the count of open and + * closed curly/square braces is the same, we know that we just passed a + * complete document, therefore the last json buffer location is the end of the + * batch. + */ + simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { + // Variant: do not count separately, just figure out depth + if (parser.n_structural_indexes == 0) { return 0; } + auto arr_cnt = 0; + auto obj_cnt = 0; + for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { + auto idxb = parser.structural_indexes[i]; + switch (parser.buf[idxb]) { + case ':': + case ',': + continue; + case '}': + obj_cnt--; + continue; + case ']': + arr_cnt--; + continue; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + auto idxa = parser.structural_indexes[i - 1]; + switch (parser.buf[idxa]) { + case '{': + case '[': + case ':': + case ',': + continue; + } + // Last document is complete, so the next document will appear after! + if (!arr_cnt && !obj_cnt) { + return parser.n_structural_indexes; + } + // Last document is incomplete; mark the document at i + 1 as the next one + return i; + } + // If we made it to the end, we want to finish counting to see if we have a full document. + switch (parser.buf[parser.structural_indexes[0]]) { + case '}': + obj_cnt--; + break; + case ']': + arr_cnt--; + break; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + if (!arr_cnt && !obj_cnt) { + // We have a complete document. + return parser.n_structural_indexes; + } + return 0; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H +/* end file generic/stage1/find_next_document_index.h for fallback */ +/* including generic/stage2/stringparsing.h for fallback: #include */ +/* begin file generic/stage2/stringparsing.h for fallback */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses +// It is intended to be included multiple times and compiled multiple times + +namespace simdjson { + namespace fallback { + namespace { + /// @private + namespace stringparsing { + + // begin copypasta + // These chars yield themselves: " \ / + // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab + // u not handled in this table as it's complex + static const uint8_t escape_map[256] = { + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. + 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. + 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + }; + + // handle a unicode codepoint + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, + uint8_t** dst_ptr, bool allow_replacement) { + // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) + constexpr uint32_t substitution_code_point = 0xfffd; + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + + // We have already checked that the high surrogate is valid and + // (code_point - 0xd800) < 1024. + // + // Check that code_point_2 is in the range 0xdc00..0xdfff + // and that code_point_2 was parsed from valid hex. + uint32_t low_bit = code_point_2 - 0xdc00; + if (low_bit >> 10) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + + } + } + else if (code_point >= 0xdc00 && code_point <= 0xdfff) { + // If we encounter a low surrogate (not preceded by a high surrogate) + // then we have an error. + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + // handle a unicode codepoint using the wobbly convention + // https://simonsapin.github.io/wtf-8/ + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, + uint8_t** dst_ptr) { + // It is not ideal that this function is nearly identical to handle_unicode_codepoint. + // + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + uint32_t low_bit = code_point_2 - 0xdc00; + if ((low_bit >> 10) == 0) { + code_point = + (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + } + } + + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + /** + * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + */ + simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { + // It is not ideal that this function is nearly identical to parse_string. + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint_wobbly(&src, &dst)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + } // namespace stringparsing + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H +/* end file generic/stage2/stringparsing.h for fallback */ +/* including generic/stage2/logger.h for fallback: #include */ +/* begin file generic/stage2/logger.h for fallback */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + + +// This is for an internal-only stage 2 specific logger. +// Set LOG_ENABLED = true to log what stage 2 is doing! +namespace simdjson { + namespace fallback { + namespace { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static constexpr const int LOG_INDEX_LEN = 5; + + static int log_depth; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static simdjson_inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + // Print the header and set up log_start + static simdjson_inline void log_start() { + if (LOG_ENABLED) { + log_depth = 0; + printf("\n"); + printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#"); + printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN + 2, DASHES, LOG_BUFFER_LEN + 2, DASHES, LOG_SMALL_BUFFER_LEN + 2, DASHES, 5 + 2, DASHES); + } + } + + simdjson_unused static simdjson_inline void log_string(const char* message) { + if (LOG_ENABLED) { + printf("%s\n", message); + } + } + + // Logs a single line from the stage 2 DOM parser + template + static simdjson_inline void log_line(S& structurals, const char* title_prefix, const char* title, const char* detail) { + if (LOG_ENABLED) { + printf("| %*s%s%-*s ", log_depth * 2, "", title_prefix, LOG_EVENT_LEN - log_depth * 2 - int(strlen(title_prefix)), title); + auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural - 1; + auto next_index = structurals.next_structural; + auto current = current_index ? &structurals.buf[*current_index] : reinterpret_cast(" "); + auto next = &structurals.buf[*next_index]; + { + // Print the next N characters in the buffer. + printf("| "); + // Otherwise, print the characters starting from the buffer position. + // Print spaces for unprintable or newline characters. + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current[i])); + } + printf(" "); + // Print the next N characters in the buffer. + printf("| "); + // Otherwise, print the characters starting from the buffer position. + // Print spaces for unprintable or newline characters. + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next[i])); + } + printf(" "); + } + if (current_index) { + printf("| %*u ", LOG_INDEX_LEN, *current_index); + } + else { + printf("| %-*s ", LOG_INDEX_LEN, ""); + } + // printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index()); + printf("| %-s ", detail); + printf("|\n"); + } + } + + } // namespace logger + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H +/* end file generic/stage2/logger.h for fallback */ +/* including generic/stage2/json_iterator.h for fallback: #include */ +/* begin file generic/stage2/json_iterator.h for fallback */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + namespace stage2 { + + class json_iterator { + public: + const uint8_t* const buf; + uint32_t* next_structural; + dom_parser_implementation& dom_parser; + uint32_t depth{ 0 }; + + /** + * Walk the JSON document. + * + * The visitor receives callbacks when values are encountered. All callbacks pass the iterator as + * the first parameter; some callbacks have other parameters as well: + * + * - visit_document_start() - at the beginning. + * - visit_document_end() - at the end (if things were successful). + * + * - visit_array_start() - at the start `[` of a non-empty array. + * - visit_array_end() - at the end `]` of a non-empty array. + * - visit_empty_array() - when an empty array is encountered. + * + * - visit_object_end() - at the start `]` of a non-empty object. + * - visit_object_start() - at the end `]` of a non-empty object. + * - visit_empty_object() - when an empty object is encountered. + * - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is + * guaranteed to point at the first quote of the string (`"key"`). + * - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null. + * - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null. + * + * - increment_count(iter) - each time a value is found in an array or object. + */ + template + simdjson_warn_unused simdjson_inline error_code walk_document(V& visitor) noexcept; + + /** + * Create an iterator capable of walking a JSON document. + * + * The document must have already passed through stage 1. + */ + simdjson_inline json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index); + + /** + * Look at the next token. + * + * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). + * + * They may include invalid JSON as well (such as `1.2.3` or `ture`). + */ + simdjson_inline const uint8_t* peek() const noexcept; + /** + * Advance to the next token. + * + * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). + * + * They may include invalid JSON as well (such as `1.2.3` or `ture`). + */ + simdjson_inline const uint8_t* advance() noexcept; + /** + * Get the remaining length of the document, from the start of the current token. + */ + simdjson_inline size_t remaining_len() const noexcept; + /** + * Check if we are at the end of the document. + * + * If this is true, there are no more tokens. + */ + simdjson_inline bool at_eof() const noexcept; + /** + * Check if we are at the beginning of the document. + */ + simdjson_inline bool at_beginning() const noexcept; + simdjson_inline uint8_t last_structural() const noexcept; + + /** + * Log that a value has been found. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_value(const char* type) const noexcept; + /** + * Log the start of a multipart value. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_start_value(const char* type) const noexcept; + /** + * Log the end of a multipart value. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_end_value(const char* type) const noexcept; + /** + * Log an error. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_error(const char* error) const noexcept; + + template + simdjson_warn_unused simdjson_inline error_code visit_root_primitive(V& visitor, const uint8_t* value) noexcept; + template + simdjson_warn_unused simdjson_inline error_code visit_primitive(V& visitor, const uint8_t* value) noexcept; + }; + + template + simdjson_warn_unused simdjson_inline error_code json_iterator::walk_document(V& visitor) noexcept { + logger::log_start(); + + // + // Start the document + // + if (at_eof()) { return EMPTY; } + log_start_value("document"); + SIMDJSON_TRY(visitor.visit_document_start(*this)); + + // + // Read first value + // + { + auto value = advance(); + + // Make sure the outer object or array is closed before continuing; otherwise, there are ways we + // could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906 + if (!STREAMING) { + switch (*value) { + case '{': if (last_structural() != '}') { log_value("starting brace unmatched"); return TAPE_ERROR; }; break; + case '[': if (last_structural() != ']') { log_value("starting bracket unmatched"); return TAPE_ERROR; }; break; + } + } + + switch (*value) { + case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; + case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; + default: SIMDJSON_TRY(visitor.visit_root_primitive(*this, value)); break; + } + } + goto document_end; + + // + // Object parser states + // + object_begin: + log_start_value("object"); + depth++; + if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } + dom_parser.is_array[depth] = false; + SIMDJSON_TRY(visitor.visit_object_start(*this)); + + { + auto key = advance(); + if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; } + SIMDJSON_TRY(visitor.increment_count(*this)); + SIMDJSON_TRY(visitor.visit_key(*this, key)); + } + + object_field: + if (simdjson_unlikely(*advance() != ':')) { log_error("Missing colon after key in object"); return TAPE_ERROR; } + { + auto value = advance(); + switch (*value) { + case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; + case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; + default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; + } + } + + object_continue: + switch (*advance()) { + case ',': + SIMDJSON_TRY(visitor.increment_count(*this)); + { + auto key = advance(); + if (simdjson_unlikely(*key != '"')) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; } + SIMDJSON_TRY(visitor.visit_key(*this, key)); + } + goto object_field; + case '}': log_end_value("object"); SIMDJSON_TRY(visitor.visit_object_end(*this)); goto scope_end; + default: log_error("No comma between object fields"); return TAPE_ERROR; + } + + scope_end: + depth--; + if (depth == 0) { goto document_end; } + if (dom_parser.is_array[depth]) { goto array_continue; } + goto object_continue; + + // + // Array parser states + // + array_begin: + log_start_value("array"); + depth++; + if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } + dom_parser.is_array[depth] = true; + SIMDJSON_TRY(visitor.visit_array_start(*this)); + SIMDJSON_TRY(visitor.increment_count(*this)); + + array_value: + { + auto value = advance(); + switch (*value) { + case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; + case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; + default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; + } + } + + array_continue: + switch (*advance()) { + case ',': SIMDJSON_TRY(visitor.increment_count(*this)); goto array_value; + case ']': log_end_value("array"); SIMDJSON_TRY(visitor.visit_array_end(*this)); goto scope_end; + default: log_error("Missing comma between array values"); return TAPE_ERROR; + } + + document_end: + log_end_value("document"); + SIMDJSON_TRY(visitor.visit_document_end(*this)); + + dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]); + + // If we didn't make it to the end, it's an error + if (!STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes) { + log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!"); + return TAPE_ERROR; + } + + return SUCCESS; + + } // walk_document() + + simdjson_inline json_iterator::json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) + : buf{ _dom_parser.buf }, + next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, + dom_parser{ _dom_parser } { + } + + simdjson_inline const uint8_t* json_iterator::peek() const noexcept { + return &buf[*(next_structural)]; + } + simdjson_inline const uint8_t* json_iterator::advance() noexcept { + return &buf[*(next_structural++)]; + } + simdjson_inline size_t json_iterator::remaining_len() const noexcept { + return dom_parser.len - *(next_structural - 1); + } + + simdjson_inline bool json_iterator::at_eof() const noexcept { + return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; + } + simdjson_inline bool json_iterator::at_beginning() const noexcept { + return next_structural == dom_parser.structural_indexes.get(); + } + simdjson_inline uint8_t json_iterator::last_structural() const noexcept { + return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]]; + } + + simdjson_inline void json_iterator::log_value(const char* type) const noexcept { + logger::log_line(*this, "", type, ""); + } + + simdjson_inline void json_iterator::log_start_value(const char* type) const noexcept { + logger::log_line(*this, "+", type, ""); + if (logger::LOG_ENABLED) { logger::log_depth++; } + } + + simdjson_inline void json_iterator::log_end_value(const char* type) const noexcept { + if (logger::LOG_ENABLED) { logger::log_depth--; } + logger::log_line(*this, "-", type, ""); + } + + simdjson_inline void json_iterator::log_error(const char* error) const noexcept { + logger::log_line(*this, "", "ERROR", error); + } + + template + simdjson_warn_unused simdjson_inline error_code json_iterator::visit_root_primitive(V& visitor, const uint8_t* value) noexcept { + switch (*value) { + case '"': return visitor.visit_root_string(*this, value); + case 't': return visitor.visit_root_true_atom(*this, value); + case 'f': return visitor.visit_root_false_atom(*this, value); + case 'n': return visitor.visit_root_null_atom(*this, value); + case '-': + case '0': case '1': case '2': case '3': case '4': + case '5': case '6': case '7': case '8': case '9': + return visitor.visit_root_number(*this, value); + default: + log_error("Document starts with a non-value character"); + return TAPE_ERROR; + } + } + template + simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { + // Use the fact that most scalars are going to be either strings or numbers. + if (*value == '"') { + return visitor.visit_string(*this, value); + } + else if (((*value - '0') < 10) || (*value == '-')) { + return visitor.visit_number(*this, value); + } + // true, false, null are uncommon. + switch (*value) { + case 't': return visitor.visit_true_atom(*this, value); + case 'f': return visitor.visit_false_atom(*this, value); + case 'n': return visitor.visit_null_atom(*this, value); + default: + log_error("Non-value found when value was expected!"); + return TAPE_ERROR; + } + } + + } // namespace stage2 + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H +/* end file generic/stage2/json_iterator.h for fallback */ +/* including generic/stage2/tape_writer.h for fallback: #include */ +/* begin file generic/stage2/tape_writer.h for fallback */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace fallback { + namespace { + namespace stage2 { + + struct tape_writer { + /** The next place to write to tape */ + uint64_t* next_tape_loc; + + /** Write a signed 64-bit value to tape. */ + simdjson_inline void append_s64(int64_t value) noexcept; + + /** Write an unsigned 64-bit value to tape. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + + /** Write a double value to tape. */ + simdjson_inline void append_double(double value) noexcept; + + /** + * Append a tape entry (an 8-bit type,and 56 bits worth of value). + */ + simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; + + /** + * Skip the current tape entry without writing. + * + * Used to skip the start of the container, since we'll come back later to fill it in when the + * container ends. + */ + simdjson_inline void skip() noexcept; + + /** + * Skip the number of tape entries necessary to write a large u64 or i64. + */ + simdjson_inline void skip_large_integer() noexcept; + + /** + * Skip the number of tape entries necessary to write a double. + */ + simdjson_inline void skip_double() noexcept; + + /** + * Write a value to a known location on tape. + * + * Used to go back and write out the start of a container after the container ends. + */ + simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; + + private: + /** + * Append both the tape entry, and a supplementary value following it. Used for types that need + * all 64 bits, such as double and uint64_t. + */ + template + simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; + }; // struct tape_writer + + simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { + append2(0, value, internal::tape_type::INT64); + } + + simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { + append(0, internal::tape_type::UINT64); + *next_tape_loc = value; + next_tape_loc++; + } + + /** Write a double value to tape. */ + simdjson_inline void tape_writer::append_double(double value) noexcept { + append2(0, value, internal::tape_type::DOUBLE); + } + + simdjson_inline void tape_writer::skip() noexcept { + next_tape_loc++; + } + + simdjson_inline void tape_writer::skip_large_integer() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::skip_double() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { + *next_tape_loc = val | ((uint64_t(char(t))) << 56); + next_tape_loc++; + } + + template + simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { + append(val, t); + static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); + memcpy(next_tape_loc, &val2, sizeof(val2)); + next_tape_loc++; + } + + simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { + tape_loc = val | ((uint64_t(char(t))) << 56); + } + + } // namespace stage2 + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H +/* end file generic/stage2/tape_writer.h for fallback */ +/* including generic/stage2/tape_builder.h for fallback: #include */ +/* begin file generic/stage2/tape_builder.h for fallback */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + + +namespace simdjson { + namespace fallback { + namespace { + namespace stage2 { + + struct tape_builder { + template + simdjson_warn_unused static simdjson_inline error_code parse_document( + dom_parser_implementation& dom_parser, + dom::document& doc) noexcept; + + /** Called when a non-empty document starts. */ + simdjson_warn_unused simdjson_inline error_code visit_document_start(json_iterator& iter) noexcept; + /** Called when a non-empty document ends without error. */ + simdjson_warn_unused simdjson_inline error_code visit_document_end(json_iterator& iter) noexcept; + + /** Called when a non-empty array starts. */ + simdjson_warn_unused simdjson_inline error_code visit_array_start(json_iterator& iter) noexcept; + /** Called when a non-empty array ends. */ + simdjson_warn_unused simdjson_inline error_code visit_array_end(json_iterator& iter) noexcept; + /** Called when an empty array is found. */ + simdjson_warn_unused simdjson_inline error_code visit_empty_array(json_iterator& iter) noexcept; + + /** Called when a non-empty object starts. */ + simdjson_warn_unused simdjson_inline error_code visit_object_start(json_iterator& iter) noexcept; + /** + * Called when a key in a field is encountered. + * + * primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array + * will be called after this with the field value. + */ + simdjson_warn_unused simdjson_inline error_code visit_key(json_iterator& iter, const uint8_t* key) noexcept; + /** Called when a non-empty object ends. */ + simdjson_warn_unused simdjson_inline error_code visit_object_end(json_iterator& iter) noexcept; + /** Called when an empty object is found. */ + simdjson_warn_unused simdjson_inline error_code visit_empty_object(json_iterator& iter) noexcept; + + /** + * Called when a string, number, boolean or null is found. + */ + simdjson_warn_unused simdjson_inline error_code visit_primitive(json_iterator& iter, const uint8_t* value) noexcept; + /** + * Called when a string, number, boolean or null is found at the top level of a document (i.e. + * when there is no array or object and the entire document is a single string, number, boolean or + * null. + * + * This is separate from primitive() because simdjson's normal primitive parsing routines assume + * there is at least one more token after the value, which is only true in an array or object. + */ + simdjson_warn_unused simdjson_inline error_code visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept; + + simdjson_warn_unused simdjson_inline error_code visit_string(json_iterator& iter, const uint8_t* value, bool key = false) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_number(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept; + + simdjson_warn_unused simdjson_inline error_code visit_root_string(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_number(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept; + + /** Called each time a new field or element in an array or object is found. */ + simdjson_warn_unused simdjson_inline error_code increment_count(json_iterator& iter) noexcept; + + /** Next location to write to tape */ + tape_writer tape; + private: + /** Next write location in the string buf for stage 2 parsing */ + uint8_t* current_string_buf_loc; + + simdjson_inline tape_builder(dom::document& doc) noexcept; + + simdjson_inline uint32_t next_tape_index(json_iterator& iter) const noexcept; + simdjson_inline void start_container(json_iterator& iter) noexcept; + simdjson_warn_unused simdjson_inline error_code end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; + simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; + simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; + simdjson_inline void on_end_string(uint8_t* dst) noexcept; + }; // struct tape_builder + + template + simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( + dom_parser_implementation& dom_parser, + dom::document& doc) noexcept { + dom_parser.doc = &doc; + json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0); + tape_builder builder(doc); + return iter.walk_document(builder); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept { + return iter.visit_root_primitive(*this, value); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_primitive(json_iterator& iter, const uint8_t* value) noexcept { + return iter.visit_primitive(*this, value); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_object(json_iterator& iter) noexcept { + return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_array(json_iterator& iter) noexcept { + return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_start(json_iterator& iter) noexcept { + start_container(iter); + return SUCCESS; + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_start(json_iterator& iter) noexcept { + start_container(iter); + return SUCCESS; + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_start(json_iterator& iter) noexcept { + start_container(iter); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_end(json_iterator& iter) noexcept { + return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_end(json_iterator& iter) noexcept { + return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_end(json_iterator& iter) noexcept { + constexpr uint32_t start_tape_index = 0; + tape.append(start_tape_index, internal::tape_type::ROOT); + tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT); + return SUCCESS; + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_key(json_iterator& iter, const uint8_t* key) noexcept { + return visit_string(iter, key, true); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::increment_count(json_iterator& iter) noexcept { + iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1 + return SUCCESS; + } + + simdjson_inline tape_builder::tape_builder(dom::document& doc) noexcept : tape{ doc.tape.get() }, current_string_buf_loc{ doc.string_buf.get() } {} + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_string(json_iterator& iter, const uint8_t* value, bool key) noexcept { + iter.log_value(key ? "key" : "string"); + uint8_t* dst = on_start_string(iter); + dst = stringparsing::parse_string(value + 1, dst, false); // We do not allow replacement when the escape characters are invalid. + if (dst == nullptr) { + iter.log_error("Invalid escape in string"); + return STRING_ERROR; + } + on_end_string(dst); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_string(json_iterator& iter, const uint8_t* value) noexcept { + return visit_string(iter, value); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_number(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("number"); + return numberparsing::parse_number(value, tape); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_number(json_iterator& iter, const uint8_t* value) noexcept { + // + // We need to make a copy to make sure that the string is space terminated. + // This is not about padding the input, which should already padded up + // to len + SIMDJSON_PADDING. However, we have no control at this stage + // on how the padding was done. What if the input string was padded with nulls? + // It is quite common for an input string to have an extra null character (C string). + // We do not want to allow 9\0 (where \0 is the null character) inside a JSON + // document, but the string "9\0" by itself is fine. So we make a copy and + // pad the input with spaces when we know that there is just one input element. + // This copy is relatively expensive, but it will almost never be called in + // practice unless you are in the strange scenario where you have many JSON + // documents made of single atoms. + // + std::unique_ptrcopy(new (std::nothrow) uint8_t[iter.remaining_len() + SIMDJSON_PADDING]); + if (copy.get() == nullptr) { return MEMALLOC; } + std::memcpy(copy.get(), value, iter.remaining_len()); + std::memset(copy.get() + iter.remaining_len(), ' ', SIMDJSON_PADDING); + error_code error = visit_number(iter, copy.get()); + return error; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("true"); + if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; } + tape.append(0, internal::tape_type::TRUE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("true"); + if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; } + tape.append(0, internal::tape_type::TRUE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("false"); + if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; } + tape.append(0, internal::tape_type::FALSE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("false"); + if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; } + tape.append(0, internal::tape_type::FALSE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("null"); + if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; } + tape.append(0, internal::tape_type::NULL_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("null"); + if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; } + tape.append(0, internal::tape_type::NULL_VALUE); + return SUCCESS; + } + + // private: + + simdjson_inline uint32_t tape_builder::next_tape_index(json_iterator& iter) const noexcept { + return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get()); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { + auto start_index = next_tape_index(iter); + tape.append(start_index + 2, start); + tape.append(start_index, end); + return SUCCESS; + } + + simdjson_inline void tape_builder::start_container(json_iterator& iter) noexcept { + iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter); + iter.dom_parser.open_containers[iter.depth].count = 0; + tape.skip(); // We don't actually *write* the start element until the end. + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { + // Write the ending tape element, pointing at the start location + const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index; + tape.append(start_tape_index, end); + // Write the start tape element, pointing at the end location (and including count) + // count can overflow if it exceeds 24 bits... so we saturate + // the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff). + const uint32_t count = iter.dom_parser.open_containers[iter.depth].count; + const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count; + tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start); + return SUCCESS; + } + + simdjson_inline uint8_t* tape_builder::on_start_string(json_iterator& iter) noexcept { + // we advance the point, accounting for the fact that we have a NULL termination + tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING); + return current_string_buf_loc + sizeof(uint32_t); + } + + simdjson_inline void tape_builder::on_end_string(uint8_t* dst) noexcept { + uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t))); + // TODO check for overflow in case someone has a crazy string (>=4GB?) + // But only add the overflow check when the document itself exceeds 4GB + // Currently unneeded because we refuse to parse docs larger or equal to 4GB. + memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t)); + // NULL termination is still handy if you expect all your strings to + // be NULL terminated? It comes at a small cost + *dst = 0; + current_string_buf_loc = dst + 1; + } + + } // namespace stage2 + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H +/* end file generic/stage2/tape_builder.h for fallback */ + +// +// Stage 1 +// + namespace simdjson { namespace fallback { @@ -5296,7 +17367,7 @@ namespace simdjson { size_t max_depth, std::unique_ptr& dst ) const noexcept { - dst.reset(new (std::nothrow) dom_parser_implementation()); + dst.reset(new (std::nothrow) fallback::dom_parser_implementation()); if (!dst) { return MEMALLOC; } if (auto err = dst->set_capacity(capacity)) return err; @@ -5305,119 +17376,6 @@ namespace simdjson { return SUCCESS; } - } // namespace fallback -} // namespace simdjson - -/* begin file include/simdjson/fallback/end.h */ -/* end file include/simdjson/fallback/end.h */ -/* end file src/fallback/implementation.cpp */ -/* begin file src/fallback/dom_parser_implementation.cpp */ -/* begin file include/simdjson/fallback/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "fallback" -// #define SIMDJSON_IMPLEMENTATION fallback -/* end file include/simdjson/fallback/begin.h */ - -// -// Stage 1 -// -/* begin file src/generic/stage1/find_next_document_index.h */ -namespace simdjson { - namespace fallback { - namespace { - - /** - * This algorithm is used to quickly identify the last structural position that - * makes up a complete document. - * - * It does this by going backwards and finding the last *document boundary* (a - * place where one value follows another without a comma between them). If the - * last document (the characters after the boundary) has an equal number of - * start and end brackets, it is considered complete. - * - * Simply put, we iterate over the structural characters, starting from - * the end. We consider that we found the end of a JSON document when the - * first element of the pair is NOT one of these characters: '{' '[' ':' ',' - * and when the second element is NOT one of these characters: '}' ']' ':' ','. - * - * This simple comparison works most of the time, but it does not cover cases - * where the batch's structural indexes contain a perfect amount of documents. - * In such a case, we do not have access to the structural index which follows - * the last document, therefore, we do not have access to the second element in - * the pair, and that means we cannot identify the last document. To fix this - * issue, we keep a count of the open and closed curly/square braces we found - * while searching for the pair. When we find a pair AND the count of open and - * closed curly/square braces is the same, we know that we just passed a - * complete document, therefore the last json buffer location is the end of the - * batch. - */ - simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { - // Variant: do not count separately, just figure out depth - if (parser.n_structural_indexes == 0) { return 0; } - auto arr_cnt = 0; - auto obj_cnt = 0; - for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { - auto idxb = parser.structural_indexes[i]; - switch (parser.buf[idxb]) { - case ':': - case ',': - continue; - case '}': - obj_cnt--; - continue; - case ']': - arr_cnt--; - continue; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - auto idxa = parser.structural_indexes[i - 1]; - switch (parser.buf[idxa]) { - case '{': - case '[': - case ':': - case ',': - continue; - } - // Last document is complete, so the next document will appear after! - if (!arr_cnt && !obj_cnt) { - return parser.n_structural_indexes; - } - // Last document is incomplete; mark the document at i + 1 as the next one - return i; - } - // If we made it to the end, we want to finish counting to see if we have a full document. - switch (parser.buf[parser.structural_indexes[0]]) { - case '}': - obj_cnt--; - break; - case ']': - arr_cnt--; - break; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - if (!arr_cnt && !obj_cnt) { - // We have a complete document. - return parser.n_structural_indexes; - } - return 0; - } - - } // unnamed namespace - } // namespace fallback -} // namespace simdjson -/* end file src/generic/stage1/find_next_document_index.h */ - -namespace simdjson { - namespace fallback { namespace { namespace stage1 { @@ -5766,1053 +17724,6 @@ namespace simdjson { // // Stage 2 // -/* begin file src/generic/stage2/stringparsing.h */ -// This file contains the common code every implementation uses -// It is intended to be included multiple times and compiled multiple times - -namespace simdjson { - namespace fallback { - namespace { - /// @private - namespace stringparsing { - - // begin copypasta - // These chars yield themselves: " \ / - // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab - // u not handled in this table as it's complex - static const uint8_t escape_map[256] = { - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. - 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. - 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - }; - - // handle a unicode codepoint - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, - uint8_t** dst_ptr, bool allow_replacement) { - // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) - constexpr uint32_t substitution_code_point = 0xfffd; - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - - // We have already checked that the high surrogate is valid and - // (code_point - 0xd800) < 1024. - // - // Check that code_point_2 is in the range 0xdc00..0xdfff - // and that code_point_2 was parsed from valid hex. - uint32_t low_bit = code_point_2 - 0xdc00; - if (low_bit >> 10) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - - } - } - else if (code_point >= 0xdc00 && code_point <= 0xdfff) { - // If we encounter a low surrogate (not preceded by a high surrogate) - // then we have an error. - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - // handle a unicode codepoint using the wobbly convention - // https://simonsapin.github.io/wtf-8/ - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, - uint8_t** dst_ptr) { - // It is not ideal that this function is nearly identical to handle_unicode_codepoint. - // - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - uint32_t low_bit = code_point_2 - 0xdc00; - if ((low_bit >> 10) == 0) { - code_point = - (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - } - } - - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - /** - * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There - * must be an unescaped quote terminating the string. It returns the final output - * position as pointer. In case of error (e.g., the string has bad escaped codes), - * then null_nullptrptr is returned. It is assumed that the output buffer is large - * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + - * SIMDJSON_PADDING bytes. - */ - simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { - // It is not ideal that this function is nearly identical to parse_string. - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint_wobbly(&src, &dst)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - } // namespace stringparsing - } // unnamed namespace - } // namespace fallback -} // namespace simdjson -/* end file src/generic/stage2/stringparsing.h */ -/* begin file src/generic/stage2/tape_builder.h */ -/* begin file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/logger.h */ -// This is for an internal-only stage 2 specific logger. -// Set LOG_ENABLED = true to log what stage 2 is doing! -namespace simdjson { - namespace fallback { - namespace { - namespace logger { - - static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; - -#if SIMDJSON_VERBOSE_LOGGING - static constexpr const bool LOG_ENABLED = true; -#else - static constexpr const bool LOG_ENABLED = false; -#endif - static constexpr const int LOG_EVENT_LEN = 20; - static constexpr const int LOG_BUFFER_LEN = 30; - static constexpr const int LOG_SMALL_BUFFER_LEN = 10; - static constexpr const int LOG_INDEX_LEN = 5; - - static int log_depth; // Not threadsafe. Log only. - - // Helper to turn unprintable or newline characters into spaces - static simdjson_inline char printable_char(char c) { - if (c >= 0x20) { - return c; - } - else { - return ' '; - } - } - - // Print the header and set up log_start - static simdjson_inline void log_start() { - if (LOG_ENABLED) { - log_depth = 0; - printf("\n"); - printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#"); - printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN + 2, DASHES, LOG_BUFFER_LEN + 2, DASHES, LOG_SMALL_BUFFER_LEN + 2, DASHES, 5 + 2, DASHES); - } - } - - simdjson_unused static simdjson_inline void log_string(const char* message) { - if (LOG_ENABLED) { - printf("%s\n", message); - } - } - - // Logs a single line from the stage 2 DOM parser - template - static simdjson_inline void log_line(S& structurals, const char* title_prefix, const char* title, const char* detail) { - if (LOG_ENABLED) { - printf("| %*s%s%-*s ", log_depth * 2, "", title_prefix, LOG_EVENT_LEN - log_depth * 2 - int(strlen(title_prefix)), title); - auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural - 1; - auto next_index = structurals.next_structural; - auto current = current_index ? &structurals.buf[*current_index] : reinterpret_cast(" "); - auto next = &structurals.buf[*next_index]; - { - // Print the next N characters in the buffer. - printf("| "); - // Otherwise, print the characters starting from the buffer position. - // Print spaces for unprintable or newline characters. - for (int i = 0; i < LOG_BUFFER_LEN; i++) { - printf("%c", printable_char(current[i])); - } - printf(" "); - // Print the next N characters in the buffer. - printf("| "); - // Otherwise, print the characters starting from the buffer position. - // Print spaces for unprintable or newline characters. - for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { - printf("%c", printable_char(next[i])); - } - printf(" "); - } - if (current_index) { - printf("| %*u ", LOG_INDEX_LEN, *current_index); - } - else { - printf("| %-*s ", LOG_INDEX_LEN, ""); - } - // printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index()); - printf("| %-s ", detail); - printf("|\n"); - } - } - - } // namespace logger - } // unnamed namespace - } // namespace fallback -} // namespace simdjson -/* end file src/generic/stage2/logger.h */ - -namespace simdjson { - namespace fallback { - namespace { - namespace stage2 { - - class json_iterator { - public: - const uint8_t* const buf; - uint32_t* next_structural; - dom_parser_implementation& dom_parser; - uint32_t depth{ 0 }; - - /** - * Walk the JSON document. - * - * The visitor receives callbacks when values are encountered. All callbacks pass the iterator as - * the first parameter; some callbacks have other parameters as well: - * - * - visit_document_start() - at the beginning. - * - visit_document_end() - at the end (if things were successful). - * - * - visit_array_start() - at the start `[` of a non-empty array. - * - visit_array_end() - at the end `]` of a non-empty array. - * - visit_empty_array() - when an empty array is encountered. - * - * - visit_object_end() - at the start `]` of a non-empty object. - * - visit_object_start() - at the end `]` of a non-empty object. - * - visit_empty_object() - when an empty object is encountered. - * - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is - * guaranteed to point at the first quote of the string (`"key"`). - * - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null. - * - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null. - * - * - increment_count(iter) - each time a value is found in an array or object. - */ - template - simdjson_warn_unused simdjson_inline error_code walk_document(V& visitor) noexcept; - - /** - * Create an iterator capable of walking a JSON document. - * - * The document must have already passed through stage 1. - */ - simdjson_inline json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index); - - /** - * Look at the next token. - * - * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). - * - * They may include invalid JSON as well (such as `1.2.3` or `ture`). - */ - simdjson_inline const uint8_t* peek() const noexcept; - /** - * Advance to the next token. - * - * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). - * - * They may include invalid JSON as well (such as `1.2.3` or `ture`). - */ - simdjson_inline const uint8_t* advance() noexcept; - /** - * Get the remaining length of the document, from the start of the current token. - */ - simdjson_inline size_t remaining_len() const noexcept; - /** - * Check if we are at the end of the document. - * - * If this is true, there are no more tokens. - */ - simdjson_inline bool at_eof() const noexcept; - /** - * Check if we are at the beginning of the document. - */ - simdjson_inline bool at_beginning() const noexcept; - simdjson_inline uint8_t last_structural() const noexcept; - - /** - * Log that a value has been found. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_value(const char* type) const noexcept; - /** - * Log the start of a multipart value. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_start_value(const char* type) const noexcept; - /** - * Log the end of a multipart value. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_end_value(const char* type) const noexcept; - /** - * Log an error. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_error(const char* error) const noexcept; - - template - simdjson_warn_unused simdjson_inline error_code visit_root_primitive(V& visitor, const uint8_t* value) noexcept; - template - simdjson_warn_unused simdjson_inline error_code visit_primitive(V& visitor, const uint8_t* value) noexcept; - }; - - template - simdjson_warn_unused simdjson_inline error_code json_iterator::walk_document(V& visitor) noexcept { - logger::log_start(); - - // - // Start the document - // - if (at_eof()) { return EMPTY; } - log_start_value("document"); - SIMDJSON_TRY(visitor.visit_document_start(*this)); - - // - // Read first value - // - { - auto value = advance(); - - // Make sure the outer object or array is closed before continuing; otherwise, there are ways we - // could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906 - if (!STREAMING) { - switch (*value) { - case '{': if (last_structural() != '}') { log_value("starting brace unmatched"); return TAPE_ERROR; }; break; - case '[': if (last_structural() != ']') { log_value("starting bracket unmatched"); return TAPE_ERROR; }; break; - } - } - - switch (*value) { - case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; - case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; - default: SIMDJSON_TRY(visitor.visit_root_primitive(*this, value)); break; - } - } - goto document_end; - - // - // Object parser states - // - object_begin: - log_start_value("object"); - depth++; - if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } - dom_parser.is_array[depth] = false; - SIMDJSON_TRY(visitor.visit_object_start(*this)); - - { - auto key = advance(); - if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; } - SIMDJSON_TRY(visitor.increment_count(*this)); - SIMDJSON_TRY(visitor.visit_key(*this, key)); - } - - object_field: - if (simdjson_unlikely(*advance() != ':')) { log_error("Missing colon after key in object"); return TAPE_ERROR; } - { - auto value = advance(); - switch (*value) { - case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; - case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; - default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; - } - } - - object_continue: - switch (*advance()) { - case ',': - SIMDJSON_TRY(visitor.increment_count(*this)); - { - auto key = advance(); - if (simdjson_unlikely(*key != '"')) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; } - SIMDJSON_TRY(visitor.visit_key(*this, key)); - } - goto object_field; - case '}': log_end_value("object"); SIMDJSON_TRY(visitor.visit_object_end(*this)); goto scope_end; - default: log_error("No comma between object fields"); return TAPE_ERROR; - } - - scope_end: - depth--; - if (depth == 0) { goto document_end; } - if (dom_parser.is_array[depth]) { goto array_continue; } - goto object_continue; - - // - // Array parser states - // - array_begin: - log_start_value("array"); - depth++; - if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } - dom_parser.is_array[depth] = true; - SIMDJSON_TRY(visitor.visit_array_start(*this)); - SIMDJSON_TRY(visitor.increment_count(*this)); - - array_value: - { - auto value = advance(); - switch (*value) { - case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; - case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; - default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; - } - } - - array_continue: - switch (*advance()) { - case ',': SIMDJSON_TRY(visitor.increment_count(*this)); goto array_value; - case ']': log_end_value("array"); SIMDJSON_TRY(visitor.visit_array_end(*this)); goto scope_end; - default: log_error("Missing comma between array values"); return TAPE_ERROR; - } - - document_end: - log_end_value("document"); - SIMDJSON_TRY(visitor.visit_document_end(*this)); - - dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]); - - // If we didn't make it to the end, it's an error - if (!STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes) { - log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!"); - return TAPE_ERROR; - } - - return SUCCESS; - - } // walk_document() - - simdjson_inline json_iterator::json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) - : buf{ _dom_parser.buf }, - next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, - dom_parser{ _dom_parser } { - } - - simdjson_inline const uint8_t* json_iterator::peek() const noexcept { - return &buf[*(next_structural)]; - } - simdjson_inline const uint8_t* json_iterator::advance() noexcept { - return &buf[*(next_structural++)]; - } - simdjson_inline size_t json_iterator::remaining_len() const noexcept { - return dom_parser.len - *(next_structural - 1); - } - - simdjson_inline bool json_iterator::at_eof() const noexcept { - return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; - } - simdjson_inline bool json_iterator::at_beginning() const noexcept { - return next_structural == dom_parser.structural_indexes.get(); - } - simdjson_inline uint8_t json_iterator::last_structural() const noexcept { - return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]]; - } - - simdjson_inline void json_iterator::log_value(const char* type) const noexcept { - logger::log_line(*this, "", type, ""); - } - - simdjson_inline void json_iterator::log_start_value(const char* type) const noexcept { - logger::log_line(*this, "+", type, ""); - if (logger::LOG_ENABLED) { logger::log_depth++; } - } - - simdjson_inline void json_iterator::log_end_value(const char* type) const noexcept { - if (logger::LOG_ENABLED) { logger::log_depth--; } - logger::log_line(*this, "-", type, ""); - } - - simdjson_inline void json_iterator::log_error(const char* error) const noexcept { - logger::log_line(*this, "", "ERROR", error); - } - - template - simdjson_warn_unused simdjson_inline error_code json_iterator::visit_root_primitive(V& visitor, const uint8_t* value) noexcept { - switch (*value) { - case '"': return visitor.visit_root_string(*this, value); - case 't': return visitor.visit_root_true_atom(*this, value); - case 'f': return visitor.visit_root_false_atom(*this, value); - case 'n': return visitor.visit_root_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_root_number(*this, value); - default: - log_error("Document starts with a non-value character"); - return TAPE_ERROR; - } - } - template - simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { - switch (*value) { - case '"': return visitor.visit_string(*this, value); - case 't': return visitor.visit_true_atom(*this, value); - case 'f': return visitor.visit_false_atom(*this, value); - case 'n': return visitor.visit_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_number(*this, value); - default: - log_error("Non-value found when value was expected!"); - return TAPE_ERROR; - } - } - - } // namespace stage2 - } // unnamed namespace - } // namespace fallback -} // namespace simdjson -/* end file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/tape_writer.h */ -namespace simdjson { - namespace fallback { - namespace { - namespace stage2 { - - struct tape_writer { - /** The next place to write to tape */ - uint64_t* next_tape_loc; - - /** Write a signed 64-bit value to tape. */ - simdjson_inline void append_s64(int64_t value) noexcept; - - /** Write an unsigned 64-bit value to tape. */ - simdjson_inline void append_u64(uint64_t value) noexcept; - - /** Write a double value to tape. */ - simdjson_inline void append_double(double value) noexcept; - - /** - * Append a tape entry (an 8-bit type,and 56 bits worth of value). - */ - simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; - - /** - * Skip the current tape entry without writing. - * - * Used to skip the start of the container, since we'll come back later to fill it in when the - * container ends. - */ - simdjson_inline void skip() noexcept; - - /** - * Skip the number of tape entries necessary to write a large u64 or i64. - */ - simdjson_inline void skip_large_integer() noexcept; - - /** - * Skip the number of tape entries necessary to write a double. - */ - simdjson_inline void skip_double() noexcept; - - /** - * Write a value to a known location on tape. - * - * Used to go back and write out the start of a container after the container ends. - */ - simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; - - private: - /** - * Append both the tape entry, and a supplementary value following it. Used for types that need - * all 64 bits, such as double and uint64_t. - */ - template - simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; - }; // struct number_writer - - simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { - append2(0, value, internal::tape_type::INT64); - } - - simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { - append(0, internal::tape_type::UINT64); - *next_tape_loc = value; - next_tape_loc++; - } - - /** Write a double value to tape. */ - simdjson_inline void tape_writer::append_double(double value) noexcept { - append2(0, value, internal::tape_type::DOUBLE); - } - - simdjson_inline void tape_writer::skip() noexcept { - next_tape_loc++; - } - - simdjson_inline void tape_writer::skip_large_integer() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::skip_double() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { - *next_tape_loc = val | ((uint64_t(char(t))) << 56); - next_tape_loc++; - } - - template - simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { - append(val, t); - static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); - memcpy(next_tape_loc, &val2, sizeof(val2)); - next_tape_loc++; - } - - simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { - tape_loc = val | ((uint64_t(char(t))) << 56); - } - - } // namespace stage2 - } // unnamed namespace - } // namespace fallback -} // namespace simdjson -/* end file src/generic/stage2/tape_writer.h */ - -namespace simdjson { - namespace fallback { - namespace { - namespace stage2 { - - struct tape_builder { - template - simdjson_warn_unused static simdjson_inline error_code parse_document( - dom_parser_implementation& dom_parser, - dom::document& doc) noexcept; - - /** Called when a non-empty document starts. */ - simdjson_warn_unused simdjson_inline error_code visit_document_start(json_iterator& iter) noexcept; - /** Called when a non-empty document ends without error. */ - simdjson_warn_unused simdjson_inline error_code visit_document_end(json_iterator& iter) noexcept; - - /** Called when a non-empty array starts. */ - simdjson_warn_unused simdjson_inline error_code visit_array_start(json_iterator& iter) noexcept; - /** Called when a non-empty array ends. */ - simdjson_warn_unused simdjson_inline error_code visit_array_end(json_iterator& iter) noexcept; - /** Called when an empty array is found. */ - simdjson_warn_unused simdjson_inline error_code visit_empty_array(json_iterator& iter) noexcept; - - /** Called when a non-empty object starts. */ - simdjson_warn_unused simdjson_inline error_code visit_object_start(json_iterator& iter) noexcept; - /** - * Called when a key in a field is encountered. - * - * primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array - * will be called after this with the field value. - */ - simdjson_warn_unused simdjson_inline error_code visit_key(json_iterator& iter, const uint8_t* key) noexcept; - /** Called when a non-empty object ends. */ - simdjson_warn_unused simdjson_inline error_code visit_object_end(json_iterator& iter) noexcept; - /** Called when an empty object is found. */ - simdjson_warn_unused simdjson_inline error_code visit_empty_object(json_iterator& iter) noexcept; - - /** - * Called when a string, number, boolean or null is found. - */ - simdjson_warn_unused simdjson_inline error_code visit_primitive(json_iterator& iter, const uint8_t* value) noexcept; - /** - * Called when a string, number, boolean or null is found at the top level of a document (i.e. - * when there is no array or object and the entire document is a single string, number, boolean or - * null. - * - * This is separate from primitive() because simdjson's normal primitive parsing routines assume - * there is at least one more token after the value, which is only true in an array or object. - */ - simdjson_warn_unused simdjson_inline error_code visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept; - - simdjson_warn_unused simdjson_inline error_code visit_string(json_iterator& iter, const uint8_t* value, bool key = false) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_number(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept; - - simdjson_warn_unused simdjson_inline error_code visit_root_string(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_number(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept; - - /** Called each time a new field or element in an array or object is found. */ - simdjson_warn_unused simdjson_inline error_code increment_count(json_iterator& iter) noexcept; - - /** Next location to write to tape */ - tape_writer tape; - private: - /** Next write location in the string buf for stage 2 parsing */ - uint8_t* current_string_buf_loc; - - simdjson_inline tape_builder(dom::document& doc) noexcept; - - simdjson_inline uint32_t next_tape_index(json_iterator& iter) const noexcept; - simdjson_inline void start_container(json_iterator& iter) noexcept; - simdjson_warn_unused simdjson_inline error_code end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; - simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; - simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; - simdjson_inline void on_end_string(uint8_t* dst) noexcept; - }; // class tape_builder - - template - simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( - dom_parser_implementation& dom_parser, - dom::document& doc) noexcept { - dom_parser.doc = &doc; - json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0); - tape_builder builder(doc); - return iter.walk_document(builder); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept { - return iter.visit_root_primitive(*this, value); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_primitive(json_iterator& iter, const uint8_t* value) noexcept { - return iter.visit_primitive(*this, value); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_object(json_iterator& iter) noexcept { - return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_array(json_iterator& iter) noexcept { - return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_start(json_iterator& iter) noexcept { - start_container(iter); - return SUCCESS; - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_start(json_iterator& iter) noexcept { - start_container(iter); - return SUCCESS; - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_start(json_iterator& iter) noexcept { - start_container(iter); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_end(json_iterator& iter) noexcept { - return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_end(json_iterator& iter) noexcept { - return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_end(json_iterator& iter) noexcept { - constexpr uint32_t start_tape_index = 0; - tape.append(start_tape_index, internal::tape_type::ROOT); - tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT); - return SUCCESS; - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_key(json_iterator& iter, const uint8_t* key) noexcept { - return visit_string(iter, key, true); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::increment_count(json_iterator& iter) noexcept { - iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1 - return SUCCESS; - } - - simdjson_inline tape_builder::tape_builder(dom::document& doc) noexcept : tape{ doc.tape.get() }, current_string_buf_loc{ doc.string_buf.get() } {} - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_string(json_iterator& iter, const uint8_t* value, bool key) noexcept { - iter.log_value(key ? "key" : "string"); - uint8_t* dst = on_start_string(iter); - dst = stringparsing::parse_string(value + 1, dst, false); // We do not allow replacement when the escape characters are invalid. - if (dst == nullptr) { - iter.log_error("Invalid escape in string"); - return STRING_ERROR; - } - on_end_string(dst); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_string(json_iterator& iter, const uint8_t* value) noexcept { - return visit_string(iter, value); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_number(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("number"); - return numberparsing::parse_number(value, tape); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_number(json_iterator& iter, const uint8_t* value) noexcept { - // - // We need to make a copy to make sure that the string is space terminated. - // This is not about padding the input, which should already padded up - // to len + SIMDJSON_PADDING. However, we have no control at this stage - // on how the padding was done. What if the input string was padded with nulls? - // It is quite common for an input string to have an extra null character (C string). - // We do not want to allow 9\0 (where \0 is the null character) inside a JSON - // document, but the string "9\0" by itself is fine. So we make a copy and - // pad the input with spaces when we know that there is just one input element. - // This copy is relatively expensive, but it will almost never be called in - // practice unless you are in the strange scenario where you have many JSON - // documents made of single atoms. - // - std::unique_ptrcopy(new (std::nothrow) uint8_t[iter.remaining_len() + SIMDJSON_PADDING]); - if (copy.get() == nullptr) { return MEMALLOC; } - std::memcpy(copy.get(), value, iter.remaining_len()); - std::memset(copy.get() + iter.remaining_len(), ' ', SIMDJSON_PADDING); - error_code error = visit_number(iter, copy.get()); - return error; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("true"); - if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; } - tape.append(0, internal::tape_type::TRUE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("true"); - if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; } - tape.append(0, internal::tape_type::TRUE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("false"); - if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; } - tape.append(0, internal::tape_type::FALSE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("false"); - if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; } - tape.append(0, internal::tape_type::FALSE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("null"); - if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; } - tape.append(0, internal::tape_type::NULL_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("null"); - if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; } - tape.append(0, internal::tape_type::NULL_VALUE); - return SUCCESS; - } - - // private: - - simdjson_inline uint32_t tape_builder::next_tape_index(json_iterator& iter) const noexcept { - return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get()); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { - auto start_index = next_tape_index(iter); - tape.append(start_index + 2, start); - tape.append(start_index, end); - return SUCCESS; - } - - simdjson_inline void tape_builder::start_container(json_iterator& iter) noexcept { - iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter); - iter.dom_parser.open_containers[iter.depth].count = 0; - tape.skip(); // We don't actually *write* the start element until the end. - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { - // Write the ending tape element, pointing at the start location - const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index; - tape.append(start_tape_index, end); - // Write the start tape element, pointing at the end location (and including count) - // count can overflow if it exceeds 24 bits... so we saturate - // the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff). - const uint32_t count = iter.dom_parser.open_containers[iter.depth].count; - const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count; - tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start); - return SUCCESS; - } - - simdjson_inline uint8_t* tape_builder::on_start_string(json_iterator& iter) noexcept { - // we advance the point, accounting for the fact that we have a NULL termination - tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING); - return current_string_buf_loc + sizeof(uint32_t); - } - - simdjson_inline void tape_builder::on_end_string(uint8_t* dst) noexcept { - uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t))); - // TODO check for overflow in case someone has a crazy string (>=4GB?) - // But only add the overflow check when the document itself exceeds 4GB - // Currently unneeded because we refuse to parse docs larger or equal to 4GB. - memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t)); - // NULL termination is still handy if you expect all your strings to - // be NULL terminated? It comes at a small cost - *dst = 0; - current_string_buf_loc = dst + 1; - } - - } // namespace stage2 - } // unnamed namespace - } // namespace fallback -} // namespace simdjson -/* end file src/generic/stage2/tape_builder.h */ namespace simdjson { namespace fallback { @@ -6842,155 +17753,3829 @@ namespace simdjson { } // namespace fallback } // namespace simdjson -/* begin file include/simdjson/fallback/end.h */ -/* end file include/simdjson/fallback/end.h */ -/* end file src/fallback/dom_parser_implementation.cpp */ +/* including simdjson/fallback/end.h: #include */ +/* begin file simdjson/fallback/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* undefining SIMDJSON_IMPLEMENTATION from "fallback" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/fallback/end.h */ + +#endif // SIMDJSON_SRC_FALLBACK_CPP +/* end file fallback.cpp */ #endif -#if SIMDJSON_IMPLEMENTATION_ICELAKE -/* begin file src/icelake/implementation.cpp */ -/* begin file include/simdjson/icelake/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "icelake" -// #define SIMDJSON_IMPLEMENTATION icelake -SIMDJSON_TARGET_ICELAKE -/* end file include/simdjson/icelake/begin.h */ +#if SIMDJSON_IMPLEMENTATION_HASWELL +/* including haswell.cpp: #include */ +/* begin file haswell.cpp */ +#ifndef SIMDJSON_SRC_HASWELL_CPP +#define SIMDJSON_SRC_HASWELL_CPP +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* including simdjson/haswell.h: #include */ +/* begin file simdjson/haswell.h */ +#ifndef SIMDJSON_HASWELL_H +#define SIMDJSON_HASWELL_H + +/* including simdjson/haswell/begin.h: #include "simdjson/haswell/begin.h" */ +/* begin file simdjson/haswell/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "haswell" */ +#define SIMDJSON_IMPLEMENTATION haswell + +/* including simdjson/haswell/base.h: #include "simdjson/haswell/base.h" */ +/* begin file simdjson/haswell/base.h */ +#ifndef SIMDJSON_HASWELL_BASE_H +#define SIMDJSON_HASWELL_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL namespace simdjson { - namespace icelake { + /** + * Implementation for Haswell (Intel AVX2). + */ + namespace haswell { - simdjson_warn_unused error_code implementation::create_dom_parser_implementation( - size_t capacity, - size_t max_depth, - std::unique_ptr& dst - ) const noexcept { - dst.reset(new (std::nothrow) dom_parser_implementation()); - if (!dst) { return MEMALLOC; } - if (auto err = dst->set_capacity(capacity)) - return err; - if (auto err = dst->set_max_depth(max_depth)) - return err; - return SUCCESS; - } + class implementation; - } // namespace icelake + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace haswell } // namespace simdjson -/* begin file include/simdjson/icelake/end.h */ -SIMDJSON_UNTARGET_ICELAKE -/* end file include/simdjson/icelake/end.h */ +#endif // SIMDJSON_HASWELL_BASE_H +/* end file simdjson/haswell/base.h */ +/* including simdjson/haswell/intrinsics.h: #include "simdjson/haswell/intrinsics.h" */ +/* begin file simdjson/haswell/intrinsics.h */ +#ifndef SIMDJSON_HASWELL_INTRINSICS_H +#define SIMDJSON_HASWELL_INTRINSICS_H -/* end file src/icelake/implementation.cpp */ -/* begin file src/icelake/dom_parser_implementation.cpp */ -/* begin file include/simdjson/icelake/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "icelake" -// #define SIMDJSON_IMPLEMENTATION icelake -SIMDJSON_TARGET_ICELAKE -/* end file include/simdjson/icelake/begin.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ -// -// Stage 1 -// +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + * e.g., if __AVX2__ is set... in turn, we normally set these + * macros by compiling against the corresponding architecture + * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole + * software with these advanced instructions. In simdjson, we + * want to compile the whole program for a generic target, + * and only target our specific kernels. As a workaround, + * we directly include the needed headers. These headers would + * normally guard against such usage, but we carefully included + * (or ) before, so the headers + * are fooled. + */ +#include // for _blsr_u64 +#include // for __lzcnt64 +#include // for most things (AVX2, AVX512, _popcnt64) +#include +#include +#include +#include +#include // for _mm_clmulepi64_si128 + // unfortunately, we may not get _blsr_u64, but, thankfully, clang + // has it as a macro. +#ifndef _blsr_u64 +// we roll our own +#define _blsr_u64(n) ((n - 1) & n) +#endif // _blsr_u64 +#endif // SIMDJSON_CLANG_VISUAL_STUDIO + +static_assert(sizeof(__m256i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for haswell kernel."); + +#endif // SIMDJSON_HASWELL_INTRINSICS_H +/* end file simdjson/haswell/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_TARGET_REGION("avx2,bmi,pclmul,lzcnt,popcnt") +#endif + +/* including simdjson/haswell/bitmanipulation.h: #include "simdjson/haswell/bitmanipulation.h" */ +/* begin file simdjson/haswell/bitmanipulation.h */ +#ifndef SIMDJSON_HASWELL_BITMANIPULATION_H +#define SIMDJSON_HASWELL_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmask.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace icelake { + namespace haswell { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return (int)_tzcnt_u64(input_num); +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + //////// + // You might expect the next line to be equivalent to + // return (int)_tzcnt_u64(input_num); + // but the generated code differs and might be less efficient? + //////// + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return _blsr_u64(input_num); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { + return int(_lzcnt_u64(input_num)); + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BITMANIPULATION_H +/* end file simdjson/haswell/bitmanipulation.h */ +/* including simdjson/haswell/bitmask.h: #include "simdjson/haswell/bitmask.h" */ +/* begin file simdjson/haswell/bitmask.h */ +#ifndef SIMDJSON_HASWELL_BITMASK_H +#define SIMDJSON_HASWELL_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processor supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BITMASK_H +/* end file simdjson/haswell/bitmask.h */ +/* including simdjson/haswell/numberparsing_defs.h: #include "simdjson/haswell/numberparsing_defs.h" */ +/* begin file simdjson/haswell/numberparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +#define SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace haswell +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +/* end file simdjson/haswell/numberparsing_defs.h */ +/* including simdjson/haswell/simd.h: #include "simdjson/haswell/simd.h" */ +/* begin file simdjson/haswell/simd.h */ +#ifndef SIMDJSON_HASWELL_SIMD_H +#define SIMDJSON_HASWELL_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace simd { + + // Forward-declared so they can be used by splat and friends. + template + struct base { + __m256i value; + + // Zero constructor + simdjson_inline base() : value{ __m256i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m256i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m256i& () const { return this->value; } + simdjson_inline operator __m256i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm256_or_si256(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm256_and_si256(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm256_xor_si256(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm256_andnot_si256(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + // Forward-declared so they can be used by splat and friends. + template + struct simd8; + + template> + struct base8 : base> { + typedef uint32_t bitmask_t; + typedef uint64_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m256i _value) : base>(_value) {} + + friend simdjson_really_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm256_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm256_alignr_epi8(*this, _mm256_permute2x128_si256(prev_chunk, *this, 0x21), 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm256_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m256i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm256_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm256_testz_si256(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm256_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm256_setzero_si256(); } + static simdjson_inline simd8 load(const T values[32]) { + return _mm256_loadu_si256(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m256i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[32]) const { return _mm256_storeu_si256(reinterpret_cast<__m256i*>(dst), *this); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm256_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm256_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm256_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint32_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in four steps, first 8 bytes and then second 8 bytes... + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // second least significant 8 bits + uint8_t mask3 = uint8_t(mask >> 16); // ... + uint8_t mask4 = uint8_t(mask >> 24); // ... + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m256i shufmask = _mm256_set_epi64x(thintable_epi8[mask4], thintable_epi8[mask3], + thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask and so forth + shufmask = + _mm256_add_epi8(shufmask, _mm256_set_epi32(0x18181818, 0x18181818, + 0x10101010, 0x10101010, 0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m256i pruned = _mm256_shuffle_epi8(*this, shufmask); + // we still need to put the pieces back together. + // we compute the popcount of the first words: + int pop1 = BitsSetTable256mul2[mask1]; + int pop3 = BitsSetTable256mul2[mask3]; + + // then load the corresponding mask + // could be done with _mm256_loadu2_m128i but many standard libraries omit this intrinsic. + __m256i v256 = _mm256_castsi128_si256( + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8))); + __m256i compactmask = _mm256_insertf128_si256(v256, + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop3 * 8)), 1); + __m256i almostthere = _mm256_shuffle_epi8(pruned, compactmask); + // We just need to write out the result. + // This is the tricky bit that is hard to do + // if we want to return a SIMD register, since there + // is no single-instruction approach to recombine + // the two 128-bit lanes with an offset. + __m128i v128; + v128 = _mm256_castsi256_si128(almostthere); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), v128); + v128 = _mm256_extractf128_si256(almostthere, 1); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output + 16 - count_ones(mask & 0xFFFF)), v128); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m256i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t values[32]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, + int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, + int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31 + ) : simd8(_mm256_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v16, v17, v18, v19, v20, v21, v22, v23, + v24, v25, v26, v27, v28, v29, v30, v31 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm256_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm256_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm256_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm256_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m256i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[32]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, + uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, + uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31 + ) : simd8(_mm256_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v16, v17, v18, v19, v20, v21, v22, v23, + v24, v25, v26, v27, v28, v29, v30, v31 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm256_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm256_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm256_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm256_min_epu8(other, *this); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm256_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm256_testz_si256(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm256_testz_si256(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm256_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm256_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm256_movemask_epi8(_mm256_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 2, "Haswell kernel should use two registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 32) } {} + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + uint32_t mask1 = uint32_t(mask); + uint32_t mask2 = uint32_t(mask >> 32); + this->chunks[0].compress(mask1, output); + this->chunks[1].compress(mask2, output + 32 - count_ones(mask1)); + return 64 - count_ones(mask); + } + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r_lo = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r_hi = this->chunks[1].to_bitmask(); + return r_lo | (r_hi << 32); + } + + simdjson_inline simd8 reduce_or() const { + return this->chunks[0] | this->chunks[1]; + } + + simdjson_inline simd8x64 bit_or(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] | mask, + this->chunks[1] | mask + ); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_SIMD_H +/* end file simdjson/haswell/simd.h */ +/* including simdjson/haswell/stringparsing_defs.h: #include "simdjson/haswell/stringparsing_defs.h" */ +/* begin file simdjson/haswell/stringparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +#define SIMDJSON_HASWELL_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { namespace { using namespace simd; - struct json_character_block { - static simdjson_inline json_character_block classify(const simd::simd8x64& in); - // ASCII white-space ('\r','\n','\t',' ') - simdjson_inline uint64_t whitespace() const noexcept; - // non-quote structural characters (comma, colon, braces, brackets) - simdjson_inline uint64_t op() const noexcept; - // neither a structural character nor a white-space, so letters, numbers and quotes - simdjson_inline uint64_t scalar() const noexcept; + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); - uint64_t _whitespace; // ASCII white-space ('\r','\n','\t',' ') - uint64_t _op; // structural characters (comma, colon, braces, brackets but not quotes) - }; + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } - simdjson_inline uint64_t json_character_block::whitespace() const noexcept { return _whitespace; } - simdjson_inline uint64_t json_character_block::op() const noexcept { return _op; } - simdjson_inline uint64_t json_character_block::scalar() const noexcept { return ~(op() | whitespace()); } + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote - // This identifies structural characters (comma, colon, braces, brackets), - // and ASCII white-space ('\r','\n','\t',' '). - simdjson_inline json_character_block json_character_block::classify(const simd::simd8x64& in) { - // These lookups rely on the fact that anything < 127 will match the lower 4 bits, which is why - // we can't use the generic lookup_16. - const auto whitespace_table = simd8::repeat_16(' ', 100, 100, 100, 17, 100, 113, 2, 100, '\t', '\n', 112, 100, '\r', 100, 100); - - // The 6 operators (:,[]{}) have these values: - // - // , 2C - // : 3A - // [ 5B - // { 7B - // ] 5D - // } 7D - // - // If you use | 0x20 to turn [ and ] into { and }, the lower 4 bits of each character is unique. - // We exploit this, using a simd 4-bit lookup to tell us which character match against, and then - // match it (against | 0x20). - // - // To prevent recognizing other characters, everything else gets compared with 0, which cannot - // match due to the | 0x20. - // - // NOTE: Due to the | 0x20, this ALSO treats and (control characters 0C and 1A) like , - // and :. This gets caught in stage 2, which checks the actual character to ensure the right - // operators are in the right places. - const auto op_table = simd8::repeat_16( - 0, 0, 0, 0, - 0, 0, 0, 0, - 0, 0, ':', '{', // : = 3A, [ = 5B, { = 7B - ',', '}', 0, 0 // , = 2C, ] = 5D, } = 7D - ); - - // We compute whitespace and op separately. If later code only uses one or the - // other, given the fact that all functions are aggressively inlined, we can - // hope that useless computations will be omitted. This is namely case when - // minifying (we only need whitespace). - - const uint64_t whitespace = in.eq({ - _mm512_shuffle_epi8(whitespace_table, in.chunks[0]) - }); - // Turn [ and ] into { and } - const simd8x64 curlified{ - in.chunks[0] | 0x20 + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast((v == '\\').to_bitmask()), // bs_bits + static_cast((v == '"').to_bitmask()), // quote_bits }; - const uint64_t op = curlified.eq({ - _mm512_shuffle_epi8(op_table, in.chunks[0]) - }); - - return { whitespace, op }; - } - - simdjson_inline bool is_ascii(const simd8x64& input) { - return input.reduce_or().is_ascii(); - } - - simdjson_unused simdjson_inline simd8 must_be_continuation(const simd8 prev1, const simd8 prev2, const simd8 prev3) { - simd8 is_second_byte = prev1.saturating_sub(0xc0u - 1); // Only 11______ will be > 0 - simd8 is_third_byte = prev2.saturating_sub(0xe0u - 1); // Only 111_____ will be > 0 - simd8 is_fourth_byte = prev3.saturating_sub(0xf0u - 1); // Only 1111____ will be > 0 - // Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine. - return simd8(is_second_byte | is_third_byte | is_fourth_byte) > int8_t(0); - } - - simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3) { - simd8 is_third_byte = prev2.saturating_sub(0xe0u - 1); // Only 111_____ will be > 0 - simd8 is_fourth_byte = prev3.saturating_sub(0xf0u - 1); // Only 1111____ will be > 0 - // Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine. - return simd8(is_third_byte | is_fourth_byte) > int8_t(0); } } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */ +#endif // SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +/* end file simdjson/haswell/stringparsing_defs.h */ +/* end file simdjson/haswell/begin.h */ +/* including simdjson/generic/amalgamated.h for haswell: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for haswell */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for haswell: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for haswell */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace icelake { + namespace haswell { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for haswell */ +/* including simdjson/generic/jsoncharutils.h for haswell: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for haswell */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace jsoncharutils { + + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for haswell */ +/* including simdjson/generic/atomparsing.h for haswell: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for haswell */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace haswell { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for haswell */ +/* including simdjson/generic/dom_parser_implementation.h for haswell: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for haswell */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container + + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); + + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; + + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; + + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; + + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + namespace haswell { + + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; + } + + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for haswell */ +/* including simdjson/generic/implementation_simdjson_result_base.h for haswell: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for haswell */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); + + +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for haswell */ +/* including simdjson/generic/numberparsing.h for haswell: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for haswell */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace haswell { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing +// +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. +// +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for haswell */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for haswell: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for haswell */ +/* end file simdjson/generic/amalgamated.h for haswell */ +/* including simdjson/haswell/end.h: #include "simdjson/haswell/end.h" */ +/* begin file simdjson/haswell/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "haswell" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/haswell/end.h */ + +#endif // SIMDJSON_HASWELL_H +/* end file simdjson/haswell.h */ +/* including simdjson/haswell/implementation.h: #include */ +/* begin file simdjson/haswell/implementation.h */ +#ifndef SIMDJSON_HASWELL_IMPLEMENTATION_H +#define SIMDJSON_HASWELL_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL +namespace simdjson { + namespace haswell { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "haswell", + "Intel/AMD AVX2", + internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_IMPLEMENTATION_H +/* end file simdjson/haswell/implementation.h */ + +/* including simdjson/haswell/begin.h: #include */ +/* begin file simdjson/haswell/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "haswell" */ +#define SIMDJSON_IMPLEMENTATION haswell + +/* including simdjson/haswell/base.h: #include "simdjson/haswell/base.h" */ +/* begin file simdjson/haswell/base.h */ +#ifndef SIMDJSON_HASWELL_BASE_H +#define SIMDJSON_HASWELL_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL +namespace simdjson { + /** + * Implementation for Haswell (Intel AVX2). + */ + namespace haswell { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BASE_H +/* end file simdjson/haswell/base.h */ +/* including simdjson/haswell/intrinsics.h: #include "simdjson/haswell/intrinsics.h" */ +/* begin file simdjson/haswell/intrinsics.h */ +#ifndef SIMDJSON_HASWELL_INTRINSICS_H +#define SIMDJSON_HASWELL_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + * e.g., if __AVX2__ is set... in turn, we normally set these + * macros by compiling against the corresponding architecture + * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole + * software with these advanced instructions. In simdjson, we + * want to compile the whole program for a generic target, + * and only target our specific kernels. As a workaround, + * we directly include the needed headers. These headers would + * normally guard against such usage, but we carefully included + * (or ) before, so the headers + * are fooled. + */ +#include // for _blsr_u64 +#include // for __lzcnt64 +#include // for most things (AVX2, AVX512, _popcnt64) +#include +#include +#include +#include +#include // for _mm_clmulepi64_si128 + // unfortunately, we may not get _blsr_u64, but, thankfully, clang + // has it as a macro. +#ifndef _blsr_u64 +// we roll our own +#define _blsr_u64(n) ((n - 1) & n) +#endif // _blsr_u64 +#endif // SIMDJSON_CLANG_VISUAL_STUDIO + +static_assert(sizeof(__m256i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for haswell kernel."); + +#endif // SIMDJSON_HASWELL_INTRINSICS_H +/* end file simdjson/haswell/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_TARGET_REGION("avx2,bmi,pclmul,lzcnt,popcnt") +#endif + +/* including simdjson/haswell/bitmanipulation.h: #include "simdjson/haswell/bitmanipulation.h" */ +/* begin file simdjson/haswell/bitmanipulation.h */ +#ifndef SIMDJSON_HASWELL_BITMANIPULATION_H +#define SIMDJSON_HASWELL_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmask.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return (int)_tzcnt_u64(input_num); +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + //////// + // You might expect the next line to be equivalent to + // return (int)_tzcnt_u64(input_num); + // but the generated code differs and might be less efficient? + //////// + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return _blsr_u64(input_num); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { + return int(_lzcnt_u64(input_num)); + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BITMANIPULATION_H +/* end file simdjson/haswell/bitmanipulation.h */ +/* including simdjson/haswell/bitmask.h: #include "simdjson/haswell/bitmask.h" */ +/* begin file simdjson/haswell/bitmask.h */ +#ifndef SIMDJSON_HASWELL_BITMASK_H +#define SIMDJSON_HASWELL_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processor supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BITMASK_H +/* end file simdjson/haswell/bitmask.h */ +/* including simdjson/haswell/numberparsing_defs.h: #include "simdjson/haswell/numberparsing_defs.h" */ +/* begin file simdjson/haswell/numberparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +#define SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace haswell +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +/* end file simdjson/haswell/numberparsing_defs.h */ +/* including simdjson/haswell/simd.h: #include "simdjson/haswell/simd.h" */ +/* begin file simdjson/haswell/simd.h */ +#ifndef SIMDJSON_HASWELL_SIMD_H +#define SIMDJSON_HASWELL_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace simd { + + // Forward-declared so they can be used by splat and friends. + template + struct base { + __m256i value; + + // Zero constructor + simdjson_inline base() : value{ __m256i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m256i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m256i& () const { return this->value; } + simdjson_inline operator __m256i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm256_or_si256(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm256_and_si256(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm256_xor_si256(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm256_andnot_si256(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + // Forward-declared so they can be used by splat and friends. + template + struct simd8; + + template> + struct base8 : base> { + typedef uint32_t bitmask_t; + typedef uint64_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m256i _value) : base>(_value) {} + + friend simdjson_really_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm256_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm256_alignr_epi8(*this, _mm256_permute2x128_si256(prev_chunk, *this, 0x21), 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm256_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m256i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm256_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm256_testz_si256(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm256_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm256_setzero_si256(); } + static simdjson_inline simd8 load(const T values[32]) { + return _mm256_loadu_si256(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m256i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[32]) const { return _mm256_storeu_si256(reinterpret_cast<__m256i*>(dst), *this); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm256_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm256_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm256_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint32_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in four steps, first 8 bytes and then second 8 bytes... + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // second least significant 8 bits + uint8_t mask3 = uint8_t(mask >> 16); // ... + uint8_t mask4 = uint8_t(mask >> 24); // ... + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m256i shufmask = _mm256_set_epi64x(thintable_epi8[mask4], thintable_epi8[mask3], + thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask and so forth + shufmask = + _mm256_add_epi8(shufmask, _mm256_set_epi32(0x18181818, 0x18181818, + 0x10101010, 0x10101010, 0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m256i pruned = _mm256_shuffle_epi8(*this, shufmask); + // we still need to put the pieces back together. + // we compute the popcount of the first words: + int pop1 = BitsSetTable256mul2[mask1]; + int pop3 = BitsSetTable256mul2[mask3]; + + // then load the corresponding mask + // could be done with _mm256_loadu2_m128i but many standard libraries omit this intrinsic. + __m256i v256 = _mm256_castsi128_si256( + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8))); + __m256i compactmask = _mm256_insertf128_si256(v256, + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop3 * 8)), 1); + __m256i almostthere = _mm256_shuffle_epi8(pruned, compactmask); + // We just need to write out the result. + // This is the tricky bit that is hard to do + // if we want to return a SIMD register, since there + // is no single-instruction approach to recombine + // the two 128-bit lanes with an offset. + __m128i v128; + v128 = _mm256_castsi256_si128(almostthere); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), v128); + v128 = _mm256_extractf128_si256(almostthere, 1); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output + 16 - count_ones(mask & 0xFFFF)), v128); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m256i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t values[32]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, + int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, + int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31 + ) : simd8(_mm256_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v16, v17, v18, v19, v20, v21, v22, v23, + v24, v25, v26, v27, v28, v29, v30, v31 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm256_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm256_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm256_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm256_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m256i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[32]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, + uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, + uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31 + ) : simd8(_mm256_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v16, v17, v18, v19, v20, v21, v22, v23, + v24, v25, v26, v27, v28, v29, v30, v31 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm256_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm256_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm256_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm256_min_epu8(other, *this); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm256_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm256_testz_si256(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm256_testz_si256(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm256_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm256_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm256_movemask_epi8(_mm256_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 2, "Haswell kernel should use two registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 32) } {} + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + uint32_t mask1 = uint32_t(mask); + uint32_t mask2 = uint32_t(mask >> 32); + this->chunks[0].compress(mask1, output); + this->chunks[1].compress(mask2, output + 32 - count_ones(mask1)); + return 64 - count_ones(mask); + } + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r_lo = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r_hi = this->chunks[1].to_bitmask(); + return r_lo | (r_hi << 32); + } + + simdjson_inline simd8 reduce_or() const { + return this->chunks[0] | this->chunks[1]; + } + + simdjson_inline simd8x64 bit_or(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] | mask, + this->chunks[1] | mask + ); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_SIMD_H +/* end file simdjson/haswell/simd.h */ +/* including simdjson/haswell/stringparsing_defs.h: #include "simdjson/haswell/stringparsing_defs.h" */ +/* begin file simdjson/haswell/stringparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +#define SIMDJSON_HASWELL_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast((v == '\\').to_bitmask()), // bs_bits + static_cast((v == '"').to_bitmask()), // quote_bits + }; + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +/* end file simdjson/haswell/stringparsing_defs.h */ +/* end file simdjson/haswell/begin.h */ +/* including generic/amalgamated.h for haswell: #include */ +/* begin file generic/amalgamated.h for haswell */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_SRC_GENERIC_DEPENDENCIES_H) +#error generic/dependencies.h must be included before generic/amalgamated.h! +#endif + +/* including generic/base.h for haswell: #include */ +/* begin file generic/base.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + struct json_character_block; + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_BASE_H +/* end file generic/base.h for haswell */ +/* including generic/dom_parser_implementation.h for haswell: #include */ +/* begin file generic/dom_parser_implementation.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// Interface a dom parser implementation must fulfill +namespace simdjson { + namespace haswell { + namespace { + + simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3); + simdjson_inline bool is_ascii(const simd8x64& input); + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file generic/dom_parser_implementation.h for haswell */ +/* including generic/json_character_block.h for haswell: #include */ +/* begin file generic/json_character_block.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + struct json_character_block { + static simdjson_inline json_character_block classify(const simd::simd8x64& in); + + simdjson_inline uint64_t whitespace() const noexcept { return _whitespace; } + simdjson_inline uint64_t op() const noexcept { return _op; } + simdjson_inline uint64_t scalar() const noexcept { return ~(op() | whitespace()); } + + uint64_t _whitespace; + uint64_t _op; + }; + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H +/* end file generic/json_character_block.h for haswell */ +/* end file generic/amalgamated.h for haswell */ +/* including generic/stage1/amalgamated.h for haswell: #include */ +/* begin file generic/stage1/amalgamated.h for haswell */ +// Stuff other things depend on +/* including generic/stage1/base.h for haswell: #include */ +/* begin file generic/stage1/base.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace stage1 { + + class bit_indexer; + template + struct buf_block_reader; + struct json_block; + class json_minifier; + class json_scanner; + struct json_string_block; + class json_string_scanner; + class json_structural_indexer; + + } // namespace stage1 + + namespace utf8_validation { + struct utf8_checker; + } // namespace utf8_validation + + using utf8_validation::utf8_checker; + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BASE_H +/* end file generic/stage1/base.h for haswell */ +/* including generic/stage1/buf_block_reader.h for haswell: #include */ +/* begin file generic/stage1/buf_block_reader.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace haswell { + namespace { + namespace stage1 { + + // Walks through a buffer in block-sized increments, loading the last part with spaces + template + struct buf_block_reader { + public: + simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); + simdjson_inline size_t block_index(); + simdjson_inline bool has_full_block() const; + simdjson_inline const uint8_t* full_block() const; + /** + * Get the last block, padded with spaces. + * + * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this + * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there + * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. + * + * @return the number of effective characters in the last block. + */ + simdjson_inline size_t get_remainder(uint8_t* dst) const; + simdjson_inline void advance(); + private: + const uint8_t* buf; + const size_t len; + const size_t lenminusstep; + size_t idx; + }; + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text_64(const uint8_t* text) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < sizeof(simd8x64); i++) { + buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text(const simd8x64& in) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] < ' ') { buf[i] = '_'; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_input_text(const simd8x64& in, uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] <= ' ') { buf[i] = '_'; } + if (!(mask & (size_t(1) << i))) { buf[i] = ' '; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_mask(uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < 64; i++) { + buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; + } + buf[64] = '\0'; + return buf; + } + + template + simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} + + template + simdjson_inline size_t buf_block_reader::block_index() { return idx; } + + template + simdjson_inline bool buf_block_reader::has_full_block() const { + return idx < lenminusstep; + } + + template + simdjson_inline const uint8_t* buf_block_reader::full_block() const { + return &buf[idx]; + } + + template + simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { + if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers + std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. + std::memcpy(dst, buf + idx, len - idx); + return len - idx; + } + + template + simdjson_inline void buf_block_reader::advance() { + idx += STEP_SIZE; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H +/* end file generic/stage1/buf_block_reader.h for haswell */ +/* including generic/stage1/json_escape_scanner.h for haswell: #include */ +/* begin file generic/stage1/json_escape_scanner.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace stage1 { + + /** + * Scans for escape characters in JSON, taking care with multiple backslashes (\\n vs. \n). + */ + struct json_escape_scanner { + /** The actual escape characters (the backslashes themselves). */ + uint64_t next_is_escaped = 0ULL; + + struct escaped_and_escape { + /** + * Mask of escaped characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 0100100010100101000 + * n \ \ n \ \ + * ``` + */ + uint64_t escaped; + /** + * Mask of escape characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 1001000101001010001 + * \ \ \ \ \ \ \ + * ``` + */ + uint64_t escape; + }; + + /** + * Get a mask of both escape and escaped characters (the characters following a backslash). + * + * @param potential_escape A mask of the character that can escape others (but could be + * escaped itself). e.g. block.eq('\\') + */ + simdjson_really_inline escaped_and_escape next(uint64_t backslash) noexcept { + +#if !SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT + if (!backslash) { return { next_escaped_without_backslashes(), 0 }; } +#endif + + // | | Mask (shows characters instead of 1's) | Depth | Instructions | + // |--------------------------------|----------------------------------------|-------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | | | + // | | ` even odd even odd odd` | | | + // | potential_escape | ` \ \\\ \\\ \\\\ \\\\ \\\` | 1 | 1 (backslash & ~first_is_escaped) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 5 | 5 (next_escape_and_terminal_code()) + // | escaped | `\ \ n \ n \ \ \ \ \ ` X | 6 | 7 (escape_and_terminal_code ^ (potential_escape | first_is_escaped)) + // | escape | ` \ \ \ \ \ \ \ \ \ \` | 6 | 8 (escape_and_terminal_code & backslash) + // | first_is_escaped | `\ ` | 7 (*) | 9 (escape >> 63) () + // (*) this is not needed until the next iteration + uint64_t escape_and_terminal_code = next_escape_and_terminal_code(backslash & ~this->next_is_escaped); + uint64_t escaped = escape_and_terminal_code ^ (backslash | this->next_is_escaped); + uint64_t escape = escape_and_terminal_code & backslash; + this->next_is_escaped = escape >> 63; + return { escaped, escape }; + } + + private: + static constexpr const uint64_t ODD_BITS = 0xAAAAAAAAAAAAAAAAULL; + + simdjson_really_inline uint64_t next_escaped_without_backslashes() noexcept { + uint64_t escaped = this->next_is_escaped; + this->next_is_escaped = 0; + return escaped; + } + + /** + * Returns a mask of the next escape characters (masking out escaped backslashes), along with + * any non-backslash escape codes. + * + * \n \\n \\\n \\\\n returns: + * \n \ \ \n \ \ + * 11 100 1011 10100 + * + * You are expected to mask out the first bit yourself if the previous block had a trailing + * escape. + * + * & the result with potential_escape to get just the escape characters. + * ^ the result with (potential_escape | first_is_escaped) to get escaped characters. + */ + static simdjson_really_inline uint64_t next_escape_and_terminal_code(uint64_t potential_escape) noexcept { + // If we were to just shift and mask out any odd bits, we'd actually get a *half* right answer: + // any even-aligned backslash runs would be correct! Odd-aligned backslash runs would be + // inverted (\\\ would be 010 instead of 101). + // + // ``` + // string: | ____\\\\_\\\\_____ | + // maybe_escaped | ODD | \ \ \ \ | + // even-aligned ^^^ ^^^^ odd-aligned + // ``` + // + // Taking that into account, our basic strategy is: + // + // 1. Use subtraction to produce a mask with 1's for even-aligned runs and 0's for + // odd-aligned runs. + // 2. XOR all odd bits, which masks out the odd bits in even-aligned runs, and brings IN the + // odd bits in odd-aligned runs. + // 3. & with backslash to clean up any stray bits. + // runs are set to 0, and then XORing with "odd": + // + // | | Mask (shows characters instead of 1's) | Instructions | + // |--------------------------------|----------------------------------------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | + // | | ` even odd even odd odd` | + // | maybe_escaped | ` n \\n \\n \\\_ \\\_ \\` X | 1 (potential_escape << 1) + // | maybe_escaped_and_odd | ` \n_ \\n _ \\\n_ _ \\\__ _\\\_ \\\` | 1 (maybe_escaped | odd) + // | even_series_codes_and_odd | ` n_\\\ _ n_ _\\\\ _ _ ` | 1 (maybe_escaped_and_odd - potential_escape) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 1 (^ odd) + // + + // Escaped characters are characters following an escape. + uint64_t maybe_escaped = potential_escape << 1; + + // To distinguish odd from even escape sequences, therefore, we turn on any *starting* + // escapes that are on an odd byte. (We actually bring in all odd bits, for speed.) + // - Odd runs of backslashes are 0000, and the code at the end ("n" in \n or \\n) is 1. + // - Odd runs of backslashes are 1111, and the code at the end ("n" in \n or \\n) is 0. + // - All other odd bytes are 1, and even bytes are 0. + uint64_t maybe_escaped_and_odd_bits = maybe_escaped | ODD_BITS; + uint64_t even_series_codes_and_odd_bits = maybe_escaped_and_odd_bits - potential_escape; + + // Now we flip all odd bytes back with xor. This: + // - Makes odd runs of backslashes go from 0000 to 1010 + // - Makes even runs of backslashes go from 1111 to 1010 + // - Sets actually-escaped codes to 1 (the n in \n and \\n: \n = 11, \\n = 100) + // - Resets all other bytes to 0 + return even_series_codes_and_odd_bits ^ ODD_BITS; + } + }; + + } // namespace stage1 + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_escape_scanner.h for haswell */ +/* including generic/stage1/json_string_scanner.h for haswell: #include */ +/* begin file generic/stage1/json_string_scanner.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace stage1 { + + struct json_string_block { + // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 + simdjson_really_inline json_string_block(uint64_t escaped, uint64_t quote, uint64_t in_string) : + _escaped(escaped), _quote(quote), _in_string(in_string) {} + + // Escaped characters (characters following an escape() character) + simdjson_really_inline uint64_t escaped() const { return _escaped; } + // Real (non-backslashed) quotes + simdjson_really_inline uint64_t quote() const { return _quote; } + // Only characters inside the string (not including the quotes) + simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } + // Tail of string (everything except the start quote) + simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; } + + // escaped characters (backslashed--does not include the hex characters after \u) + uint64_t _escaped; + // real quotes (non-escaped ones) + uint64_t _quote; + // string characters (includes start quote but not end quote) + uint64_t _in_string; + }; + + // Scans blocks for string characters, storing the state necessary to do so + class json_string_scanner { + public: + simdjson_really_inline json_string_block next(const simd::simd8x64& in); + // Returns either UNCLOSED_STRING or SUCCESS + simdjson_really_inline error_code finish(); + + private: + // Scans for escape characters + json_escape_scanner escape_scanner{}; + // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). + uint64_t prev_in_string = 0ULL; + }; + + // + // Return a mask of all string characters plus end quotes. + // + // prev_escaped is overflow saying whether the next character is escaped. + // prev_in_string is overflow saying whether we're still in a string. + // + // Backslash sequences outside of quotes will be detected in stage 2. + // + simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { + const uint64_t backslash = in.eq('\\'); + const uint64_t escaped = escape_scanner.next(backslash).escaped; + const uint64_t quote = in.eq('"') & ~escaped; + + // + // prefix_xor flips on bits inside the string (and flips off the end quote). + // + // Then we xor with prev_in_string: if we were in a string already, its effect is flipped + // (characters inside strings are outside, and characters outside strings are inside). + // + const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; + + // + // Check if we're still in a string at the end of the box so the next block will know + // + prev_in_string = uint64_t(static_cast(in_string) >> 63); + + // Use ^ to turn the beginning quote off, and the end quote on. + + // We are returning a function-local object so either we get a move constructor + // or we get copy elision. + return json_string_block(escaped, quote, in_string); + } + + simdjson_really_inline error_code json_string_scanner::finish() { + if (prev_in_string) { + return UNCLOSED_STRING; + } + return SUCCESS; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_string_scanner.h for haswell */ +/* including generic/stage1/utf8_lookup4_algorithm.h for haswell: #include */ +/* begin file generic/stage1/utf8_lookup4_algorithm.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { namespace { namespace utf8_validation { @@ -7153,14 +21738,6 @@ namespace simdjson { this->error |= this->prev_incomplete; } -#ifndef SIMDJSON_IF_CONSTEXPR -#if SIMDJSON_CPLUSPLUS17 -#define SIMDJSON_IF_CONSTEXPR if constexpr -#else -#define SIMDJSON_IF_CONSTEXPR if -#endif -#endif - simdjson_inline void check_next_input(const simd8x64& input) { if (simdjson_likely(is_ascii(input))) { this->error |= this->prev_incomplete; @@ -7175,17 +21752,17 @@ namespace simdjson { this->check_utf8_bytes(input.chunks[0], this->prev_input_block); } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - } + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 4) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - this->check_utf8_bytes(input.chunks[2], input.chunks[1]); - this->check_utf8_bytes(input.chunks[3], input.chunks[2]); - } - this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); - this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + this->check_utf8_bytes(input.chunks[2], input.chunks[1]); + this->check_utf8_bytes(input.chunks[3], input.chunks[2]); + } + this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); + this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; } } // do not forget to call check_eof! @@ -7196,272 +21773,25 @@ else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { }; // struct utf8_checker } // namespace utf8_validation - using utf8_validation::utf8_checker; - } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage1/utf8_lookup4_algorithm.h */ -// defining SIMDJSON_CUSTOM_BIT_INDEXER allows us to provide our own bit_indexer::write -#define SIMDJSON_CUSTOM_BIT_INDEXER -/* begin file src/generic/stage1/json_structural_indexer.h */ -// This file contains the common code every implementation uses in stage1 -// It is intended to be included multiple times and compiled multiple times -// We assume the file in which it is included already includes -// "simdjson/stage1.h" (this simplifies amalgation) -/* begin file src/generic/stage1/buf_block_reader.h */ +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H +/* end file generic/stage1/utf8_lookup4_algorithm.h for haswell */ +/* including generic/stage1/json_scanner.h for haswell: #include */ +/* begin file generic/stage1/json_scanner.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace icelake { - namespace { - - // Walks through a buffer in block-sized increments, loading the last part with spaces - template - struct buf_block_reader { - public: - simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); - simdjson_inline size_t block_index(); - simdjson_inline bool has_full_block() const; - simdjson_inline const uint8_t* full_block() const; - /** - * Get the last block, padded with spaces. - * - * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this - * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there - * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. - * - * @return the number of effective characters in the last block. - */ - simdjson_inline size_t get_remainder(uint8_t* dst) const; - simdjson_inline void advance(); - private: - const uint8_t* buf; - const size_t len; - const size_t lenminusstep; - size_t idx; - }; - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text_64(const uint8_t* text) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < sizeof(simd8x64); i++) { - buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text(const simd8x64& in) { - static char buf[sizeof(simd8x64) + 1]; - in.store(reinterpret_cast(buf)); - for (size_t i = 0; i < sizeof(simd8x64); i++) { - if (buf[i] < ' ') { buf[i] = '_'; } - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - simdjson_unused static char* format_mask(uint64_t mask) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < 64; i++) { - buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; - } - buf[64] = '\0'; - return buf; - } - - template - simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} - - template - simdjson_inline size_t buf_block_reader::block_index() { return idx; } - - template - simdjson_inline bool buf_block_reader::has_full_block() const { - return idx < lenminusstep; - } - - template - simdjson_inline const uint8_t* buf_block_reader::full_block() const { - return &buf[idx]; - } - - template - simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { - if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers - std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. - std::memcpy(dst, buf + idx, len - idx); - return len - idx; - } - - template - simdjson_inline void buf_block_reader::advance() { - idx += STEP_SIZE; - } - - } // unnamed namespace - } // namespace icelake -} // namespace simdjson -/* end file src/generic/stage1/buf_block_reader.h */ -/* begin file src/generic/stage1/json_string_scanner.h */ -namespace simdjson { - namespace icelake { - namespace { - namespace stage1 { - - struct json_string_block { - // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 - simdjson_inline json_string_block(uint64_t backslash, uint64_t escaped, uint64_t quote, uint64_t in_string) : - _backslash(backslash), _escaped(escaped), _quote(quote), _in_string(in_string) {} - - // Escaped characters (characters following an escape() character) - simdjson_inline uint64_t escaped() const { return _escaped; } - // Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \) - simdjson_inline uint64_t escape() const { return _backslash & ~_escaped; } - // Real (non-backslashed) quotes - simdjson_inline uint64_t quote() const { return _quote; } - // Start quotes of strings - simdjson_inline uint64_t string_start() const { return _quote & _in_string; } - // End quotes of strings - simdjson_inline uint64_t string_end() const { return _quote & ~_in_string; } - // Only characters inside the string (not including the quotes) - simdjson_inline uint64_t string_content() const { return _in_string & ~_quote; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } - // Tail of string (everything except the start quote) - simdjson_inline uint64_t string_tail() const { return _in_string ^ _quote; } - - // backslash characters - uint64_t _backslash; - // escaped characters (backslashed--does not include the hex characters after \u) - uint64_t _escaped; - // real quotes (non-backslashed ones) - uint64_t _quote; - // string characters (includes start quote but not end quote) - uint64_t _in_string; - }; - - // Scans blocks for string characters, storing the state necessary to do so - class json_string_scanner { - public: - simdjson_inline json_string_block next(const simd::simd8x64& in); - // Returns either UNCLOSED_STRING or SUCCESS - simdjson_inline error_code finish(); - - private: - // Intended to be defined by the implementation - simdjson_inline uint64_t find_escaped(uint64_t escape); - simdjson_inline uint64_t find_escaped_branchless(uint64_t escape); - - // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). - uint64_t prev_in_string = 0ULL; - // Whether the first character of the next iteration is escaped. - uint64_t prev_escaped = 0ULL; - }; - - // - // Finds escaped characters (characters following \). - // - // Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively). - // - // Does this by: - // - Shift the escape mask to get potentially escaped characters (characters after backslashes). - // - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not) - // - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not) - // - // To distinguish between escaped sequences starting on even/odd bits, it finds the start of all - // escape sequences, filters out the ones that start on even bits, and adds that to the mask of - // escape sequences. This causes the addition to clear out the sequences starting on odd bits (since - // the start bit causes a carry), and leaves even-bit sequences alone. - // - // Example: - // - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape - // odd_starts | x | x x x | escape & ~even_bits & ~follows_escape - // even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later - // invert_mask | | cxxx c xx c| even_seq << 1 - // follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit - // escaped | x | x x x x x x x x | - // desired | x | x x x x x x x x | - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // - simdjson_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) { - // If there was overflow, pretend the first character isn't a backslash - backslash &= ~prev_escaped; - uint64_t follows_escape = backslash << 1 | prev_escaped; - - // Get sequences starting on even bits by clearing out the odd series using + - const uint64_t even_bits = 0x5555555555555555ULL; - uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape; - uint64_t sequences_starting_on_even_bits; - prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits); - uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes. - - // Mask every other backslashed character as an escaped character - // Flip the mask for sequences that start on even bits, to correct them - return (even_bits ^ invert_mask) & follows_escape; - } - - // - // Return a mask of all string characters plus end quotes. - // - // prev_escaped is overflow saying whether the next character is escaped. - // prev_in_string is overflow saying whether we're still in a string. - // - // Backslash sequences outside of quotes will be detected in stage 2. - // - simdjson_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { - const uint64_t backslash = in.eq('\\'); - const uint64_t escaped = find_escaped(backslash); - const uint64_t quote = in.eq('"') & ~escaped; - - // - // prefix_xor flips on bits inside the string (and flips off the end quote). - // - // Then we xor with prev_in_string: if we were in a string already, its effect is flipped - // (characters inside strings are outside, and characters outside strings are inside). - // - const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; - - // - // Check if we're still in a string at the end of the box so the next block will know - // - // right shift of a signed value expected to be well-defined and standard - // compliant as of C++20, John Regher from Utah U. says this is fine code - // - prev_in_string = uint64_t(static_cast(in_string) >> 63); - - // Use ^ to turn the beginning quote off, and the end quote on. - - // We are returning a function-local object so either we get a move constructor - // or we get copy elision. - return json_string_block( - backslash, - escaped, - quote, - in_string - ); - } - - simdjson_inline error_code json_string_scanner::finish() { - if (prev_in_string) { - return UNCLOSED_STRING; - } - return SUCCESS; - } - - } // namespace stage1 - } // unnamed namespace - } // namespace icelake -} // namespace simdjson -/* end file src/generic/stage1/json_string_scanner.h */ -/* begin file src/generic/stage1/json_scanner.h */ -namespace simdjson { - namespace icelake { + namespace haswell { namespace { namespace stage1 { @@ -7615,17 +21945,139 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage1/json_scanner.h */ -/* begin file src/generic/stage1/json_minifier.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H +/* end file generic/stage1/json_scanner.h for haswell */ + +// All other declarations +/* including generic/stage1/find_next_document_index.h for haswell: #include */ +/* begin file generic/stage1/find_next_document_index.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace stage1 { + + /** + * This algorithm is used to quickly identify the last structural position that + * makes up a complete document. + * + * It does this by going backwards and finding the last *document boundary* (a + * place where one value follows another without a comma between them). If the + * last document (the characters after the boundary) has an equal number of + * start and end brackets, it is considered complete. + * + * Simply put, we iterate over the structural characters, starting from + * the end. We consider that we found the end of a JSON document when the + * first element of the pair is NOT one of these characters: '{' '[' ':' ',' + * and when the second element is NOT one of these characters: '}' ']' ':' ','. + * + * This simple comparison works most of the time, but it does not cover cases + * where the batch's structural indexes contain a perfect amount of documents. + * In such a case, we do not have access to the structural index which follows + * the last document, therefore, we do not have access to the second element in + * the pair, and that means we cannot identify the last document. To fix this + * issue, we keep a count of the open and closed curly/square braces we found + * while searching for the pair. When we find a pair AND the count of open and + * closed curly/square braces is the same, we know that we just passed a + * complete document, therefore the last json buffer location is the end of the + * batch. + */ + simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { + // Variant: do not count separately, just figure out depth + if (parser.n_structural_indexes == 0) { return 0; } + auto arr_cnt = 0; + auto obj_cnt = 0; + for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { + auto idxb = parser.structural_indexes[i]; + switch (parser.buf[idxb]) { + case ':': + case ',': + continue; + case '}': + obj_cnt--; + continue; + case ']': + arr_cnt--; + continue; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + auto idxa = parser.structural_indexes[i - 1]; + switch (parser.buf[idxa]) { + case '{': + case '[': + case ':': + case ',': + continue; + } + // Last document is complete, so the next document will appear after! + if (!arr_cnt && !obj_cnt) { + return parser.n_structural_indexes; + } + // Last document is incomplete; mark the document at i + 1 as the next one + return i; + } + // If we made it to the end, we want to finish counting to see if we have a full document. + switch (parser.buf[parser.structural_indexes[0]]) { + case '}': + obj_cnt--; + break; + case ']': + arr_cnt--; + break; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + if (!arr_cnt && !obj_cnt) { + // We have a complete document. + return parser.n_structural_indexes; + } + return 0; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H +/* end file generic/stage1/find_next_document_index.h for haswell */ +/* including generic/stage1/json_minifier.h for haswell: #include */ +/* begin file generic/stage1/json_minifier.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + // This file contains the common code every implementation uses in stage1 // It is intended to be included multiple times and compiled multiple times // We assume the file in which it is included already includes // "simdjson/stage1.h" (this simplifies amalgation) namespace simdjson { - namespace icelake { + namespace haswell { namespace { namespace stage1 { @@ -7710,107 +22162,33 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage1/json_minifier.h */ -/* begin file src/generic/stage1/find_next_document_index.h */ -namespace simdjson { - namespace icelake { - namespace { - /** - * This algorithm is used to quickly identify the last structural position that - * makes up a complete document. - * - * It does this by going backwards and finding the last *document boundary* (a - * place where one value follows another without a comma between them). If the - * last document (the characters after the boundary) has an equal number of - * start and end brackets, it is considered complete. - * - * Simply put, we iterate over the structural characters, starting from - * the end. We consider that we found the end of a JSON document when the - * first element of the pair is NOT one of these characters: '{' '[' ':' ',' - * and when the second element is NOT one of these characters: '}' ']' ':' ','. - * - * This simple comparison works most of the time, but it does not cover cases - * where the batch's structural indexes contain a perfect amount of documents. - * In such a case, we do not have access to the structural index which follows - * the last document, therefore, we do not have access to the second element in - * the pair, and that means we cannot identify the last document. To fix this - * issue, we keep a count of the open and closed curly/square braces we found - * while searching for the pair. When we find a pair AND the count of open and - * closed curly/square braces is the same, we know that we just passed a - * complete document, therefore the last json buffer location is the end of the - * batch. - */ - simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { - // Variant: do not count separately, just figure out depth - if (parser.n_structural_indexes == 0) { return 0; } - auto arr_cnt = 0; - auto obj_cnt = 0; - for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { - auto idxb = parser.structural_indexes[i]; - switch (parser.buf[idxb]) { - case ':': - case ',': - continue; - case '}': - obj_cnt--; - continue; - case ']': - arr_cnt--; - continue; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - auto idxa = parser.structural_indexes[i - 1]; - switch (parser.buf[idxa]) { - case '{': - case '[': - case ':': - case ',': - continue; - } - // Last document is complete, so the next document will appear after! - if (!arr_cnt && !obj_cnt) { - return parser.n_structural_indexes; - } - // Last document is incomplete; mark the document at i + 1 as the next one - return i; - } - // If we made it to the end, we want to finish counting to see if we have a full document. - switch (parser.buf[parser.structural_indexes[0]]) { - case '}': - obj_cnt--; - break; - case ']': - arr_cnt--; - break; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - if (!arr_cnt && !obj_cnt) { - // We have a complete document. - return parser.n_structural_indexes; - } - return 0; - } +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H +/* end file generic/stage1/json_minifier.h for haswell */ +/* including generic/stage1/json_structural_indexer.h for haswell: #include */ +/* begin file generic/stage1/json_structural_indexer.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H - } // unnamed namespace - } // namespace icelake -} // namespace simdjson -/* end file src/generic/stage1/find_next_document_index.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses in stage1 +// It is intended to be included multiple times and compiled multiple times +// We assume the file in which it is included already includes +// "simdjson/stage1.h" (this simplifies amalgation) namespace simdjson { - namespace icelake { + namespace haswell { namespace { namespace stage1 { @@ -7820,15 +22198,67 @@ namespace simdjson { simdjson_inline bit_indexer(uint32_t* index_buf) : tail(index_buf) {} +#if SIMDJSON_PREFER_REVERSE_BITS + /** + * ARM lacks a fast trailing zero instruction, but it has a fast + * bit reversal instruction and a fast leading zero instruction. + * Thus it may be profitable to reverse the bits (once) and then + * to rely on a sequence of instructions that call the leading + * zero instruction. + * + * Performance notes: + * The chosen routine is not optimal in terms of data dependency + * since zero_leading_bit might require two instructions. However, + * it tends to minimize the total number of instructions which is + * beneficial. + */ + simdjson_inline void write_index(uint32_t idx, uint64_t& rev_bits, int i) { + int lz = leading_zeroes(rev_bits); + this->tail[i] = static_cast(idx) + lz; + rev_bits = zero_leading_bit(rev_bits, lz); + } +#else + /** + * Under recent x64 systems, we often have both a fast trailing zero + * instruction and a fast 'clear-lower-bit' instruction so the following + * algorithm can be competitive. + */ + + simdjson_inline void write_index(uint32_t idx, uint64_t& bits, int i) { + this->tail[i] = idx + trailing_zeroes(bits); + bits = clear_lowest_bit(bits); + } +#endif // SIMDJSON_PREFER_REVERSE_BITS + + template + simdjson_inline int write_indexes(uint32_t idx, uint64_t& bits) { + write_index(idx, bits, START); + SIMDJSON_IF_CONSTEXPR(N > 1) { + write_indexes<(N - 1 > 0 ? START + 1 : START), (N - 1 >= 0 ? N - 1 : 1)>(idx, bits); + } + return START + N; + } + + template + simdjson_inline int write_indexes_stepped(uint32_t idx, uint64_t& bits, int cnt) { + write_indexes(idx, bits); + SIMDJSON_IF_CONSTEXPR((START + STEP) < END) { + if (simdjson_unlikely((START + STEP) < cnt)) { + write_indexes_stepped<(START + STEP < END ? START + STEP : END), END, STEP>(idx, bits, cnt); + } + } + return ((END - START) % STEP) == 0 ? END : (END - START) - ((END - START) % STEP) + STEP; + } + // flatten out values in 'bits' assuming that they are are to have values of idx // plus their position in the bitvector, and store these indexes at // base_ptr[base] incrementing base as we go // will potentially store extra values beyond end of valid bits, so base_ptr // needs to be large enough to handle this // - // If the kernel sets SIMDJSON_CUSTOM_BIT_INDEXER, then it will provide its own - // version of the code. -#ifdef SIMDJSON_CUSTOM_BIT_INDEXER + // If the kernel sets SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER, then it + // will provide its own version of the code. +#ifdef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER simdjson_inline void write(uint32_t idx, uint64_t bits); #else simdjson_inline void write(uint32_t idx, uint64_t bits) { @@ -7837,93 +22267,31 @@ namespace simdjson { // it helps tremendously. if (bits == 0) return; -#if SIMDJSON_PREFER_REVERSE_BITS - /** - * ARM lacks a fast trailing zero instruction, but it has a fast - * bit reversal instruction and a fast leading zero instruction. - * Thus it may be profitable to reverse the bits (once) and then - * to rely on a sequence of instructions that call the leading - * zero instruction. - * - * Performance notes: - * The chosen routine is not optimal in terms of data dependency - * since zero_leading_bit might require two instructions. However, - * it tends to minimize the total number of instructions which is - * beneficial. - */ - uint64_t rev_bits = reverse_bits(bits); int cnt = static_cast(count_ones(bits)); - int i = 0; - // Do the first 8 all together - for (; i < 8; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - i = 8; - for (; i < 16; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } +#if SIMDJSON_PREFER_REVERSE_BITS + bits = reverse_bits(bits); +#endif +#ifdef SIMDJSON_STRUCTURAL_INDEXER_STEP + static constexpr const int STEP = SIMDJSON_STRUCTURAL_INDEXER_STEP; +#else + static constexpr const int STEP = 4; +#endif + static constexpr const int STEP_UNTIL = 24; - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - i = 16; - while (rev_bits != 0) { - int lz = leading_zeroes(rev_bits); - this->tail[i++] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); + write_indexes_stepped<0, STEP_UNTIL, STEP>(idx, bits, cnt); + SIMDJSON_IF_CONSTEXPR(STEP_UNTIL < 64) { + if (simdjson_unlikely(STEP_UNTIL < cnt)) { + for (int i = STEP_UNTIL; i < cnt; i++) { + write_index(idx, bits, i); } } } - this->tail += cnt; -#else // SIMDJSON_PREFER_REVERSE_BITS - /** - * Under recent x64 systems, we often have both a fast trailing zero - * instruction and a fast 'clear-lower-bit' instruction so the following - * algorithm can be competitive. - */ - - int cnt = static_cast(count_ones(bits)); - // Do the first 8 all together - for (int i = 0; i < 8; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - for (int i = 8; i < 16; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - int i = 16; - do { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - i++; - } while (i < cnt); - } - } this->tail += cnt; -#endif } -#endif // SIMDJSON_CUSTOM_BIT_INDEXER +#endif // SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER }; @@ -8154,65 +22522,27 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage1/json_structural_indexer.h */ -// We must not forget to undefine it now: -#undef SIMDJSON_CUSTOM_BIT_INDEXER -/** - * We provide a custom version of bit_indexer::write using - * naked intrinsics. - * TODO: make this code more elegant. - */ - // Under GCC 12, the intrinsic _mm512_extracti32x4_epi32 may generate 'maybe uninitialized'. - // as a workaround, we disable warnings within the following function. -SIMDJSON_PUSH_DISABLE_ALL_WARNINGS +// Clear CUSTOM_BIT_INDEXER so other implementations can set it if they need to. +#undef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H +/* end file generic/stage1/json_structural_indexer.h for haswell */ +/* including generic/stage1/utf8_validator.h for haswell: #include */ +/* begin file generic/stage1/utf8_validator.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace icelake { - namespace { - namespace stage1 { - simdjson_inline void bit_indexer::write(uint32_t idx, uint64_t bits) { - // In some instances, the next branch is expensive because it is mispredicted. - // Unfortunately, in other cases, - // it helps tremendously. - if (bits == 0) { return; } - - const __m512i indexes = _mm512_maskz_compress_epi8(bits, _mm512_set_epi32( - 0x3f3e3d3c, 0x3b3a3938, 0x37363534, 0x33323130, - 0x2f2e2d2c, 0x2b2a2928, 0x27262524, 0x23222120, - 0x1f1e1d1c, 0x1b1a1918, 0x17161514, 0x13121110, - 0x0f0e0d0c, 0x0b0a0908, 0x07060504, 0x03020100 - )); - const __m512i start_index = _mm512_set1_epi32(idx); - - const auto count = count_ones(bits); - __m512i t0 = _mm512_cvtepu8_epi32(_mm512_castsi512_si128(indexes)); - _mm512_storeu_si512(this->tail, _mm512_add_epi32(t0, start_index)); - - if (count > 16) { - const __m512i t1 = _mm512_cvtepu8_epi32(_mm512_extracti32x4_epi32(indexes, 1)); - _mm512_storeu_si512(this->tail + 16, _mm512_add_epi32(t1, start_index)); - if (count > 32) { - const __m512i t2 = _mm512_cvtepu8_epi32(_mm512_extracti32x4_epi32(indexes, 2)); - _mm512_storeu_si512(this->tail + 32, _mm512_add_epi32(t2, start_index)); - if (count > 48) { - const __m512i t3 = _mm512_cvtepu8_epi32(_mm512_extracti32x4_epi32(indexes, 3)); - _mm512_storeu_si512(this->tail + 48, _mm512_add_epi32(t3, start_index)); - } - } - } - this->tail += count; - } - } - } - } -} -SIMDJSON_POP_DISABLE_WARNINGS - -/* begin file src/generic/stage1/utf8_validator.h */ -namespace simdjson { - namespace icelake { + namespace haswell { namespace { namespace stage1 { @@ -8243,267 +22573,177 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage1/utf8_validator.h */ -// -// Stage 2 -// -/* begin file src/generic/stage2/stringparsing.h */ -// This file contains the common code every implementation uses -// It is intended to be included multiple times and compiled multiple times +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H +/* end file generic/stage1/utf8_validator.h for haswell */ +/* end file generic/stage1/amalgamated.h for haswell */ +/* including generic/stage2/amalgamated.h for haswell: #include */ +/* begin file generic/stage2/amalgamated.h for haswell */ +// Stuff other things depend on +/* including generic/stage2/base.h for haswell: #include */ +/* begin file generic/stage2/base.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace icelake { + namespace haswell { namespace { - /// @private - namespace stringparsing { + namespace stage2 { - // begin copypasta - // These chars yield themselves: " \ / - // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab - // u not handled in this table as it's complex - static const uint8_t escape_map[256] = { - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + class json_iterator; + class structural_iterator; + struct tape_builder; + struct tape_writer; - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. - 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. - 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - }; - - // handle a unicode codepoint - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, - uint8_t** dst_ptr, bool allow_replacement) { - // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) - constexpr uint32_t substitution_code_point = 0xfffd; - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - - // We have already checked that the high surrogate is valid and - // (code_point - 0xd800) < 1024. - // - // Check that code_point_2 is in the range 0xdc00..0xdfff - // and that code_point_2 was parsed from valid hex. - uint32_t low_bit = code_point_2 - 0xdc00; - if (low_bit >> 10) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - - } - } - else if (code_point >= 0xdc00 && code_point <= 0xdfff) { - // If we encounter a low surrogate (not preceded by a high surrogate) - // then we have an error. - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - // handle a unicode codepoint using the wobbly convention - // https://simonsapin.github.io/wtf-8/ - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, - uint8_t** dst_ptr) { - // It is not ideal that this function is nearly identical to handle_unicode_codepoint. - // - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - uint32_t low_bit = code_point_2 - 0xdc00; - if ((low_bit >> 10) == 0) { - code_point = - (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - } - } - - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - /** - * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There - * must be an unescaped quote terminating the string. It returns the final output - * position as pointer. In case of error (e.g., the string has bad escaped codes), - * then null_nullptrptr is returned. It is assumed that the output buffer is large - * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + - * SIMDJSON_PADDING bytes. - */ - simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { - // It is not ideal that this function is nearly identical to parse_string. - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint_wobbly(&src, &dst)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - } // namespace stringparsing + } // namespace stage2 } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage2/stringparsing.h */ -/* begin file src/generic/stage2/tape_builder.h */ -/* begin file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_BASE_H +/* end file generic/stage2/base.h for haswell */ +/* including generic/stage2/tape_writer.h for haswell: #include */ +/* begin file generic/stage2/tape_writer.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace haswell { + namespace { + namespace stage2 { + + struct tape_writer { + /** The next place to write to tape */ + uint64_t* next_tape_loc; + + /** Write a signed 64-bit value to tape. */ + simdjson_inline void append_s64(int64_t value) noexcept; + + /** Write an unsigned 64-bit value to tape. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + + /** Write a double value to tape. */ + simdjson_inline void append_double(double value) noexcept; + + /** + * Append a tape entry (an 8-bit type,and 56 bits worth of value). + */ + simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; + + /** + * Skip the current tape entry without writing. + * + * Used to skip the start of the container, since we'll come back later to fill it in when the + * container ends. + */ + simdjson_inline void skip() noexcept; + + /** + * Skip the number of tape entries necessary to write a large u64 or i64. + */ + simdjson_inline void skip_large_integer() noexcept; + + /** + * Skip the number of tape entries necessary to write a double. + */ + simdjson_inline void skip_double() noexcept; + + /** + * Write a value to a known location on tape. + * + * Used to go back and write out the start of a container after the container ends. + */ + simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; + + private: + /** + * Append both the tape entry, and a supplementary value following it. Used for types that need + * all 64 bits, such as double and uint64_t. + */ + template + simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; + }; // struct tape_writer + + simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { + append2(0, value, internal::tape_type::INT64); + } + + simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { + append(0, internal::tape_type::UINT64); + *next_tape_loc = value; + next_tape_loc++; + } + + /** Write a double value to tape. */ + simdjson_inline void tape_writer::append_double(double value) noexcept { + append2(0, value, internal::tape_type::DOUBLE); + } + + simdjson_inline void tape_writer::skip() noexcept { + next_tape_loc++; + } + + simdjson_inline void tape_writer::skip_large_integer() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::skip_double() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { + *next_tape_loc = val | ((uint64_t(char(t))) << 56); + next_tape_loc++; + } + + template + simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { + append(val, t); + static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); + memcpy(next_tape_loc, &val2, sizeof(val2)); + next_tape_loc++; + } + + simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { + tape_loc = val | ((uint64_t(char(t))) << 56); + } + + } // namespace stage2 + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H +/* end file generic/stage2/tape_writer.h for haswell */ +/* including generic/stage2/logger.h for haswell: #include */ +/* begin file generic/stage2/logger.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + + // This is for an internal-only stage 2 specific logger. // Set LOG_ENABLED = true to log what stage 2 is doing! namespace simdjson { - namespace icelake { + namespace haswell { namespace { namespace logger { @@ -8588,12 +22828,26 @@ namespace simdjson { } // namespace logger } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H +/* end file generic/stage2/logger.h for haswell */ + +// All other declarations +/* including generic/stage2/json_iterator.h for haswell: #include */ +/* begin file generic/stage2/json_iterator.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace icelake { + namespace haswell { namespace { namespace stage2 { @@ -8888,15 +23142,18 @@ namespace simdjson { } template simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { + // Use the fact that most scalars are going to be either strings or numbers. + if (*value == '"') { + return visitor.visit_string(*this, value); + } + else if (((*value - '0') < 10) || (*value == '-')) { + return visitor.visit_number(*this, value); + } + // true, false, null are uncommon. switch (*value) { - case '"': return visitor.visit_string(*this, value); case 't': return visitor.visit_true_atom(*this, value); case 'f': return visitor.visit_false_atom(*this, value); case 'n': return visitor.visit_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_number(*this, value); default: log_error("Non-value found when value was expected!"); return TAPE_ERROR; @@ -8905,119 +23162,351 @@ namespace simdjson { } // namespace stage2 } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H +/* end file generic/stage2/json_iterator.h for haswell */ +/* including generic/stage2/stringparsing.h for haswell: #include */ +/* begin file generic/stage2/stringparsing.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses +// It is intended to be included multiple times and compiled multiple times + namespace simdjson { - namespace icelake { + namespace haswell { + namespace { + /// @private + namespace stringparsing { + + // begin copypasta + // These chars yield themselves: " \ / + // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab + // u not handled in this table as it's complex + static const uint8_t escape_map[256] = { + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. + 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. + 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + }; + + // handle a unicode codepoint + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, + uint8_t** dst_ptr, bool allow_replacement) { + // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) + constexpr uint32_t substitution_code_point = 0xfffd; + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + + // We have already checked that the high surrogate is valid and + // (code_point - 0xd800) < 1024. + // + // Check that code_point_2 is in the range 0xdc00..0xdfff + // and that code_point_2 was parsed from valid hex. + uint32_t low_bit = code_point_2 - 0xdc00; + if (low_bit >> 10) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + + } + } + else if (code_point >= 0xdc00 && code_point <= 0xdfff) { + // If we encounter a low surrogate (not preceded by a high surrogate) + // then we have an error. + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + // handle a unicode codepoint using the wobbly convention + // https://simonsapin.github.io/wtf-8/ + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, + uint8_t** dst_ptr) { + // It is not ideal that this function is nearly identical to handle_unicode_codepoint. + // + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + uint32_t low_bit = code_point_2 - 0xdc00; + if ((low_bit >> 10) == 0) { + code_point = + (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + } + } + + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + /** + * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + */ + simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { + // It is not ideal that this function is nearly identical to parse_string. + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint_wobbly(&src, &dst)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + } // namespace stringparsing + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H +/* end file generic/stage2/stringparsing.h for haswell */ +/* including generic/stage2/structural_iterator.h for haswell: #include */ +/* begin file generic/stage2/structural_iterator.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { namespace { namespace stage2 { - struct tape_writer { - /** The next place to write to tape */ - uint64_t* next_tape_loc; + class structural_iterator { + public: + const uint8_t* const buf; + uint32_t* next_structural; + dom_parser_implementation& dom_parser; - /** Write a signed 64-bit value to tape. */ - simdjson_inline void append_s64(int64_t value) noexcept; + // Start a structural + simdjson_inline structural_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) + : buf{ _dom_parser.buf }, + next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, + dom_parser{ _dom_parser } { + } + // Get the buffer position of the current structural character + simdjson_inline const uint8_t* current() { + return &buf[*(next_structural - 1)]; + } + // Get the current structural character + simdjson_inline char current_char() { + return buf[*(next_structural - 1)]; + } + // Get the next structural character without advancing + simdjson_inline char peek_next_char() { + return buf[*next_structural]; + } + simdjson_inline const uint8_t* peek() { + return &buf[*next_structural]; + } + simdjson_inline const uint8_t* advance() { + return &buf[*(next_structural++)]; + } + simdjson_inline char advance_char() { + return buf[*(next_structural++)]; + } + simdjson_inline size_t remaining_len() { + return dom_parser.len - *(next_structural - 1); + } - /** Write an unsigned 64-bit value to tape. */ - simdjson_inline void append_u64(uint64_t value) noexcept; - - /** Write a double value to tape. */ - simdjson_inline void append_double(double value) noexcept; - - /** - * Append a tape entry (an 8-bit type,and 56 bits worth of value). - */ - simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; - - /** - * Skip the current tape entry without writing. - * - * Used to skip the start of the container, since we'll come back later to fill it in when the - * container ends. - */ - simdjson_inline void skip() noexcept; - - /** - * Skip the number of tape entries necessary to write a large u64 or i64. - */ - simdjson_inline void skip_large_integer() noexcept; - - /** - * Skip the number of tape entries necessary to write a double. - */ - simdjson_inline void skip_double() noexcept; - - /** - * Write a value to a known location on tape. - * - * Used to go back and write out the start of a container after the container ends. - */ - simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; - - private: - /** - * Append both the tape entry, and a supplementary value following it. Used for types that need - * all 64 bits, such as double and uint64_t. - */ - template - simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; - }; // struct number_writer - - simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { - append2(0, value, internal::tape_type::INT64); - } - - simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { - append(0, internal::tape_type::UINT64); - *next_tape_loc = value; - next_tape_loc++; - } - - /** Write a double value to tape. */ - simdjson_inline void tape_writer::append_double(double value) noexcept { - append2(0, value, internal::tape_type::DOUBLE); - } - - simdjson_inline void tape_writer::skip() noexcept { - next_tape_loc++; - } - - simdjson_inline void tape_writer::skip_large_integer() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::skip_double() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { - *next_tape_loc = val | ((uint64_t(char(t))) << 56); - next_tape_loc++; - } - - template - simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { - append(val, t); - static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); - memcpy(next_tape_loc, &val2, sizeof(val2)); - next_tape_loc++; - } - - simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { - tape_loc = val | ((uint64_t(char(t))) << 56); - } + simdjson_inline bool at_end() { + return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; + } + simdjson_inline bool at_beginning() { + return next_structural == dom_parser.structural_indexes.get(); + } + }; } // namespace stage2 } // unnamed namespace - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* end file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H +/* end file generic/stage2/structural_iterator.h for haswell */ +/* including generic/stage2/tape_builder.h for haswell: #include */ +/* begin file generic/stage2/tape_builder.h for haswell */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace icelake { + namespace haswell { namespace { namespace stage2 { @@ -9096,7 +23585,7 @@ namespace simdjson { simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; simdjson_inline void on_end_string(uint8_t* dst) noexcept; - }; // class tape_builder + }; // struct tape_builder template simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( @@ -9294,77 +23783,16 @@ namespace simdjson { } // namespace stage2 } // unnamed namespace - } // namespace icelake -} // namespace simdjson -/* end file src/generic/stage2/tape_builder.h */ - -// -// Implementation-specific overrides -// -namespace simdjson { - namespace icelake { - namespace { - namespace stage1 { - - simdjson_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) { - if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; } - return find_escaped_branchless(backslash); - } - - } // namespace stage1 - } // unnamed namespace - - simdjson_warn_unused error_code implementation::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept { - return icelake::stage1::json_minifier::minify<128>(buf, len, dst, dst_len); - } - - simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t* _buf, size_t _len, stage1_mode streaming) noexcept { - this->buf = _buf; - this->len = _len; - return icelake::stage1::json_structural_indexer::index<128>(_buf, _len, *this, streaming); - } - - simdjson_warn_unused bool implementation::validate_utf8(const char* buf, size_t len) const noexcept { - return icelake::stage1::generic_validate_utf8(buf, len); - } - - simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document& _doc) noexcept { - return stage2::tape_builder::parse_document(*this, _doc); - } - - simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document& _doc) noexcept { - return stage2::tape_builder::parse_document(*this, _doc); - } - - simdjson_warn_unused uint8_t* dom_parser_implementation::parse_string(const uint8_t* src, uint8_t* dst, bool replacement_char) const noexcept { - return icelake::stringparsing::parse_string(src, dst, replacement_char); - } - - simdjson_warn_unused uint8_t* dom_parser_implementation::parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept { - return icelake::stringparsing::parse_wobbly_string(src, dst); - } - - simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t* _buf, size_t _len, dom::document& _doc) noexcept { - auto error = stage1(_buf, _len, stage1_mode::regular); - if (error) { return error; } - return stage2(_doc); - } - - } // namespace icelake + } // namespace haswell } // namespace simdjson -/* begin file include/simdjson/icelake/end.h */ -SIMDJSON_UNTARGET_ICELAKE -/* end file include/simdjson/icelake/end.h */ -/* end file src/icelake/dom_parser_implementation.cpp */ -#endif -#if SIMDJSON_IMPLEMENTATION_HASWELL -/* begin file src/haswell/implementation.cpp */ -/* begin file include/simdjson/haswell/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "haswell" -// #define SIMDJSON_IMPLEMENTATION haswell -SIMDJSON_TARGET_HASWELL -/* end file include/simdjson/haswell/begin.h */ +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H +/* end file generic/stage2/tape_builder.h for haswell */ +/* end file generic/stage2/amalgamated.h for haswell */ + +// +// Stage 1 +// namespace simdjson { namespace haswell { @@ -9383,48 +23811,10 @@ namespace simdjson { return SUCCESS; } - } // namespace haswell -} // namespace simdjson - -/* begin file include/simdjson/haswell/end.h */ -SIMDJSON_UNTARGET_HASWELL -/* end file include/simdjson/haswell/end.h */ - -/* end file src/haswell/implementation.cpp */ -/* begin file src/haswell/dom_parser_implementation.cpp */ -/* begin file include/simdjson/haswell/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "haswell" -// #define SIMDJSON_IMPLEMENTATION haswell -SIMDJSON_TARGET_HASWELL -/* end file include/simdjson/haswell/begin.h */ - -// -// Stage 1 -// - -namespace simdjson { - namespace haswell { namespace { using namespace simd; - struct json_character_block { - static simdjson_inline json_character_block classify(const simd::simd8x64& in); - // ASCII white-space ('\r','\n','\t',' ') - simdjson_inline uint64_t whitespace() const noexcept; - // non-quote structural characters (comma, colon, braces, brackets) - simdjson_inline uint64_t op() const noexcept; - // neither a structural character nor a white-space, so letters, numbers and quotes - simdjson_inline uint64_t scalar() const noexcept; - - uint64_t _whitespace; // ASCII white-space ('\r','\n','\t',' ') - uint64_t _op; // structural characters (comma, colon, braces, brackets but not quotes) - }; - - simdjson_inline uint64_t json_character_block::whitespace() const noexcept { return _whitespace; } - simdjson_inline uint64_t json_character_block::op() const noexcept { return _op; } - simdjson_inline uint64_t json_character_block::scalar() const noexcept { return ~(op() | whitespace()); } - // This identifies structural characters (comma, colon, braces, brackets), // and ASCII white-space ('\r','\n','\t',' '). simdjson_inline json_character_block json_character_block::classify(const simd::simd8x64& in) { @@ -9503,9 +23893,3875 @@ namespace simdjson { } // namespace haswell } // namespace simdjson -/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */ +// +// Stage 2 +// + +// +// Implementation-specific overrides +// namespace simdjson { namespace haswell { + + simdjson_warn_unused error_code implementation::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept { + return haswell::stage1::json_minifier::minify<128>(buf, len, dst, dst_len); + } + + simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t* _buf, size_t _len, stage1_mode streaming) noexcept { + this->buf = _buf; + this->len = _len; + return haswell::stage1::json_structural_indexer::index<128>(_buf, _len, *this, streaming); + } + + simdjson_warn_unused bool implementation::validate_utf8(const char* buf, size_t len) const noexcept { + return haswell::stage1::generic_validate_utf8(buf, len); + } + + simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document& _doc) noexcept { + return stage2::tape_builder::parse_document(*this, _doc); + } + + simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document& _doc) noexcept { + return stage2::tape_builder::parse_document(*this, _doc); + } + + simdjson_warn_unused uint8_t* dom_parser_implementation::parse_string(const uint8_t* src, uint8_t* dst, bool replacement_char) const noexcept { + return haswell::stringparsing::parse_string(src, dst, replacement_char); + } + + simdjson_warn_unused uint8_t* dom_parser_implementation::parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept { + return haswell::stringparsing::parse_wobbly_string(src, dst); + } + + simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t* _buf, size_t _len, dom::document& _doc) noexcept { + auto error = stage1(_buf, _len, stage1_mode::regular); + if (error) { return error; } + return stage2(_doc); + } + + } // namespace haswell +} // namespace simdjson + +/* including simdjson/haswell/end.h: #include */ +/* begin file simdjson/haswell/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "haswell" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/haswell/end.h */ + +#endif // SIMDJSON_SRC_HASWELL_CPP +/* end file haswell.cpp */ +#endif +#if SIMDJSON_IMPLEMENTATION_ICELAKE +/* including icelake.cpp: #include */ +/* begin file icelake.cpp */ +#ifndef SIMDJSON_SRC_ICELAKE_CPP +#define SIMDJSON_SRC_ICELAKE_CPP + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* including simdjson/icelake.h: #include */ +/* begin file simdjson/icelake.h */ +#ifndef SIMDJSON_ICELAKE_H +#define SIMDJSON_ICELAKE_H + +/* including simdjson/icelake/begin.h: #include "simdjson/icelake/begin.h" */ +/* begin file simdjson/icelake/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "icelake" */ +#define SIMDJSON_IMPLEMENTATION icelake +/* including simdjson/icelake/base.h: #include "simdjson/icelake/base.h" */ +/* begin file simdjson/icelake/base.h */ +#ifndef SIMDJSON_ICELAKE_BASE_H +#define SIMDJSON_ICELAKE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE +namespace simdjson { + /** + * Implementation for Icelake (Intel AVX512). + */ + namespace icelake { + + class implementation; + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BASE_H +/* end file simdjson/icelake/base.h */ +/* including simdjson/icelake/intrinsics.h: #include "simdjson/icelake/intrinsics.h" */ +/* begin file simdjson/icelake/intrinsics.h */ +#ifndef SIMDJSON_ICELAKE_INTRINSICS_H +#define SIMDJSON_ICELAKE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + * e.g., if __AVX2__ is set... in turn, we normally set these + * macros by compiling against the corresponding architecture + * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole + * software with these advanced instructions. In simdjson, we + * want to compile the whole program for a generic target, + * and only target our specific kernels. As a workaround, + * we directly include the needed headers. These headers would + * normally guard against such usage, but we carefully included + * (or ) before, so the headers + * are fooled. + */ +#include // for _blsr_u64 +#include // for __lzcnt64 +#include // for most things (AVX2, AVX512, _popcnt64) +#include +#include +#include +#include +#include // for _mm_clmulepi64_si128 + // Important: we need the AVX-512 headers: +#include +#include +#include +#include +#include +#include +#include +// unfortunately, we may not get _blsr_u64, but, thankfully, clang +// has it as a macro. +#ifndef _blsr_u64 +// we roll our own +#define _blsr_u64(n) ((n - 1) & n) +#endif // _blsr_u64 +#endif // SIMDJSON_CLANG_VISUAL_STUDIO + +static_assert(sizeof(__m512i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for icelake"); + +#endif // SIMDJSON_ICELAKE_INTRINSICS_H +/* end file simdjson/icelake/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_TARGET_REGION("avx512f,avx512dq,avx512cd,avx512bw,avx512vbmi,avx512vbmi2,avx512vl,avx2,bmi,pclmul,lzcnt,popcnt") +#endif + +/* including simdjson/icelake/bitmanipulation.h: #include "simdjson/icelake/bitmanipulation.h" */ +/* begin file simdjson/icelake/bitmanipulation.h */ +#ifndef SIMDJSON_ICELAKE_BITMANIPULATION_H +#define SIMDJSON_ICELAKE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return (int)_tzcnt_u64(input_num); +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + //////// + // You might expect the next line to be equivalent to + // return (int)_tzcnt_u64(input_num); + // but the generated code differs and might be less efficient? + //////// + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return _blsr_u64(input_num); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { + return int(_lzcnt_u64(input_num)); + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMANIPULATION_H +/* end file simdjson/icelake/bitmanipulation.h */ +/* including simdjson/icelake/bitmask.h: #include "simdjson/icelake/bitmask.h" */ +/* begin file simdjson/icelake/bitmask.h */ +#ifndef SIMDJSON_ICELAKE_BITMASK_H +#define SIMDJSON_ICELAKE_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processor supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMASK_H +/* end file simdjson/icelake/bitmask.h */ +/* including simdjson/icelake/simd.h: #include "simdjson/icelake/simd.h" */ +/* begin file simdjson/icelake/simd.h */ +#ifndef SIMDJSON_ICELAKE_SIMD_H +#define SIMDJSON_ICELAKE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if defined(__GNUC__) && !defined(__clang__) +#if __GNUC__ == 8 +#define SIMDJSON_GCC8 1 +#endif // __GNUC__ == 8 +#endif // defined(__GNUC__) && !defined(__clang__) + +#if SIMDJSON_GCC8 +/** + * GCC 8 fails to provide _mm512_set_epi8. We roll our own. + */ +inline __m512i _mm512_set_epi8(uint8_t a0, uint8_t a1, uint8_t a2, uint8_t a3, uint8_t a4, uint8_t a5, uint8_t a6, uint8_t a7, uint8_t a8, uint8_t a9, uint8_t a10, uint8_t a11, uint8_t a12, uint8_t a13, uint8_t a14, uint8_t a15, uint8_t a16, uint8_t a17, uint8_t a18, uint8_t a19, uint8_t a20, uint8_t a21, uint8_t a22, uint8_t a23, uint8_t a24, uint8_t a25, uint8_t a26, uint8_t a27, uint8_t a28, uint8_t a29, uint8_t a30, uint8_t a31, uint8_t a32, uint8_t a33, uint8_t a34, uint8_t a35, uint8_t a36, uint8_t a37, uint8_t a38, uint8_t a39, uint8_t a40, uint8_t a41, uint8_t a42, uint8_t a43, uint8_t a44, uint8_t a45, uint8_t a46, uint8_t a47, uint8_t a48, uint8_t a49, uint8_t a50, uint8_t a51, uint8_t a52, uint8_t a53, uint8_t a54, uint8_t a55, uint8_t a56, uint8_t a57, uint8_t a58, uint8_t a59, uint8_t a60, uint8_t a61, uint8_t a62, uint8_t a63) { + return _mm512_set_epi64(uint64_t(a7) + (uint64_t(a6) << 8) + (uint64_t(a5) << 16) + (uint64_t(a4) << 24) + (uint64_t(a3) << 32) + (uint64_t(a2) << 40) + (uint64_t(a1) << 48) + (uint64_t(a0) << 56), + uint64_t(a15) + (uint64_t(a14) << 8) + (uint64_t(a13) << 16) + (uint64_t(a12) << 24) + (uint64_t(a11) << 32) + (uint64_t(a10) << 40) + (uint64_t(a9) << 48) + (uint64_t(a8) << 56), + uint64_t(a23) + (uint64_t(a22) << 8) + (uint64_t(a21) << 16) + (uint64_t(a20) << 24) + (uint64_t(a19) << 32) + (uint64_t(a18) << 40) + (uint64_t(a17) << 48) + (uint64_t(a16) << 56), + uint64_t(a31) + (uint64_t(a30) << 8) + (uint64_t(a29) << 16) + (uint64_t(a28) << 24) + (uint64_t(a27) << 32) + (uint64_t(a26) << 40) + (uint64_t(a25) << 48) + (uint64_t(a24) << 56), + uint64_t(a39) + (uint64_t(a38) << 8) + (uint64_t(a37) << 16) + (uint64_t(a36) << 24) + (uint64_t(a35) << 32) + (uint64_t(a34) << 40) + (uint64_t(a33) << 48) + (uint64_t(a32) << 56), + uint64_t(a47) + (uint64_t(a46) << 8) + (uint64_t(a45) << 16) + (uint64_t(a44) << 24) + (uint64_t(a43) << 32) + (uint64_t(a42) << 40) + (uint64_t(a41) << 48) + (uint64_t(a40) << 56), + uint64_t(a55) + (uint64_t(a54) << 8) + (uint64_t(a53) << 16) + (uint64_t(a52) << 24) + (uint64_t(a51) << 32) + (uint64_t(a50) << 40) + (uint64_t(a49) << 48) + (uint64_t(a48) << 56), + uint64_t(a63) + (uint64_t(a62) << 8) + (uint64_t(a61) << 16) + (uint64_t(a60) << 24) + (uint64_t(a59) << 32) + (uint64_t(a58) << 40) + (uint64_t(a57) << 48) + (uint64_t(a56) << 56)); +} +#endif // SIMDJSON_GCC8 + + + +namespace simdjson { + namespace icelake { + namespace { + namespace simd { + + // Forward-declared so they can be used by splat and friends. + template + struct base { + __m512i value; + + // Zero constructor + simdjson_inline base() : value{ __m512i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m512i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m512i& () const { return this->value; } + simdjson_inline operator __m512i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm512_or_si512(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm512_and_si512(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm512_xor_si512(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm512_andnot_si512(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + // Forward-declared so they can be used by splat and friends. + template + struct simd8; + + template> + struct base8 : base> { + typedef uint32_t bitmask_t; + typedef uint64_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m512i _value) : base>(_value) {} + + friend simdjson_really_inline uint64_t operator==(const simd8 lhs, const simd8 rhs) { + return _mm512_cmpeq_epi8_mask(lhs, rhs); + } + + static const int SIZE = sizeof(base::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + // workaround for compilers unable to figure out that 16 - N is a constant (GCC 8) + constexpr int shift = 16 - N; + return _mm512_alignr_epi8(*this, _mm512_permutex2var_epi64(prev_chunk, _mm512_set_epi64(13, 12, 11, 10, 9, 8, 7, 6), *this), shift); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm512_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m512i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + simdjson_inline bool any() const { return !!_mm512_test_epi8_mask(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm512_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm512_setzero_si512(); } + static simdjson_inline simd8 load(const T values[64]) { + return _mm512_loadu_si512(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m512i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[64]) const { return _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), *this); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm512_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm512_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm512_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint64_t mask, L* output) const { + _mm512_mask_compressstoreu_epi8(output, ~mask, *this); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, + int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, + int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31, + int8_t v32, int8_t v33, int8_t v34, int8_t v35, int8_t v36, int8_t v37, int8_t v38, int8_t v39, + int8_t v40, int8_t v41, int8_t v42, int8_t v43, int8_t v44, int8_t v45, int8_t v46, int8_t v47, + int8_t v48, int8_t v49, int8_t v50, int8_t v51, int8_t v52, int8_t v53, int8_t v54, int8_t v55, + int8_t v56, int8_t v57, int8_t v58, int8_t v59, int8_t v60, int8_t v61, int8_t v62, int8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epi8(*this, other); } + + simdjson_inline simd8 operator>(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(*this, other), _mm512_set1_epi8(uint8_t(0x80))); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(other, *this), _mm512_set1_epi8(uint8_t(0x80))); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, + uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, + uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31, + uint8_t v32, uint8_t v33, uint8_t v34, uint8_t v35, uint8_t v36, uint8_t v37, uint8_t v38, uint8_t v39, + uint8_t v40, uint8_t v41, uint8_t v42, uint8_t v43, uint8_t v44, uint8_t v45, uint8_t v46, uint8_t v47, + uint8_t v48, uint8_t v49, uint8_t v50, uint8_t v51, uint8_t v52, uint8_t v53, uint8_t v54, uint8_t v55, + uint8_t v56, uint8_t v57, uint8_t v58, uint8_t v59, uint8_t v60, uint8_t v61, uint8_t v62, uint8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm512_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm512_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epu8(other, *this); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline uint64_t operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline uint64_t operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return _mm512_mask_blend_epi8(*this == uint8_t(0), _mm512_set1_epi8(0), _mm512_set1_epi8(-1)); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + + simdjson_inline bool is_ascii() const { return _mm512_movepi8_mask(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { + return !_mm512_test_epi8_mask(*this, *this); + } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return !_mm512_test_epi8_mask(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm512_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm512_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline uint64_t get_bit() const { return _mm512_movepi8_mask(_mm512_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 1, "Icelake kernel should use one register per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} + simdjson_inline simd8x64(const simd8 chunk0) : chunks{ chunk0 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr) } {} + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(mask, output); + return 64 - count_ones(mask); + } + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + } + + simdjson_inline simd8 reduce_or() const { + return this->chunks[0]; + } + + simdjson_inline simd8x64 bit_or(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] | mask + ); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] == mask; + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return this->chunks[0] == other.chunks[0]; + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] <= mask; + } + }; // struct simd8x64 + + } // namespace simd + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_SIMD_H +/* end file simdjson/icelake/simd.h */ +/* including simdjson/icelake/stringparsing_defs.h: #include "simdjson/icelake/stringparsing_defs.h" */ +/* begin file simdjson/icelake/stringparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +#define SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 64; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint64_t bs_bits; + uint64_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast(v == '\\'), // bs_bits + static_cast(v == '"'), // quote_bits + }; + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +/* end file simdjson/icelake/stringparsing_defs.h */ +/* including simdjson/icelake/numberparsing_defs.h: #include "simdjson/icelake/numberparsing_defs.h" */ +/* begin file simdjson/icelake/numberparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +#define SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace numberparsing { + + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace icelake +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +/* end file simdjson/icelake/numberparsing_defs.h */ +/* end file simdjson/icelake/begin.h */ +/* including simdjson/generic/amalgamated.h for icelake: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for icelake */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for icelake: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for icelake */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for icelake */ +/* including simdjson/generic/jsoncharutils.h for icelake: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for icelake */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + namespace jsoncharutils { + + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for icelake */ +/* including simdjson/generic/atomparsing.h for icelake: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for icelake */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace icelake { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for icelake */ +/* including simdjson/generic/dom_parser_implementation.h for icelake: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for icelake */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container + + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); + + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; + + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; + + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; + + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + namespace icelake { + + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; + } + + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for icelake */ +/* including simdjson/generic/implementation_simdjson_result_base.h for icelake: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for icelake */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); + + +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for icelake */ +/* including simdjson/generic/numberparsing.h for icelake: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for icelake */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace icelake { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing +// +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. +// +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for icelake */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for icelake: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for icelake */ +/* end file simdjson/generic/amalgamated.h for icelake */ +/* including simdjson/icelake/end.h: #include "simdjson/icelake/end.h" */ +/* begin file simdjson/icelake/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "icelake" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/icelake/end.h */ + +#endif // SIMDJSON_ICELAKE_H +/* end file simdjson/icelake.h */ +/* including simdjson/icelake/implementation.h: #include */ +/* begin file simdjson/icelake/implementation.h */ +#ifndef SIMDJSON_ICELAKE_IMPLEMENTATION_H +#define SIMDJSON_ICELAKE_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE +namespace simdjson { + namespace icelake { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "icelake", + "Intel/AMD AVX512", + internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 | internal::instruction_set::AVX512F | internal::instruction_set::AVX512DQ | internal::instruction_set::AVX512CD | internal::instruction_set::AVX512BW | internal::instruction_set::AVX512VL | internal::instruction_set::AVX512VBMI2 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_IMPLEMENTATION_H +/* end file simdjson/icelake/implementation.h */ + +// defining SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER allows us to provide our own bit_indexer::write +#define SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + +/* including simdjson/icelake/begin.h: #include */ +/* begin file simdjson/icelake/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "icelake" */ +#define SIMDJSON_IMPLEMENTATION icelake +/* including simdjson/icelake/base.h: #include "simdjson/icelake/base.h" */ +/* begin file simdjson/icelake/base.h */ +#ifndef SIMDJSON_ICELAKE_BASE_H +#define SIMDJSON_ICELAKE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE +namespace simdjson { + /** + * Implementation for Icelake (Intel AVX512). + */ + namespace icelake { + + class implementation; + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BASE_H +/* end file simdjson/icelake/base.h */ +/* including simdjson/icelake/intrinsics.h: #include "simdjson/icelake/intrinsics.h" */ +/* begin file simdjson/icelake/intrinsics.h */ +#ifndef SIMDJSON_ICELAKE_INTRINSICS_H +#define SIMDJSON_ICELAKE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + * e.g., if __AVX2__ is set... in turn, we normally set these + * macros by compiling against the corresponding architecture + * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole + * software with these advanced instructions. In simdjson, we + * want to compile the whole program for a generic target, + * and only target our specific kernels. As a workaround, + * we directly include the needed headers. These headers would + * normally guard against such usage, but we carefully included + * (or ) before, so the headers + * are fooled. + */ +#include // for _blsr_u64 +#include // for __lzcnt64 +#include // for most things (AVX2, AVX512, _popcnt64) +#include +#include +#include +#include +#include // for _mm_clmulepi64_si128 + // Important: we need the AVX-512 headers: +#include +#include +#include +#include +#include +#include +#include +// unfortunately, we may not get _blsr_u64, but, thankfully, clang +// has it as a macro. +#ifndef _blsr_u64 +// we roll our own +#define _blsr_u64(n) ((n - 1) & n) +#endif // _blsr_u64 +#endif // SIMDJSON_CLANG_VISUAL_STUDIO + +static_assert(sizeof(__m512i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for icelake"); + +#endif // SIMDJSON_ICELAKE_INTRINSICS_H +/* end file simdjson/icelake/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_TARGET_REGION("avx512f,avx512dq,avx512cd,avx512bw,avx512vbmi,avx512vbmi2,avx512vl,avx2,bmi,pclmul,lzcnt,popcnt") +#endif + +/* including simdjson/icelake/bitmanipulation.h: #include "simdjson/icelake/bitmanipulation.h" */ +/* begin file simdjson/icelake/bitmanipulation.h */ +#ifndef SIMDJSON_ICELAKE_BITMANIPULATION_H +#define SIMDJSON_ICELAKE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return (int)_tzcnt_u64(input_num); +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + //////// + // You might expect the next line to be equivalent to + // return (int)_tzcnt_u64(input_num); + // but the generated code differs and might be less efficient? + //////// + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return _blsr_u64(input_num); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { + return int(_lzcnt_u64(input_num)); + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMANIPULATION_H +/* end file simdjson/icelake/bitmanipulation.h */ +/* including simdjson/icelake/bitmask.h: #include "simdjson/icelake/bitmask.h" */ +/* begin file simdjson/icelake/bitmask.h */ +#ifndef SIMDJSON_ICELAKE_BITMASK_H +#define SIMDJSON_ICELAKE_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processor supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMASK_H +/* end file simdjson/icelake/bitmask.h */ +/* including simdjson/icelake/simd.h: #include "simdjson/icelake/simd.h" */ +/* begin file simdjson/icelake/simd.h */ +#ifndef SIMDJSON_ICELAKE_SIMD_H +#define SIMDJSON_ICELAKE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if defined(__GNUC__) && !defined(__clang__) +#if __GNUC__ == 8 +#define SIMDJSON_GCC8 1 +#endif // __GNUC__ == 8 +#endif // defined(__GNUC__) && !defined(__clang__) + +#if SIMDJSON_GCC8 +/** + * GCC 8 fails to provide _mm512_set_epi8. We roll our own. + */ +inline __m512i _mm512_set_epi8(uint8_t a0, uint8_t a1, uint8_t a2, uint8_t a3, uint8_t a4, uint8_t a5, uint8_t a6, uint8_t a7, uint8_t a8, uint8_t a9, uint8_t a10, uint8_t a11, uint8_t a12, uint8_t a13, uint8_t a14, uint8_t a15, uint8_t a16, uint8_t a17, uint8_t a18, uint8_t a19, uint8_t a20, uint8_t a21, uint8_t a22, uint8_t a23, uint8_t a24, uint8_t a25, uint8_t a26, uint8_t a27, uint8_t a28, uint8_t a29, uint8_t a30, uint8_t a31, uint8_t a32, uint8_t a33, uint8_t a34, uint8_t a35, uint8_t a36, uint8_t a37, uint8_t a38, uint8_t a39, uint8_t a40, uint8_t a41, uint8_t a42, uint8_t a43, uint8_t a44, uint8_t a45, uint8_t a46, uint8_t a47, uint8_t a48, uint8_t a49, uint8_t a50, uint8_t a51, uint8_t a52, uint8_t a53, uint8_t a54, uint8_t a55, uint8_t a56, uint8_t a57, uint8_t a58, uint8_t a59, uint8_t a60, uint8_t a61, uint8_t a62, uint8_t a63) { + return _mm512_set_epi64(uint64_t(a7) + (uint64_t(a6) << 8) + (uint64_t(a5) << 16) + (uint64_t(a4) << 24) + (uint64_t(a3) << 32) + (uint64_t(a2) << 40) + (uint64_t(a1) << 48) + (uint64_t(a0) << 56), + uint64_t(a15) + (uint64_t(a14) << 8) + (uint64_t(a13) << 16) + (uint64_t(a12) << 24) + (uint64_t(a11) << 32) + (uint64_t(a10) << 40) + (uint64_t(a9) << 48) + (uint64_t(a8) << 56), + uint64_t(a23) + (uint64_t(a22) << 8) + (uint64_t(a21) << 16) + (uint64_t(a20) << 24) + (uint64_t(a19) << 32) + (uint64_t(a18) << 40) + (uint64_t(a17) << 48) + (uint64_t(a16) << 56), + uint64_t(a31) + (uint64_t(a30) << 8) + (uint64_t(a29) << 16) + (uint64_t(a28) << 24) + (uint64_t(a27) << 32) + (uint64_t(a26) << 40) + (uint64_t(a25) << 48) + (uint64_t(a24) << 56), + uint64_t(a39) + (uint64_t(a38) << 8) + (uint64_t(a37) << 16) + (uint64_t(a36) << 24) + (uint64_t(a35) << 32) + (uint64_t(a34) << 40) + (uint64_t(a33) << 48) + (uint64_t(a32) << 56), + uint64_t(a47) + (uint64_t(a46) << 8) + (uint64_t(a45) << 16) + (uint64_t(a44) << 24) + (uint64_t(a43) << 32) + (uint64_t(a42) << 40) + (uint64_t(a41) << 48) + (uint64_t(a40) << 56), + uint64_t(a55) + (uint64_t(a54) << 8) + (uint64_t(a53) << 16) + (uint64_t(a52) << 24) + (uint64_t(a51) << 32) + (uint64_t(a50) << 40) + (uint64_t(a49) << 48) + (uint64_t(a48) << 56), + uint64_t(a63) + (uint64_t(a62) << 8) + (uint64_t(a61) << 16) + (uint64_t(a60) << 24) + (uint64_t(a59) << 32) + (uint64_t(a58) << 40) + (uint64_t(a57) << 48) + (uint64_t(a56) << 56)); +} +#endif // SIMDJSON_GCC8 + + + +namespace simdjson { + namespace icelake { + namespace { + namespace simd { + + // Forward-declared so they can be used by splat and friends. + template + struct base { + __m512i value; + + // Zero constructor + simdjson_inline base() : value{ __m512i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m512i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m512i& () const { return this->value; } + simdjson_inline operator __m512i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm512_or_si512(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm512_and_si512(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm512_xor_si512(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm512_andnot_si512(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + // Forward-declared so they can be used by splat and friends. + template + struct simd8; + + template> + struct base8 : base> { + typedef uint32_t bitmask_t; + typedef uint64_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m512i _value) : base>(_value) {} + + friend simdjson_really_inline uint64_t operator==(const simd8 lhs, const simd8 rhs) { + return _mm512_cmpeq_epi8_mask(lhs, rhs); + } + + static const int SIZE = sizeof(base::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + // workaround for compilers unable to figure out that 16 - N is a constant (GCC 8) + constexpr int shift = 16 - N; + return _mm512_alignr_epi8(*this, _mm512_permutex2var_epi64(prev_chunk, _mm512_set_epi64(13, 12, 11, 10, 9, 8, 7, 6), *this), shift); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm512_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m512i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + simdjson_inline bool any() const { return !!_mm512_test_epi8_mask(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm512_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm512_setzero_si512(); } + static simdjson_inline simd8 load(const T values[64]) { + return _mm512_loadu_si512(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m512i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[64]) const { return _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), *this); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm512_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm512_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm512_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint64_t mask, L* output) const { + _mm512_mask_compressstoreu_epi8(output, ~mask, *this); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, + int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, + int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31, + int8_t v32, int8_t v33, int8_t v34, int8_t v35, int8_t v36, int8_t v37, int8_t v38, int8_t v39, + int8_t v40, int8_t v41, int8_t v42, int8_t v43, int8_t v44, int8_t v45, int8_t v46, int8_t v47, + int8_t v48, int8_t v49, int8_t v50, int8_t v51, int8_t v52, int8_t v53, int8_t v54, int8_t v55, + int8_t v56, int8_t v57, int8_t v58, int8_t v59, int8_t v60, int8_t v61, int8_t v62, int8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epi8(*this, other); } + + simdjson_inline simd8 operator>(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(*this, other), _mm512_set1_epi8(uint8_t(0x80))); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(other, *this), _mm512_set1_epi8(uint8_t(0x80))); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, + uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, + uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31, + uint8_t v32, uint8_t v33, uint8_t v34, uint8_t v35, uint8_t v36, uint8_t v37, uint8_t v38, uint8_t v39, + uint8_t v40, uint8_t v41, uint8_t v42, uint8_t v43, uint8_t v44, uint8_t v45, uint8_t v46, uint8_t v47, + uint8_t v48, uint8_t v49, uint8_t v50, uint8_t v51, uint8_t v52, uint8_t v53, uint8_t v54, uint8_t v55, + uint8_t v56, uint8_t v57, uint8_t v58, uint8_t v59, uint8_t v60, uint8_t v61, uint8_t v62, uint8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm512_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm512_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epu8(other, *this); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline uint64_t operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline uint64_t operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return _mm512_mask_blend_epi8(*this == uint8_t(0), _mm512_set1_epi8(0), _mm512_set1_epi8(-1)); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + + simdjson_inline bool is_ascii() const { return _mm512_movepi8_mask(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { + return !_mm512_test_epi8_mask(*this, *this); + } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return !_mm512_test_epi8_mask(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm512_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm512_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline uint64_t get_bit() const { return _mm512_movepi8_mask(_mm512_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 1, "Icelake kernel should use one register per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} + simdjson_inline simd8x64(const simd8 chunk0) : chunks{ chunk0 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr) } {} + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(mask, output); + return 64 - count_ones(mask); + } + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + } + + simdjson_inline simd8 reduce_or() const { + return this->chunks[0]; + } + + simdjson_inline simd8x64 bit_or(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] | mask + ); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] == mask; + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return this->chunks[0] == other.chunks[0]; + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] <= mask; + } + }; // struct simd8x64 + + } // namespace simd + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_SIMD_H +/* end file simdjson/icelake/simd.h */ +/* including simdjson/icelake/stringparsing_defs.h: #include "simdjson/icelake/stringparsing_defs.h" */ +/* begin file simdjson/icelake/stringparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +#define SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 64; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint64_t bs_bits; + uint64_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast(v == '\\'), // bs_bits + static_cast(v == '"'), // quote_bits + }; + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +/* end file simdjson/icelake/stringparsing_defs.h */ +/* including simdjson/icelake/numberparsing_defs.h: #include "simdjson/icelake/numberparsing_defs.h" */ +/* begin file simdjson/icelake/numberparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +#define SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace numberparsing { + + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace icelake +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +/* end file simdjson/icelake/numberparsing_defs.h */ +/* end file simdjson/icelake/begin.h */ +/* including generic/amalgamated.h for icelake: #include */ +/* begin file generic/amalgamated.h for icelake */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_SRC_GENERIC_DEPENDENCIES_H) +#error generic/dependencies.h must be included before generic/amalgamated.h! +#endif + +/* including generic/base.h for icelake: #include */ +/* begin file generic/base.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + struct json_character_block; + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_BASE_H +/* end file generic/base.h for icelake */ +/* including generic/dom_parser_implementation.h for icelake: #include */ +/* begin file generic/dom_parser_implementation.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// Interface a dom parser implementation must fulfill +namespace simdjson { + namespace icelake { + namespace { + + simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3); + simdjson_inline bool is_ascii(const simd8x64& input); + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file generic/dom_parser_implementation.h for icelake */ +/* including generic/json_character_block.h for icelake: #include */ +/* begin file generic/json_character_block.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + struct json_character_block { + static simdjson_inline json_character_block classify(const simd::simd8x64& in); + + simdjson_inline uint64_t whitespace() const noexcept { return _whitespace; } + simdjson_inline uint64_t op() const noexcept { return _op; } + simdjson_inline uint64_t scalar() const noexcept { return ~(op() | whitespace()); } + + uint64_t _whitespace; + uint64_t _op; + }; + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H +/* end file generic/json_character_block.h for icelake */ +/* end file generic/amalgamated.h for icelake */ +/* including generic/stage1/amalgamated.h for icelake: #include */ +/* begin file generic/stage1/amalgamated.h for icelake */ +// Stuff other things depend on +/* including generic/stage1/base.h for icelake: #include */ +/* begin file generic/stage1/base.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + namespace stage1 { + + class bit_indexer; + template + struct buf_block_reader; + struct json_block; + class json_minifier; + class json_scanner; + struct json_string_block; + class json_string_scanner; + class json_structural_indexer; + + } // namespace stage1 + + namespace utf8_validation { + struct utf8_checker; + } // namespace utf8_validation + + using utf8_validation::utf8_checker; + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BASE_H +/* end file generic/stage1/base.h for icelake */ +/* including generic/stage1/buf_block_reader.h for icelake: #include */ +/* begin file generic/stage1/buf_block_reader.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace icelake { + namespace { + namespace stage1 { + + // Walks through a buffer in block-sized increments, loading the last part with spaces + template + struct buf_block_reader { + public: + simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); + simdjson_inline size_t block_index(); + simdjson_inline bool has_full_block() const; + simdjson_inline const uint8_t* full_block() const; + /** + * Get the last block, padded with spaces. + * + * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this + * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there + * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. + * + * @return the number of effective characters in the last block. + */ + simdjson_inline size_t get_remainder(uint8_t* dst) const; + simdjson_inline void advance(); + private: + const uint8_t* buf; + const size_t len; + const size_t lenminusstep; + size_t idx; + }; + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text_64(const uint8_t* text) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < sizeof(simd8x64); i++) { + buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text(const simd8x64& in) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] < ' ') { buf[i] = '_'; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_input_text(const simd8x64& in, uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] <= ' ') { buf[i] = '_'; } + if (!(mask & (size_t(1) << i))) { buf[i] = ' '; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_mask(uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < 64; i++) { + buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; + } + buf[64] = '\0'; + return buf; + } + + template + simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} + + template + simdjson_inline size_t buf_block_reader::block_index() { return idx; } + + template + simdjson_inline bool buf_block_reader::has_full_block() const { + return idx < lenminusstep; + } + + template + simdjson_inline const uint8_t* buf_block_reader::full_block() const { + return &buf[idx]; + } + + template + simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { + if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers + std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. + std::memcpy(dst, buf + idx, len - idx); + return len - idx; + } + + template + simdjson_inline void buf_block_reader::advance() { + idx += STEP_SIZE; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H +/* end file generic/stage1/buf_block_reader.h for icelake */ +/* including generic/stage1/json_escape_scanner.h for icelake: #include */ +/* begin file generic/stage1/json_escape_scanner.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + namespace stage1 { + + /** + * Scans for escape characters in JSON, taking care with multiple backslashes (\\n vs. \n). + */ + struct json_escape_scanner { + /** The actual escape characters (the backslashes themselves). */ + uint64_t next_is_escaped = 0ULL; + + struct escaped_and_escape { + /** + * Mask of escaped characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 0100100010100101000 + * n \ \ n \ \ + * ``` + */ + uint64_t escaped; + /** + * Mask of escape characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 1001000101001010001 + * \ \ \ \ \ \ \ + * ``` + */ + uint64_t escape; + }; + + /** + * Get a mask of both escape and escaped characters (the characters following a backslash). + * + * @param potential_escape A mask of the character that can escape others (but could be + * escaped itself). e.g. block.eq('\\') + */ + simdjson_really_inline escaped_and_escape next(uint64_t backslash) noexcept { + +#if !SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT + if (!backslash) { return { next_escaped_without_backslashes(), 0 }; } +#endif + + // | | Mask (shows characters instead of 1's) | Depth | Instructions | + // |--------------------------------|----------------------------------------|-------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | | | + // | | ` even odd even odd odd` | | | + // | potential_escape | ` \ \\\ \\\ \\\\ \\\\ \\\` | 1 | 1 (backslash & ~first_is_escaped) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 5 | 5 (next_escape_and_terminal_code()) + // | escaped | `\ \ n \ n \ \ \ \ \ ` X | 6 | 7 (escape_and_terminal_code ^ (potential_escape | first_is_escaped)) + // | escape | ` \ \ \ \ \ \ \ \ \ \` | 6 | 8 (escape_and_terminal_code & backslash) + // | first_is_escaped | `\ ` | 7 (*) | 9 (escape >> 63) () + // (*) this is not needed until the next iteration + uint64_t escape_and_terminal_code = next_escape_and_terminal_code(backslash & ~this->next_is_escaped); + uint64_t escaped = escape_and_terminal_code ^ (backslash | this->next_is_escaped); + uint64_t escape = escape_and_terminal_code & backslash; + this->next_is_escaped = escape >> 63; + return { escaped, escape }; + } + + private: + static constexpr const uint64_t ODD_BITS = 0xAAAAAAAAAAAAAAAAULL; + + simdjson_really_inline uint64_t next_escaped_without_backslashes() noexcept { + uint64_t escaped = this->next_is_escaped; + this->next_is_escaped = 0; + return escaped; + } + + /** + * Returns a mask of the next escape characters (masking out escaped backslashes), along with + * any non-backslash escape codes. + * + * \n \\n \\\n \\\\n returns: + * \n \ \ \n \ \ + * 11 100 1011 10100 + * + * You are expected to mask out the first bit yourself if the previous block had a trailing + * escape. + * + * & the result with potential_escape to get just the escape characters. + * ^ the result with (potential_escape | first_is_escaped) to get escaped characters. + */ + static simdjson_really_inline uint64_t next_escape_and_terminal_code(uint64_t potential_escape) noexcept { + // If we were to just shift and mask out any odd bits, we'd actually get a *half* right answer: + // any even-aligned backslash runs would be correct! Odd-aligned backslash runs would be + // inverted (\\\ would be 010 instead of 101). + // + // ``` + // string: | ____\\\\_\\\\_____ | + // maybe_escaped | ODD | \ \ \ \ | + // even-aligned ^^^ ^^^^ odd-aligned + // ``` + // + // Taking that into account, our basic strategy is: + // + // 1. Use subtraction to produce a mask with 1's for even-aligned runs and 0's for + // odd-aligned runs. + // 2. XOR all odd bits, which masks out the odd bits in even-aligned runs, and brings IN the + // odd bits in odd-aligned runs. + // 3. & with backslash to clean up any stray bits. + // runs are set to 0, and then XORing with "odd": + // + // | | Mask (shows characters instead of 1's) | Instructions | + // |--------------------------------|----------------------------------------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | + // | | ` even odd even odd odd` | + // | maybe_escaped | ` n \\n \\n \\\_ \\\_ \\` X | 1 (potential_escape << 1) + // | maybe_escaped_and_odd | ` \n_ \\n _ \\\n_ _ \\\__ _\\\_ \\\` | 1 (maybe_escaped | odd) + // | even_series_codes_and_odd | ` n_\\\ _ n_ _\\\\ _ _ ` | 1 (maybe_escaped_and_odd - potential_escape) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 1 (^ odd) + // + + // Escaped characters are characters following an escape. + uint64_t maybe_escaped = potential_escape << 1; + + // To distinguish odd from even escape sequences, therefore, we turn on any *starting* + // escapes that are on an odd byte. (We actually bring in all odd bits, for speed.) + // - Odd runs of backslashes are 0000, and the code at the end ("n" in \n or \\n) is 1. + // - Odd runs of backslashes are 1111, and the code at the end ("n" in \n or \\n) is 0. + // - All other odd bytes are 1, and even bytes are 0. + uint64_t maybe_escaped_and_odd_bits = maybe_escaped | ODD_BITS; + uint64_t even_series_codes_and_odd_bits = maybe_escaped_and_odd_bits - potential_escape; + + // Now we flip all odd bytes back with xor. This: + // - Makes odd runs of backslashes go from 0000 to 1010 + // - Makes even runs of backslashes go from 1111 to 1010 + // - Sets actually-escaped codes to 1 (the n in \n and \\n: \n = 11, \\n = 100) + // - Resets all other bytes to 0 + return even_series_codes_and_odd_bits ^ ODD_BITS; + } + }; + + } // namespace stage1 + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_escape_scanner.h for icelake */ +/* including generic/stage1/json_string_scanner.h for icelake: #include */ +/* begin file generic/stage1/json_string_scanner.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + namespace stage1 { + + struct json_string_block { + // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 + simdjson_really_inline json_string_block(uint64_t escaped, uint64_t quote, uint64_t in_string) : + _escaped(escaped), _quote(quote), _in_string(in_string) {} + + // Escaped characters (characters following an escape() character) + simdjson_really_inline uint64_t escaped() const { return _escaped; } + // Real (non-backslashed) quotes + simdjson_really_inline uint64_t quote() const { return _quote; } + // Only characters inside the string (not including the quotes) + simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } + // Tail of string (everything except the start quote) + simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; } + + // escaped characters (backslashed--does not include the hex characters after \u) + uint64_t _escaped; + // real quotes (non-escaped ones) + uint64_t _quote; + // string characters (includes start quote but not end quote) + uint64_t _in_string; + }; + + // Scans blocks for string characters, storing the state necessary to do so + class json_string_scanner { + public: + simdjson_really_inline json_string_block next(const simd::simd8x64& in); + // Returns either UNCLOSED_STRING or SUCCESS + simdjson_really_inline error_code finish(); + + private: + // Scans for escape characters + json_escape_scanner escape_scanner{}; + // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). + uint64_t prev_in_string = 0ULL; + }; + + // + // Return a mask of all string characters plus end quotes. + // + // prev_escaped is overflow saying whether the next character is escaped. + // prev_in_string is overflow saying whether we're still in a string. + // + // Backslash sequences outside of quotes will be detected in stage 2. + // + simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { + const uint64_t backslash = in.eq('\\'); + const uint64_t escaped = escape_scanner.next(backslash).escaped; + const uint64_t quote = in.eq('"') & ~escaped; + + // + // prefix_xor flips on bits inside the string (and flips off the end quote). + // + // Then we xor with prev_in_string: if we were in a string already, its effect is flipped + // (characters inside strings are outside, and characters outside strings are inside). + // + const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; + + // + // Check if we're still in a string at the end of the box so the next block will know + // + prev_in_string = uint64_t(static_cast(in_string) >> 63); + + // Use ^ to turn the beginning quote off, and the end quote on. + + // We are returning a function-local object so either we get a move constructor + // or we get copy elision. + return json_string_block(escaped, quote, in_string); + } + + simdjson_really_inline error_code json_string_scanner::finish() { + if (prev_in_string) { + return UNCLOSED_STRING; + } + return SUCCESS; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_string_scanner.h for icelake */ +/* including generic/stage1/utf8_lookup4_algorithm.h for icelake: #include */ +/* begin file generic/stage1/utf8_lookup4_algorithm.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { namespace { namespace utf8_validation { @@ -9668,14 +27924,6 @@ namespace simdjson { this->error |= this->prev_incomplete; } -#ifndef SIMDJSON_IF_CONSTEXPR -#if SIMDJSON_CPLUSPLUS17 -#define SIMDJSON_IF_CONSTEXPR if constexpr -#else -#define SIMDJSON_IF_CONSTEXPR if -#endif -#endif - simdjson_inline void check_next_input(const simd8x64& input) { if (simdjson_likely(is_ascii(input))) { this->error |= this->prev_incomplete; @@ -9690,17 +27938,17 @@ namespace simdjson { this->check_utf8_bytes(input.chunks[0], this->prev_input_block); } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - } + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 4) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - this->check_utf8_bytes(input.chunks[2], input.chunks[1]); - this->check_utf8_bytes(input.chunks[3], input.chunks[2]); - } - this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); - this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + this->check_utf8_bytes(input.chunks[2], input.chunks[1]); + this->check_utf8_bytes(input.chunks[3], input.chunks[2]); + } + this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); + this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; } } // do not forget to call check_eof! @@ -9711,270 +27959,25 @@ else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { }; // struct utf8_checker } // namespace utf8_validation - using utf8_validation::utf8_checker; - } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage1/utf8_lookup4_algorithm.h */ -/* begin file src/generic/stage1/json_structural_indexer.h */ -// This file contains the common code every implementation uses in stage1 -// It is intended to be included multiple times and compiled multiple times -// We assume the file in which it is included already includes -// "simdjson/stage1.h" (this simplifies amalgation) -/* begin file src/generic/stage1/buf_block_reader.h */ +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H +/* end file generic/stage1/utf8_lookup4_algorithm.h for icelake */ +/* including generic/stage1/json_scanner.h for icelake: #include */ +/* begin file generic/stage1/json_scanner.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace haswell { - namespace { - - // Walks through a buffer in block-sized increments, loading the last part with spaces - template - struct buf_block_reader { - public: - simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); - simdjson_inline size_t block_index(); - simdjson_inline bool has_full_block() const; - simdjson_inline const uint8_t* full_block() const; - /** - * Get the last block, padded with spaces. - * - * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this - * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there - * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. - * - * @return the number of effective characters in the last block. - */ - simdjson_inline size_t get_remainder(uint8_t* dst) const; - simdjson_inline void advance(); - private: - const uint8_t* buf; - const size_t len; - const size_t lenminusstep; - size_t idx; - }; - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text_64(const uint8_t* text) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < sizeof(simd8x64); i++) { - buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text(const simd8x64& in) { - static char buf[sizeof(simd8x64) + 1]; - in.store(reinterpret_cast(buf)); - for (size_t i = 0; i < sizeof(simd8x64); i++) { - if (buf[i] < ' ') { buf[i] = '_'; } - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - simdjson_unused static char* format_mask(uint64_t mask) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < 64; i++) { - buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; - } - buf[64] = '\0'; - return buf; - } - - template - simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} - - template - simdjson_inline size_t buf_block_reader::block_index() { return idx; } - - template - simdjson_inline bool buf_block_reader::has_full_block() const { - return idx < lenminusstep; - } - - template - simdjson_inline const uint8_t* buf_block_reader::full_block() const { - return &buf[idx]; - } - - template - simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { - if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers - std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. - std::memcpy(dst, buf + idx, len - idx); - return len - idx; - } - - template - simdjson_inline void buf_block_reader::advance() { - idx += STEP_SIZE; - } - - } // unnamed namespace - } // namespace haswell -} // namespace simdjson -/* end file src/generic/stage1/buf_block_reader.h */ -/* begin file src/generic/stage1/json_string_scanner.h */ -namespace simdjson { - namespace haswell { - namespace { - namespace stage1 { - - struct json_string_block { - // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 - simdjson_inline json_string_block(uint64_t backslash, uint64_t escaped, uint64_t quote, uint64_t in_string) : - _backslash(backslash), _escaped(escaped), _quote(quote), _in_string(in_string) {} - - // Escaped characters (characters following an escape() character) - simdjson_inline uint64_t escaped() const { return _escaped; } - // Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \) - simdjson_inline uint64_t escape() const { return _backslash & ~_escaped; } - // Real (non-backslashed) quotes - simdjson_inline uint64_t quote() const { return _quote; } - // Start quotes of strings - simdjson_inline uint64_t string_start() const { return _quote & _in_string; } - // End quotes of strings - simdjson_inline uint64_t string_end() const { return _quote & ~_in_string; } - // Only characters inside the string (not including the quotes) - simdjson_inline uint64_t string_content() const { return _in_string & ~_quote; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } - // Tail of string (everything except the start quote) - simdjson_inline uint64_t string_tail() const { return _in_string ^ _quote; } - - // backslash characters - uint64_t _backslash; - // escaped characters (backslashed--does not include the hex characters after \u) - uint64_t _escaped; - // real quotes (non-backslashed ones) - uint64_t _quote; - // string characters (includes start quote but not end quote) - uint64_t _in_string; - }; - - // Scans blocks for string characters, storing the state necessary to do so - class json_string_scanner { - public: - simdjson_inline json_string_block next(const simd::simd8x64& in); - // Returns either UNCLOSED_STRING or SUCCESS - simdjson_inline error_code finish(); - - private: - // Intended to be defined by the implementation - simdjson_inline uint64_t find_escaped(uint64_t escape); - simdjson_inline uint64_t find_escaped_branchless(uint64_t escape); - - // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). - uint64_t prev_in_string = 0ULL; - // Whether the first character of the next iteration is escaped. - uint64_t prev_escaped = 0ULL; - }; - - // - // Finds escaped characters (characters following \). - // - // Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively). - // - // Does this by: - // - Shift the escape mask to get potentially escaped characters (characters after backslashes). - // - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not) - // - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not) - // - // To distinguish between escaped sequences starting on even/odd bits, it finds the start of all - // escape sequences, filters out the ones that start on even bits, and adds that to the mask of - // escape sequences. This causes the addition to clear out the sequences starting on odd bits (since - // the start bit causes a carry), and leaves even-bit sequences alone. - // - // Example: - // - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape - // odd_starts | x | x x x | escape & ~even_bits & ~follows_escape - // even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later - // invert_mask | | cxxx c xx c| even_seq << 1 - // follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit - // escaped | x | x x x x x x x x | - // desired | x | x x x x x x x x | - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // - simdjson_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) { - // If there was overflow, pretend the first character isn't a backslash - backslash &= ~prev_escaped; - uint64_t follows_escape = backslash << 1 | prev_escaped; - - // Get sequences starting on even bits by clearing out the odd series using + - const uint64_t even_bits = 0x5555555555555555ULL; - uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape; - uint64_t sequences_starting_on_even_bits; - prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits); - uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes. - - // Mask every other backslashed character as an escaped character - // Flip the mask for sequences that start on even bits, to correct them - return (even_bits ^ invert_mask) & follows_escape; - } - - // - // Return a mask of all string characters plus end quotes. - // - // prev_escaped is overflow saying whether the next character is escaped. - // prev_in_string is overflow saying whether we're still in a string. - // - // Backslash sequences outside of quotes will be detected in stage 2. - // - simdjson_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { - const uint64_t backslash = in.eq('\\'); - const uint64_t escaped = find_escaped(backslash); - const uint64_t quote = in.eq('"') & ~escaped; - - // - // prefix_xor flips on bits inside the string (and flips off the end quote). - // - // Then we xor with prev_in_string: if we were in a string already, its effect is flipped - // (characters inside strings are outside, and characters outside strings are inside). - // - const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; - - // - // Check if we're still in a string at the end of the box so the next block will know - // - // right shift of a signed value expected to be well-defined and standard - // compliant as of C++20, John Regher from Utah U. says this is fine code - // - prev_in_string = uint64_t(static_cast(in_string) >> 63); - - // Use ^ to turn the beginning quote off, and the end quote on. - - // We are returning a function-local object so either we get a move constructor - // or we get copy elision. - return json_string_block( - backslash, - escaped, - quote, - in_string - ); - } - - simdjson_inline error_code json_string_scanner::finish() { - if (prev_in_string) { - return UNCLOSED_STRING; - } - return SUCCESS; - } - - } // namespace stage1 - } // unnamed namespace - } // namespace haswell -} // namespace simdjson -/* end file src/generic/stage1/json_string_scanner.h */ -/* begin file src/generic/stage1/json_scanner.h */ -namespace simdjson { - namespace haswell { + namespace icelake { namespace { namespace stage1 { @@ -10128,17 +28131,139 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage1/json_scanner.h */ -/* begin file src/generic/stage1/json_minifier.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H +/* end file generic/stage1/json_scanner.h for icelake */ + +// All other declarations +/* including generic/stage1/find_next_document_index.h for icelake: #include */ +/* begin file generic/stage1/find_next_document_index.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + namespace stage1 { + + /** + * This algorithm is used to quickly identify the last structural position that + * makes up a complete document. + * + * It does this by going backwards and finding the last *document boundary* (a + * place where one value follows another without a comma between them). If the + * last document (the characters after the boundary) has an equal number of + * start and end brackets, it is considered complete. + * + * Simply put, we iterate over the structural characters, starting from + * the end. We consider that we found the end of a JSON document when the + * first element of the pair is NOT one of these characters: '{' '[' ':' ',' + * and when the second element is NOT one of these characters: '}' ']' ':' ','. + * + * This simple comparison works most of the time, but it does not cover cases + * where the batch's structural indexes contain a perfect amount of documents. + * In such a case, we do not have access to the structural index which follows + * the last document, therefore, we do not have access to the second element in + * the pair, and that means we cannot identify the last document. To fix this + * issue, we keep a count of the open and closed curly/square braces we found + * while searching for the pair. When we find a pair AND the count of open and + * closed curly/square braces is the same, we know that we just passed a + * complete document, therefore the last json buffer location is the end of the + * batch. + */ + simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { + // Variant: do not count separately, just figure out depth + if (parser.n_structural_indexes == 0) { return 0; } + auto arr_cnt = 0; + auto obj_cnt = 0; + for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { + auto idxb = parser.structural_indexes[i]; + switch (parser.buf[idxb]) { + case ':': + case ',': + continue; + case '}': + obj_cnt--; + continue; + case ']': + arr_cnt--; + continue; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + auto idxa = parser.structural_indexes[i - 1]; + switch (parser.buf[idxa]) { + case '{': + case '[': + case ':': + case ',': + continue; + } + // Last document is complete, so the next document will appear after! + if (!arr_cnt && !obj_cnt) { + return parser.n_structural_indexes; + } + // Last document is incomplete; mark the document at i + 1 as the next one + return i; + } + // If we made it to the end, we want to finish counting to see if we have a full document. + switch (parser.buf[parser.structural_indexes[0]]) { + case '}': + obj_cnt--; + break; + case ']': + arr_cnt--; + break; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + if (!arr_cnt && !obj_cnt) { + // We have a complete document. + return parser.n_structural_indexes; + } + return 0; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H +/* end file generic/stage1/find_next_document_index.h for icelake */ +/* including generic/stage1/json_minifier.h for icelake: #include */ +/* begin file generic/stage1/json_minifier.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + // This file contains the common code every implementation uses in stage1 // It is intended to be included multiple times and compiled multiple times // We assume the file in which it is included already includes // "simdjson/stage1.h" (this simplifies amalgation) namespace simdjson { - namespace haswell { + namespace icelake { namespace { namespace stage1 { @@ -10223,107 +28348,33 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage1/json_minifier.h */ -/* begin file src/generic/stage1/find_next_document_index.h */ -namespace simdjson { - namespace haswell { - namespace { - /** - * This algorithm is used to quickly identify the last structural position that - * makes up a complete document. - * - * It does this by going backwards and finding the last *document boundary* (a - * place where one value follows another without a comma between them). If the - * last document (the characters after the boundary) has an equal number of - * start and end brackets, it is considered complete. - * - * Simply put, we iterate over the structural characters, starting from - * the end. We consider that we found the end of a JSON document when the - * first element of the pair is NOT one of these characters: '{' '[' ':' ',' - * and when the second element is NOT one of these characters: '}' ']' ':' ','. - * - * This simple comparison works most of the time, but it does not cover cases - * where the batch's structural indexes contain a perfect amount of documents. - * In such a case, we do not have access to the structural index which follows - * the last document, therefore, we do not have access to the second element in - * the pair, and that means we cannot identify the last document. To fix this - * issue, we keep a count of the open and closed curly/square braces we found - * while searching for the pair. When we find a pair AND the count of open and - * closed curly/square braces is the same, we know that we just passed a - * complete document, therefore the last json buffer location is the end of the - * batch. - */ - simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { - // Variant: do not count separately, just figure out depth - if (parser.n_structural_indexes == 0) { return 0; } - auto arr_cnt = 0; - auto obj_cnt = 0; - for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { - auto idxb = parser.structural_indexes[i]; - switch (parser.buf[idxb]) { - case ':': - case ',': - continue; - case '}': - obj_cnt--; - continue; - case ']': - arr_cnt--; - continue; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - auto idxa = parser.structural_indexes[i - 1]; - switch (parser.buf[idxa]) { - case '{': - case '[': - case ':': - case ',': - continue; - } - // Last document is complete, so the next document will appear after! - if (!arr_cnt && !obj_cnt) { - return parser.n_structural_indexes; - } - // Last document is incomplete; mark the document at i + 1 as the next one - return i; - } - // If we made it to the end, we want to finish counting to see if we have a full document. - switch (parser.buf[parser.structural_indexes[0]]) { - case '}': - obj_cnt--; - break; - case ']': - arr_cnt--; - break; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - if (!arr_cnt && !obj_cnt) { - // We have a complete document. - return parser.n_structural_indexes; - } - return 0; - } +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H +/* end file generic/stage1/json_minifier.h for icelake */ +/* including generic/stage1/json_structural_indexer.h for icelake: #include */ +/* begin file generic/stage1/json_structural_indexer.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H - } // unnamed namespace - } // namespace haswell -} // namespace simdjson -/* end file src/generic/stage1/find_next_document_index.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses in stage1 +// It is intended to be included multiple times and compiled multiple times +// We assume the file in which it is included already includes +// "simdjson/stage1.h" (this simplifies amalgation) namespace simdjson { - namespace haswell { + namespace icelake { namespace { namespace stage1 { @@ -10333,15 +28384,67 @@ namespace simdjson { simdjson_inline bit_indexer(uint32_t* index_buf) : tail(index_buf) {} +#if SIMDJSON_PREFER_REVERSE_BITS + /** + * ARM lacks a fast trailing zero instruction, but it has a fast + * bit reversal instruction and a fast leading zero instruction. + * Thus it may be profitable to reverse the bits (once) and then + * to rely on a sequence of instructions that call the leading + * zero instruction. + * + * Performance notes: + * The chosen routine is not optimal in terms of data dependency + * since zero_leading_bit might require two instructions. However, + * it tends to minimize the total number of instructions which is + * beneficial. + */ + simdjson_inline void write_index(uint32_t idx, uint64_t& rev_bits, int i) { + int lz = leading_zeroes(rev_bits); + this->tail[i] = static_cast(idx) + lz; + rev_bits = zero_leading_bit(rev_bits, lz); + } +#else + /** + * Under recent x64 systems, we often have both a fast trailing zero + * instruction and a fast 'clear-lower-bit' instruction so the following + * algorithm can be competitive. + */ + + simdjson_inline void write_index(uint32_t idx, uint64_t& bits, int i) { + this->tail[i] = idx + trailing_zeroes(bits); + bits = clear_lowest_bit(bits); + } +#endif // SIMDJSON_PREFER_REVERSE_BITS + + template + simdjson_inline int write_indexes(uint32_t idx, uint64_t& bits) { + write_index(idx, bits, START); + SIMDJSON_IF_CONSTEXPR(N > 1) { + write_indexes<(N - 1 > 0 ? START + 1 : START), (N - 1 >= 0 ? N - 1 : 1)>(idx, bits); + } + return START + N; + } + + template + simdjson_inline int write_indexes_stepped(uint32_t idx, uint64_t& bits, int cnt) { + write_indexes(idx, bits); + SIMDJSON_IF_CONSTEXPR((START + STEP) < END) { + if (simdjson_unlikely((START + STEP) < cnt)) { + write_indexes_stepped<(START + STEP < END ? START + STEP : END), END, STEP>(idx, bits, cnt); + } + } + return ((END - START) % STEP) == 0 ? END : (END - START) - ((END - START) % STEP) + STEP; + } + // flatten out values in 'bits' assuming that they are are to have values of idx // plus their position in the bitvector, and store these indexes at // base_ptr[base] incrementing base as we go // will potentially store extra values beyond end of valid bits, so base_ptr // needs to be large enough to handle this // - // If the kernel sets SIMDJSON_CUSTOM_BIT_INDEXER, then it will provide its own - // version of the code. -#ifdef SIMDJSON_CUSTOM_BIT_INDEXER + // If the kernel sets SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER, then it + // will provide its own version of the code. +#ifdef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER simdjson_inline void write(uint32_t idx, uint64_t bits); #else simdjson_inline void write(uint32_t idx, uint64_t bits) { @@ -10350,93 +28453,31 @@ namespace simdjson { // it helps tremendously. if (bits == 0) return; -#if SIMDJSON_PREFER_REVERSE_BITS - /** - * ARM lacks a fast trailing zero instruction, but it has a fast - * bit reversal instruction and a fast leading zero instruction. - * Thus it may be profitable to reverse the bits (once) and then - * to rely on a sequence of instructions that call the leading - * zero instruction. - * - * Performance notes: - * The chosen routine is not optimal in terms of data dependency - * since zero_leading_bit might require two instructions. However, - * it tends to minimize the total number of instructions which is - * beneficial. - */ - uint64_t rev_bits = reverse_bits(bits); int cnt = static_cast(count_ones(bits)); - int i = 0; - // Do the first 8 all together - for (; i < 8; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - i = 8; - for (; i < 16; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } +#if SIMDJSON_PREFER_REVERSE_BITS + bits = reverse_bits(bits); +#endif +#ifdef SIMDJSON_STRUCTURAL_INDEXER_STEP + static constexpr const int STEP = SIMDJSON_STRUCTURAL_INDEXER_STEP; +#else + static constexpr const int STEP = 4; +#endif + static constexpr const int STEP_UNTIL = 24; - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - i = 16; - while (rev_bits != 0) { - int lz = leading_zeroes(rev_bits); - this->tail[i++] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); + write_indexes_stepped<0, STEP_UNTIL, STEP>(idx, bits, cnt); + SIMDJSON_IF_CONSTEXPR(STEP_UNTIL < 64) { + if (simdjson_unlikely(STEP_UNTIL < cnt)) { + for (int i = STEP_UNTIL; i < cnt; i++) { + write_index(idx, bits, i); } } } - this->tail += cnt; -#else // SIMDJSON_PREFER_REVERSE_BITS - /** - * Under recent x64 systems, we often have both a fast trailing zero - * instruction and a fast 'clear-lower-bit' instruction so the following - * algorithm can be competitive. - */ - - int cnt = static_cast(count_ones(bits)); - // Do the first 8 all together - for (int i = 0; i < 8; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - for (int i = 8; i < 16; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - int i = 16; - do { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - i++; - } while (i < cnt); - } - } this->tail += cnt; -#endif } -#endif // SIMDJSON_CUSTOM_BIT_INDEXER +#endif // SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER }; @@ -10667,12 +28708,27 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage1/json_structural_indexer.h */ -/* begin file src/generic/stage1/utf8_validator.h */ + +// Clear CUSTOM_BIT_INDEXER so other implementations can set it if they need to. +#undef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H +/* end file generic/stage1/json_structural_indexer.h for icelake */ +/* including generic/stage1/utf8_validator.h for icelake: #include */ +/* begin file generic/stage1/utf8_validator.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace haswell { + namespace icelake { namespace { namespace stage1 { @@ -10703,267 +28759,177 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage1/utf8_validator.h */ -// -// Stage 2 -// -/* begin file src/generic/stage2/stringparsing.h */ -// This file contains the common code every implementation uses -// It is intended to be included multiple times and compiled multiple times +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H +/* end file generic/stage1/utf8_validator.h for icelake */ +/* end file generic/stage1/amalgamated.h for icelake */ +/* including generic/stage2/amalgamated.h for icelake: #include */ +/* begin file generic/stage2/amalgamated.h for icelake */ +// Stuff other things depend on +/* including generic/stage2/base.h for icelake: #include */ +/* begin file generic/stage2/base.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace haswell { + namespace icelake { namespace { - /// @private - namespace stringparsing { + namespace stage2 { - // begin copypasta - // These chars yield themselves: " \ / - // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab - // u not handled in this table as it's complex - static const uint8_t escape_map[256] = { - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + class json_iterator; + class structural_iterator; + struct tape_builder; + struct tape_writer; - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. - 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. - 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - }; - - // handle a unicode codepoint - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, - uint8_t** dst_ptr, bool allow_replacement) { - // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) - constexpr uint32_t substitution_code_point = 0xfffd; - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - - // We have already checked that the high surrogate is valid and - // (code_point - 0xd800) < 1024. - // - // Check that code_point_2 is in the range 0xdc00..0xdfff - // and that code_point_2 was parsed from valid hex. - uint32_t low_bit = code_point_2 - 0xdc00; - if (low_bit >> 10) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - - } - } - else if (code_point >= 0xdc00 && code_point <= 0xdfff) { - // If we encounter a low surrogate (not preceded by a high surrogate) - // then we have an error. - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - // handle a unicode codepoint using the wobbly convention - // https://simonsapin.github.io/wtf-8/ - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, - uint8_t** dst_ptr) { - // It is not ideal that this function is nearly identical to handle_unicode_codepoint. - // - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - uint32_t low_bit = code_point_2 - 0xdc00; - if ((low_bit >> 10) == 0) { - code_point = - (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - } - } - - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - /** - * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There - * must be an unescaped quote terminating the string. It returns the final output - * position as pointer. In case of error (e.g., the string has bad escaped codes), - * then null_nullptrptr is returned. It is assumed that the output buffer is large - * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + - * SIMDJSON_PADDING bytes. - */ - simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { - // It is not ideal that this function is nearly identical to parse_string. - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint_wobbly(&src, &dst)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - } // namespace stringparsing + } // namespace stage2 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage2/stringparsing.h */ -/* begin file src/generic/stage2/tape_builder.h */ -/* begin file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_BASE_H +/* end file generic/stage2/base.h for icelake */ +/* including generic/stage2/tape_writer.h for icelake: #include */ +/* begin file generic/stage2/tape_writer.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace icelake { + namespace { + namespace stage2 { + + struct tape_writer { + /** The next place to write to tape */ + uint64_t* next_tape_loc; + + /** Write a signed 64-bit value to tape. */ + simdjson_inline void append_s64(int64_t value) noexcept; + + /** Write an unsigned 64-bit value to tape. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + + /** Write a double value to tape. */ + simdjson_inline void append_double(double value) noexcept; + + /** + * Append a tape entry (an 8-bit type,and 56 bits worth of value). + */ + simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; + + /** + * Skip the current tape entry without writing. + * + * Used to skip the start of the container, since we'll come back later to fill it in when the + * container ends. + */ + simdjson_inline void skip() noexcept; + + /** + * Skip the number of tape entries necessary to write a large u64 or i64. + */ + simdjson_inline void skip_large_integer() noexcept; + + /** + * Skip the number of tape entries necessary to write a double. + */ + simdjson_inline void skip_double() noexcept; + + /** + * Write a value to a known location on tape. + * + * Used to go back and write out the start of a container after the container ends. + */ + simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; + + private: + /** + * Append both the tape entry, and a supplementary value following it. Used for types that need + * all 64 bits, such as double and uint64_t. + */ + template + simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; + }; // struct tape_writer + + simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { + append2(0, value, internal::tape_type::INT64); + } + + simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { + append(0, internal::tape_type::UINT64); + *next_tape_loc = value; + next_tape_loc++; + } + + /** Write a double value to tape. */ + simdjson_inline void tape_writer::append_double(double value) noexcept { + append2(0, value, internal::tape_type::DOUBLE); + } + + simdjson_inline void tape_writer::skip() noexcept { + next_tape_loc++; + } + + simdjson_inline void tape_writer::skip_large_integer() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::skip_double() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { + *next_tape_loc = val | ((uint64_t(char(t))) << 56); + next_tape_loc++; + } + + template + simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { + append(val, t); + static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); + memcpy(next_tape_loc, &val2, sizeof(val2)); + next_tape_loc++; + } + + simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { + tape_loc = val | ((uint64_t(char(t))) << 56); + } + + } // namespace stage2 + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H +/* end file generic/stage2/tape_writer.h for icelake */ +/* including generic/stage2/logger.h for icelake: #include */ +/* begin file generic/stage2/logger.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + + // This is for an internal-only stage 2 specific logger. // Set LOG_ENABLED = true to log what stage 2 is doing! namespace simdjson { - namespace haswell { + namespace icelake { namespace { namespace logger { @@ -11048,12 +29014,26 @@ namespace simdjson { } // namespace logger } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H +/* end file generic/stage2/logger.h for icelake */ + +// All other declarations +/* including generic/stage2/json_iterator.h for icelake: #include */ +/* begin file generic/stage2/json_iterator.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace haswell { + namespace icelake { namespace { namespace stage2 { @@ -11348,15 +29328,18 @@ namespace simdjson { } template simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { + // Use the fact that most scalars are going to be either strings or numbers. + if (*value == '"') { + return visitor.visit_string(*this, value); + } + else if (((*value - '0') < 10) || (*value == '-')) { + return visitor.visit_number(*this, value); + } + // true, false, null are uncommon. switch (*value) { - case '"': return visitor.visit_string(*this, value); case 't': return visitor.visit_true_atom(*this, value); case 'f': return visitor.visit_false_atom(*this, value); case 'n': return visitor.visit_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_number(*this, value); default: log_error("Non-value found when value was expected!"); return TAPE_ERROR; @@ -11365,119 +29348,351 @@ namespace simdjson { } // namespace stage2 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H +/* end file generic/stage2/json_iterator.h for icelake */ +/* including generic/stage2/stringparsing.h for icelake: #include */ +/* begin file generic/stage2/stringparsing.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses +// It is intended to be included multiple times and compiled multiple times + namespace simdjson { - namespace haswell { + namespace icelake { + namespace { + /// @private + namespace stringparsing { + + // begin copypasta + // These chars yield themselves: " \ / + // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab + // u not handled in this table as it's complex + static const uint8_t escape_map[256] = { + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. + 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. + 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + }; + + // handle a unicode codepoint + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, + uint8_t** dst_ptr, bool allow_replacement) { + // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) + constexpr uint32_t substitution_code_point = 0xfffd; + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + + // We have already checked that the high surrogate is valid and + // (code_point - 0xd800) < 1024. + // + // Check that code_point_2 is in the range 0xdc00..0xdfff + // and that code_point_2 was parsed from valid hex. + uint32_t low_bit = code_point_2 - 0xdc00; + if (low_bit >> 10) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + + } + } + else if (code_point >= 0xdc00 && code_point <= 0xdfff) { + // If we encounter a low surrogate (not preceded by a high surrogate) + // then we have an error. + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + // handle a unicode codepoint using the wobbly convention + // https://simonsapin.github.io/wtf-8/ + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, + uint8_t** dst_ptr) { + // It is not ideal that this function is nearly identical to handle_unicode_codepoint. + // + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + uint32_t low_bit = code_point_2 - 0xdc00; + if ((low_bit >> 10) == 0) { + code_point = + (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + } + } + + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + /** + * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + */ + simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { + // It is not ideal that this function is nearly identical to parse_string. + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint_wobbly(&src, &dst)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + } // namespace stringparsing + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H +/* end file generic/stage2/stringparsing.h for icelake */ +/* including generic/stage2/structural_iterator.h for icelake: #include */ +/* begin file generic/stage2/structural_iterator.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { namespace { namespace stage2 { - struct tape_writer { - /** The next place to write to tape */ - uint64_t* next_tape_loc; + class structural_iterator { + public: + const uint8_t* const buf; + uint32_t* next_structural; + dom_parser_implementation& dom_parser; - /** Write a signed 64-bit value to tape. */ - simdjson_inline void append_s64(int64_t value) noexcept; + // Start a structural + simdjson_inline structural_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) + : buf{ _dom_parser.buf }, + next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, + dom_parser{ _dom_parser } { + } + // Get the buffer position of the current structural character + simdjson_inline const uint8_t* current() { + return &buf[*(next_structural - 1)]; + } + // Get the current structural character + simdjson_inline char current_char() { + return buf[*(next_structural - 1)]; + } + // Get the next structural character without advancing + simdjson_inline char peek_next_char() { + return buf[*next_structural]; + } + simdjson_inline const uint8_t* peek() { + return &buf[*next_structural]; + } + simdjson_inline const uint8_t* advance() { + return &buf[*(next_structural++)]; + } + simdjson_inline char advance_char() { + return buf[*(next_structural++)]; + } + simdjson_inline size_t remaining_len() { + return dom_parser.len - *(next_structural - 1); + } - /** Write an unsigned 64-bit value to tape. */ - simdjson_inline void append_u64(uint64_t value) noexcept; - - /** Write a double value to tape. */ - simdjson_inline void append_double(double value) noexcept; - - /** - * Append a tape entry (an 8-bit type,and 56 bits worth of value). - */ - simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; - - /** - * Skip the current tape entry without writing. - * - * Used to skip the start of the container, since we'll come back later to fill it in when the - * container ends. - */ - simdjson_inline void skip() noexcept; - - /** - * Skip the number of tape entries necessary to write a large u64 or i64. - */ - simdjson_inline void skip_large_integer() noexcept; - - /** - * Skip the number of tape entries necessary to write a double. - */ - simdjson_inline void skip_double() noexcept; - - /** - * Write a value to a known location on tape. - * - * Used to go back and write out the start of a container after the container ends. - */ - simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; - - private: - /** - * Append both the tape entry, and a supplementary value following it. Used for types that need - * all 64 bits, such as double and uint64_t. - */ - template - simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; - }; // struct number_writer - - simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { - append2(0, value, internal::tape_type::INT64); - } - - simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { - append(0, internal::tape_type::UINT64); - *next_tape_loc = value; - next_tape_loc++; - } - - /** Write a double value to tape. */ - simdjson_inline void tape_writer::append_double(double value) noexcept { - append2(0, value, internal::tape_type::DOUBLE); - } - - simdjson_inline void tape_writer::skip() noexcept { - next_tape_loc++; - } - - simdjson_inline void tape_writer::skip_large_integer() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::skip_double() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { - *next_tape_loc = val | ((uint64_t(char(t))) << 56); - next_tape_loc++; - } - - template - simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { - append(val, t); - static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); - memcpy(next_tape_loc, &val2, sizeof(val2)); - next_tape_loc++; - } - - simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { - tape_loc = val | ((uint64_t(char(t))) << 56); - } + simdjson_inline bool at_end() { + return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; + } + simdjson_inline bool at_beginning() { + return next_structural == dom_parser.structural_indexes.get(); + } + }; } // namespace stage2 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H +/* end file generic/stage2/structural_iterator.h for icelake */ +/* including generic/stage2/tape_builder.h for icelake: #include */ +/* begin file generic/stage2/tape_builder.h for icelake */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace haswell { + namespace icelake { namespace { namespace stage2 { @@ -11556,7 +29771,7 @@ namespace simdjson { simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; simdjson_inline void on_end_string(uint8_t* dst) noexcept; - }; // class tape_builder + }; // struct tape_builder template simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( @@ -11754,38 +29969,187 @@ namespace simdjson { } // namespace stage2 } // unnamed namespace - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* end file src/generic/stage2/tape_builder.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H +/* end file generic/stage2/tape_builder.h for icelake */ +/* end file generic/stage2/amalgamated.h for icelake */ + +#undef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + +// +// Stage 1 +// + +namespace simdjson { + namespace icelake { + + simdjson_warn_unused error_code implementation::create_dom_parser_implementation( + size_t capacity, + size_t max_depth, + std::unique_ptr& dst + ) const noexcept { + dst.reset(new (std::nothrow) dom_parser_implementation()); + if (!dst) { return MEMALLOC; } + if (auto err = dst->set_capacity(capacity)) + return err; + if (auto err = dst->set_max_depth(max_depth)) + return err; + return SUCCESS; + } + + namespace { + + using namespace simd; + + // This identifies structural characters (comma, colon, braces, brackets), + // and ASCII white-space ('\r','\n','\t',' '). + simdjson_inline json_character_block json_character_block::classify(const simd::simd8x64& in) { + // These lookups rely on the fact that anything < 127 will match the lower 4 bits, which is why + // we can't use the generic lookup_16. + const auto whitespace_table = simd8::repeat_16(' ', 100, 100, 100, 17, 100, 113, 2, 100, '\t', '\n', 112, 100, '\r', 100, 100); + + // The 6 operators (:,[]{}) have these values: + // + // , 2C + // : 3A + // [ 5B + // { 7B + // ] 5D + // } 7D + // + // If you use | 0x20 to turn [ and ] into { and }, the lower 4 bits of each character is unique. + // We exploit this, using a simd 4-bit lookup to tell us which character match against, and then + // match it (against | 0x20). + // + // To prevent recognizing other characters, everything else gets compared with 0, which cannot + // match due to the | 0x20. + // + // NOTE: Due to the | 0x20, this ALSO treats and (control characters 0C and 1A) like , + // and :. This gets caught in stage 2, which checks the actual character to ensure the right + // operators are in the right places. + const auto op_table = simd8::repeat_16( + 0, 0, 0, 0, + 0, 0, 0, 0, + 0, 0, ':', '{', // : = 3A, [ = 5B, { = 7B + ',', '}', 0, 0 // , = 2C, ] = 5D, } = 7D + ); + + // We compute whitespace and op separately. If later code only uses one or the + // other, given the fact that all functions are aggressively inlined, we can + // hope that useless computations will be omitted. This is namely case when + // minifying (we only need whitespace). + + const uint64_t whitespace = in.eq({ + _mm512_shuffle_epi8(whitespace_table, in.chunks[0]) + }); + // Turn [ and ] into { and } + const simd8x64 curlified{ + in.chunks[0] | 0x20 + }; + const uint64_t op = curlified.eq({ + _mm512_shuffle_epi8(op_table, in.chunks[0]) + }); + + return { whitespace, op }; + } + + simdjson_inline bool is_ascii(const simd8x64& input) { + return input.reduce_or().is_ascii(); + } + + simdjson_unused simdjson_inline simd8 must_be_continuation(const simd8 prev1, const simd8 prev2, const simd8 prev3) { + simd8 is_second_byte = prev1.saturating_sub(0xc0u - 1); // Only 11______ will be > 0 + simd8 is_third_byte = prev2.saturating_sub(0xe0u - 1); // Only 111_____ will be > 0 + simd8 is_fourth_byte = prev3.saturating_sub(0xf0u - 1); // Only 1111____ will be > 0 + // Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine. + return simd8(is_second_byte | is_third_byte | is_fourth_byte) > int8_t(0); + } + + simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3) { + simd8 is_third_byte = prev2.saturating_sub(0xe0u - 1); // Only 111_____ will be > 0 + simd8 is_fourth_byte = prev3.saturating_sub(0xf0u - 1); // Only 1111____ will be > 0 + // Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine. + return simd8(is_third_byte | is_fourth_byte) > int8_t(0); + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +/** + * We provide a custom version of bit_indexer::write using + * naked intrinsics. + * TODO: make this code more elegant. + */ + // Under GCC 12, the intrinsic _mm512_extracti32x4_epi32 may generate 'maybe uninitialized'. + // as a workaround, we disable warnings within the following function. +SIMDJSON_PUSH_DISABLE_ALL_WARNINGS +namespace simdjson { + namespace icelake { + namespace { + namespace stage1 { + simdjson_inline void bit_indexer::write(uint32_t idx, uint64_t bits) { + // In some instances, the next branch is expensive because it is mispredicted. + // Unfortunately, in other cases, + // it helps tremendously. + if (bits == 0) { return; } + + const __m512i indexes = _mm512_maskz_compress_epi8(bits, _mm512_set_epi32( + 0x3f3e3d3c, 0x3b3a3938, 0x37363534, 0x33323130, + 0x2f2e2d2c, 0x2b2a2928, 0x27262524, 0x23222120, + 0x1f1e1d1c, 0x1b1a1918, 0x17161514, 0x13121110, + 0x0f0e0d0c, 0x0b0a0908, 0x07060504, 0x03020100 + )); + const __m512i start_index = _mm512_set1_epi32(idx); + + const auto count = count_ones(bits); + __m512i t0 = _mm512_cvtepu8_epi32(_mm512_castsi512_si128(indexes)); + _mm512_storeu_si512(this->tail, _mm512_add_epi32(t0, start_index)); + + if (count > 16) { + const __m512i t1 = _mm512_cvtepu8_epi32(_mm512_extracti32x4_epi32(indexes, 1)); + _mm512_storeu_si512(this->tail + 16, _mm512_add_epi32(t1, start_index)); + if (count > 32) { + const __m512i t2 = _mm512_cvtepu8_epi32(_mm512_extracti32x4_epi32(indexes, 2)); + _mm512_storeu_si512(this->tail + 32, _mm512_add_epi32(t2, start_index)); + if (count > 48) { + const __m512i t3 = _mm512_cvtepu8_epi32(_mm512_extracti32x4_epi32(indexes, 3)); + _mm512_storeu_si512(this->tail + 48, _mm512_add_epi32(t3, start_index)); + } + } + } + this->tail += count; + } + } + } + } +} +SIMDJSON_POP_DISABLE_WARNINGS + +// +// Stage 2 +// // // Implementation-specific overrides // namespace simdjson { - namespace haswell { - namespace { - namespace stage1 { - - simdjson_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) { - if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; } - return find_escaped_branchless(backslash); - } - - } // namespace stage1 - } // unnamed namespace + namespace icelake { simdjson_warn_unused error_code implementation::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept { - return haswell::stage1::json_minifier::minify<128>(buf, len, dst, dst_len); + return icelake::stage1::json_minifier::minify<128>(buf, len, dst, dst_len); } simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t* _buf, size_t _len, stage1_mode streaming) noexcept { this->buf = _buf; this->len = _len; - return haswell::stage1::json_structural_indexer::index<128>(_buf, _len, *this, streaming); + return icelake::stage1::json_structural_indexer::index<128>(_buf, _len, *this, streaming); } simdjson_warn_unused bool implementation::validate_utf8(const char* buf, size_t len) const noexcept { - return haswell::stage1::generic_validate_utf8(buf, len); + return icelake::stage1::generic_validate_utf8(buf, len); } simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document& _doc) noexcept { @@ -11797,11 +30161,11 @@ namespace simdjson { } simdjson_warn_unused uint8_t* dom_parser_implementation::parse_string(const uint8_t* src, uint8_t* dst, bool replacement_char) const noexcept { - return haswell::stringparsing::parse_string(src, dst, replacement_char); + return icelake::stringparsing::parse_string(src, dst, replacement_char); } simdjson_warn_unused uint8_t* dom_parser_implementation::parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept { - return haswell::stringparsing::parse_wobbly_string(src, dst); + return icelake::stringparsing::parse_wobbly_string(src, dst); } simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t* _buf, size_t _len, dom::document& _doc) noexcept { @@ -11810,21 +30174,6286 @@ namespace simdjson { return stage2(_doc); } - } // namespace haswell + } // namespace icelake } // namespace simdjson -/* begin file include/simdjson/haswell/end.h */ -SIMDJSON_UNTARGET_HASWELL -/* end file include/simdjson/haswell/end.h */ -/* end file src/haswell/dom_parser_implementation.cpp */ +/* including simdjson/icelake/end.h: #include */ +/* begin file simdjson/icelake/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "icelake" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/icelake/end.h */ + +#endif // SIMDJSON_SRC_ICELAKE_CPP +/* end file icelake.cpp */ #endif #if SIMDJSON_IMPLEMENTATION_PPC64 -/* begin file src/ppc64/implementation.cpp */ -/* begin file include/simdjson/ppc64/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "ppc64" -// #define SIMDJSON_IMPLEMENTATION ppc64 -/* end file include/simdjson/ppc64/begin.h */ +/* including ppc64.cpp: #include */ +/* begin file ppc64.cpp */ +#ifndef SIMDJSON_SRC_PPC64_CPP +#define SIMDJSON_SRC_PPC64_CPP +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* including simdjson/ppc64.h: #include */ +/* begin file simdjson/ppc64.h */ +#ifndef SIMDJSON_PPC64_H +#define SIMDJSON_PPC64_H + +/* including simdjson/ppc64/begin.h: #include "simdjson/ppc64/begin.h" */ +/* begin file simdjson/ppc64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "ppc64" */ +#define SIMDJSON_IMPLEMENTATION ppc64 +/* including simdjson/ppc64/base.h: #include "simdjson/ppc64/base.h" */ +/* begin file simdjson/ppc64/base.h */ +#ifndef SIMDJSON_PPC64_BASE_H +#define SIMDJSON_PPC64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for ALTIVEC (PPC64). + */ + namespace ppc64 { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_BASE_H +/* end file simdjson/ppc64/base.h */ +/* including simdjson/ppc64/intrinsics.h: #include "simdjson/ppc64/intrinsics.h" */ +/* begin file simdjson/ppc64/intrinsics.h */ +#ifndef SIMDJSON_PPC64_INTRINSICS_H +#define SIMDJSON_PPC64_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This should be the correct header whether +// you use visual studio or other compilers. +#include + +// These are defined by altivec.h in GCC toolchain, it is safe to undef them. +#ifdef bool +#undef bool +#endif + +#ifdef vector +#undef vector +#endif + +static_assert(sizeof(__vector unsigned char) <= simdjson::SIMDJSON_PADDING, "insufficient padding for ppc64"); + +#endif // SIMDJSON_PPC64_INTRINSICS_H +/* end file simdjson/ppc64/intrinsics.h */ +/* including simdjson/ppc64/bitmanipulation.h: #include "simdjson/ppc64/bitmanipulation.h" */ +/* begin file simdjson/ppc64/bitmanipulation.h */ +#ifndef SIMDJSON_PPC64_BITMANIPULATION_H +#define SIMDJSON_PPC64_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline int count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num); // Visual Studio wants two underscores + } +#else + simdjson_inline int count_ones(uint64_t input_num) { + return __builtin_popcountll(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + * result = value1 + value2; + return *result < value1; +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_BITMANIPULATION_H +/* end file simdjson/ppc64/bitmanipulation.h */ +/* including simdjson/ppc64/bitmask.h: #include "simdjson/ppc64/bitmask.h" */ +/* begin file simdjson/ppc64/bitmask.h */ +#ifndef SIMDJSON_PPC64_BITMASK_H +#define SIMDJSON_PPC64_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is + // encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(uint64_t bitmask) { + // You can use the version below, however gcc sometimes miscompiles + // vec_pmsum_be, it happens somewhere around between 8 and 9th version. + // The performance boost was not noticeable, falling back to a usual + // implementation. + // __vector unsigned long long all_ones = {~0ull, ~0ull}; + // __vector unsigned long long mask = {bitmask, 0}; + // // Clang and GCC return different values for pmsum for ull so cast it to one. + // // Generally it is not specified by ALTIVEC ISA what is returned by + // // vec_pmsum_be. + // #if defined(__LITTLE_ENDIAN__) + // return (uint64_t)(((__vector unsigned long long)vec_pmsum_be(all_ones, mask))[0]); + // #else + // return (uint64_t)(((__vector unsigned long long)vec_pmsum_be(all_ones, mask))[1]); + // #endif + bitmask ^= bitmask << 1; + bitmask ^= bitmask << 2; + bitmask ^= bitmask << 4; + bitmask ^= bitmask << 8; + bitmask ^= bitmask << 16; + bitmask ^= bitmask << 32; + return bitmask; + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif +/* end file simdjson/ppc64/bitmask.h */ +/* including simdjson/ppc64/numberparsing_defs.h: #include "simdjson/ppc64/numberparsing_defs.h" */ +/* begin file simdjson/ppc64/numberparsing_defs.h */ +#ifndef SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +#define SIMDJSON_PPC64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if defined(__linux__) +#include +#elif defined(__FreeBSD__) +#include +#endif + +namespace simdjson { + namespace ppc64 { + namespace numberparsing { + + // we don't have appropriate instructions, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); +#ifdef __BIG_ENDIAN__ +#if defined(__linux__) + val = bswap_64(val); +#elif defined(__FreeBSD__) + val = bswap64(val); +#endif +#endif + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace ppc64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +/* end file simdjson/ppc64/numberparsing_defs.h */ +/* including simdjson/ppc64/simd.h: #include "simdjson/ppc64/simd.h" */ +/* begin file simdjson/ppc64/simd.h */ +#ifndef SIMDJSON_PPC64_SIMD_H +#define SIMDJSON_PPC64_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace ppc64 { + namespace { + namespace simd { + + using __m128i = __vector unsigned char; + + template struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { + return this->value; + } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { + return vec_or(this->value, (__m128i)other); + } + simdjson_inline Child operator&(const Child other) const { + return vec_and(this->value, (__m128i)other); + } + simdjson_inline Child operator^(const Child other) const { + return vec_xor(this->value, (__m128i)other); + } + simdjson_inline Child bit_andnot(const Child other) const { + return vec_andc(this->value, (__m128i)other); + } + simdjson_inline Child& operator|=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast | other; + return *this_cast; + } + simdjson_inline Child& operator&=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast & other; + return *this_cast; + } + simdjson_inline Child& operator^=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast ^ other; + return *this_cast; + } + }; + + template > + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { + return (__m128i)vec_cmpeq(lhs.value, (__m128i)rhs); + } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(simd8 prev_chunk) const { + __m128i chunk = this->value; +#ifdef __LITTLE_ENDIAN__ + chunk = (__m128i)vec_reve(this->value); + prev_chunk = (__m128i)vec_reve((__m128i)prev_chunk); +#endif + chunk = (__m128i)vec_sld((__m128i)prev_chunk, (__m128i)chunk, 16 - N); +#ifdef __LITTLE_ENDIAN__ + chunk = (__m128i)vec_reve((__m128i)chunk); +#endif + return chunk; + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template <> struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { + return (__m128i)vec_splats((unsigned char)(-(!!_value))); + } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) + : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) + : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { + __vector unsigned long long result; + const __m128i perm_mask = { 0x78, 0x70, 0x68, 0x60, 0x58, 0x50, 0x48, 0x40, + 0x38, 0x30, 0x28, 0x20, 0x18, 0x10, 0x08, 0x00 }; + + result = ((__vector unsigned long long)vec_vbpermq((__m128i)this->value, + (__m128i)perm_mask)); +#ifdef __LITTLE_ENDIAN__ + return static_cast(result[1]); +#else + return static_cast(result[0]); +#endif + } + simdjson_inline bool any() const { + return !vec_all_eq(this->value, (__m128i)vec_splats(0)); + } + simdjson_inline simd8 operator~() const { + return this->value ^ (__m128i)splat(true); + } + }; + + template struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T value) { + (void)value; + return (__m128i)vec_splats(value); + } + static simdjson_inline simd8 zero() { return splat(0); } + static simdjson_inline simd8 load(const T values[16]) { + return (__m128i)(vec_vsx_ld(0, reinterpret_cast(values))); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16(T v0, T v1, T v2, T v3, T v4, + T v5, T v6, T v7, T v8, T v9, + T v10, T v11, T v12, T v13, + T v14, T v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, + v14, v15); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) + : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { + vec_vsx_st(this->value, 0, reinterpret_cast<__m128i*>(dst)); + } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { + return (__m128i)((__m128i)this->value + (__m128i)other); + } + simdjson_inline simd8 operator-(const simd8 other) const { + return (__m128i)((__m128i)this->value - (__m128i)other); + } + simdjson_inline simd8& operator+=(const simd8 other) { + *this = *this + other; + return *static_cast *>(this); + } + simdjson_inline simd8& operator-=(const simd8 other) { + *this = *this - other; + return *static_cast *>(this); + } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior + // for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return (__m128i)vec_perm((__m128i)lookup_table, (__m128i)lookup_table, this->value); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted + // as a bitset). Passing a 0 value for mask would be equivalent to writing out + // every byte to output. Only the first 16 - count_ones(mask) bytes of the + // result are significant but 16 bytes get written. Design consideration: it + // seems like a function with the signature simd8 compress(uint32_t mask) + // would be sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + using internal::thintable_epi8; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. +#ifdef __LITTLE_ENDIAN__ + __m128i shufmask = (__m128i)(__vector unsigned long long) { + thintable_epi8[mask1], thintable_epi8[mask2] + }; +#else + __m128i shufmask = (__m128i)(__vector unsigned long long) { + thintable_epi8[mask2], thintable_epi8[mask1] + }; + shufmask = (__m128i)vec_reve((__m128i)shufmask); +#endif + // we increment by 0x08 the second half of the mask + shufmask = ((__m128i)shufmask) + + ((__m128i)(__vector int) { 0, 0, 0x08080808, 0x08080808 }); + + // this is the version "nearly pruned" + __m128i pruned = vec_perm(this->value, this->value, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + vec_vsx_ld(0, reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = vec_perm(pruned, (__m128i)vec_splats(0), compactmask); + vec_vsx_st(answer, 0, reinterpret_cast<__m128i*>(output)); + } + + template + simdjson_inline simd8 + lookup_16(L replace0, L replace1, L replace2, L replace3, L replace4, + L replace5, L replace6, L replace7, L replace8, L replace9, + L replace10, L replace11, L replace12, L replace13, L replace14, + L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, replace4, replace5, replace6, + replace7, replace8, replace9, replace10, replace11, replace12, + replace13, replace14, replace15)); + } + }; + + // Signed bytes + template <> struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) + : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8(int8_t v0, int8_t v1, int8_t v2, int8_t v3, + int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, + int8_t v12, int8_t v13, int8_t v14, int8_t v15) + : simd8((__m128i)(__vector signed char) { + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, + v15 + }) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, + int8_t v6, int8_t v7, int8_t v8, int8_t v9, int8_t v10, int8_t v11, + int8_t v12, int8_t v13, int8_t v14, int8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } + + // Order-sensitive comparisons + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return (__m128i)vec_cmpgt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return (__m128i)vec_cmplt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + }; + + // Unsigned bytes + template <> struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) + : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline + simd8(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, + uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, uint8_t v10, + uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15) + : simd8((__m128i) { + v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15 + }) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, + uint8_t v5, uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, + uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, + uint8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } + + // Saturated math + simdjson_inline simd8 + saturating_add(const simd8 other) const { + return (__m128i)vec_adds(this->value, (__m128i)other); + } + simdjson_inline simd8 + saturating_sub(const simd8 other) const { + return (__m128i)vec_subs(this->value, (__m128i)other); + } + + // Order-specific operations + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max(this->value, (__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min(this->value, (__m128i)other); + } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + gt_bits(const simd8 other) const { + return this->saturating_sub(other); + } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + lt_bits(const simd8 other) const { + return other.saturating_sub(*this); + } + simdjson_inline simd8 + operator<=(const simd8 other) const { + return other.max_val(*this) == other; + } + simdjson_inline simd8 + operator>=(const simd8 other) const { + return other.min_val(*this) == other; + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { + return (__m128i)vec_cmpeq(this->value, (__m128i)vec_splats(uint8_t(0))); + } + simdjson_inline simd8 bits_not_set(simd8 bits) const { + return (*this & bits).bits_not_set(); + } + simdjson_inline simd8 any_bits_set() const { + return ~this->bits_not_set(); + } + simdjson_inline simd8 any_bits_set(simd8 bits) const { + return ~this->bits_not_set(bits); + } + simdjson_inline bool bits_not_set_anywhere() const { + return vec_all_eq(this->value, (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere() const { + return !bits_not_set_anywhere(); + } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { + return vec_all_eq(vec_and(this->value, (__m128i)bits), + (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { + return !bits_not_set_anywhere(bits); + } + template simdjson_inline simd8 shr() const { + return simd8( + (__m128i)vec_sr(this->value, (__m128i)vec_splat_u8(N))); + } + template simdjson_inline simd8 shl() const { + return simd8( + (__m128i)vec_sl(this->value, (__m128i)vec_splat_u8(N))); + } + }; + + template struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, + "PPC64 kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& + operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, + const simd8 chunk2, const simd8 chunk3) + : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) + : chunks{ simd8::load(ptr), simd8::load(ptr + 16), + simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | + (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), + output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), + output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), + output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64(this->chunks[0] == mask, this->chunks[1] == mask, + this->chunks[2] == mask, this->chunks[3] == mask) + .to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64(this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3]) + .to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64(this->chunks[0] <= mask, this->chunks[1] <= mask, + this->chunks[2] <= mask, this->chunks[3] <= mask) + .to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_SIMD_INPUT_H +/* end file simdjson/ppc64/simd.h */ +/* including simdjson/ppc64/stringparsing_defs.h: #include "simdjson/ppc64/stringparsing_defs.h" */ +/* begin file simdjson/ppc64/stringparsing_defs.h */ +#ifndef SIMDJSON_PPC64_STRINGPARSING_DEFS_H +#define SIMDJSON_PPC64_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/simd.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote + copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { + return ((bs_bits - 1) & quote_bits) != 0; + } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { + return trailing_zeroes(quote_bits); + } + simdjson_inline int backslash_index() { + return trailing_zeroes(bs_bits); + } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote + backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), + "backslash and quote finder must process fewer than " + "SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + sizeof(v0)); + v0.store(dst); + v1.store(dst + sizeof(v0)); + + // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on + // PPC; therefore, we smash them together into a 64-byte mask and get the + // bitmask from there. + uint64_t bs_and_quote = + simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_STRINGPARSING_DEFS_H +/* end file simdjson/ppc64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/ppc64/begin.h */ +/* including simdjson/generic/amalgamated.h for ppc64: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for ppc64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for ppc64: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for ppc64 */ +/* including simdjson/generic/jsoncharutils.h for ppc64: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace jsoncharutils { + + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for ppc64 */ +/* including simdjson/generic/atomparsing.h for ppc64: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace ppc64 { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for ppc64 */ +/* including simdjson/generic/dom_parser_implementation.h for ppc64: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container + + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); + + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; + + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; + + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; + + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + namespace ppc64 { + + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; + } + + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for ppc64 */ +/* including simdjson/generic/implementation_simdjson_result_base.h for ppc64: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); + + +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for ppc64 */ +/* including simdjson/generic/numberparsing.h for ppc64: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace ppc64 { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing +// +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. +// +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for ppc64 */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for ppc64: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for ppc64 */ +/* end file simdjson/generic/amalgamated.h for ppc64 */ +/* including simdjson/ppc64/end.h: #include "simdjson/ppc64/end.h" */ +/* begin file simdjson/ppc64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "ppc64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/ppc64/end.h */ + +#endif // SIMDJSON_PPC64_H +/* end file simdjson/ppc64.h */ +/* including simdjson/ppc64/implementation.h: #include */ +/* begin file simdjson/ppc64/implementation.h */ +#ifndef SIMDJSON_PPC64_IMPLEMENTATION_H +#define SIMDJSON_PPC64_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + /** + * Implementation for ALTIVEC (PPC64). + */ + namespace ppc64 { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() + : simdjson::implementation("ppc64", "PPC64 ALTIVEC", + internal::instruction_set::ALTIVEC) {} + + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, size_t max_length, + std::unique_ptr& dst) + const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, + uint8_t* dst, + size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, + size_t len) const noexcept final; + }; + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_IMPLEMENTATION_H +/* end file simdjson/ppc64/implementation.h */ + +/* including simdjson/ppc64/begin.h: #include */ +/* begin file simdjson/ppc64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "ppc64" */ +#define SIMDJSON_IMPLEMENTATION ppc64 +/* including simdjson/ppc64/base.h: #include "simdjson/ppc64/base.h" */ +/* begin file simdjson/ppc64/base.h */ +#ifndef SIMDJSON_PPC64_BASE_H +#define SIMDJSON_PPC64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for ALTIVEC (PPC64). + */ + namespace ppc64 { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_BASE_H +/* end file simdjson/ppc64/base.h */ +/* including simdjson/ppc64/intrinsics.h: #include "simdjson/ppc64/intrinsics.h" */ +/* begin file simdjson/ppc64/intrinsics.h */ +#ifndef SIMDJSON_PPC64_INTRINSICS_H +#define SIMDJSON_PPC64_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This should be the correct header whether +// you use visual studio or other compilers. +#include + +// These are defined by altivec.h in GCC toolchain, it is safe to undef them. +#ifdef bool +#undef bool +#endif + +#ifdef vector +#undef vector +#endif + +static_assert(sizeof(__vector unsigned char) <= simdjson::SIMDJSON_PADDING, "insufficient padding for ppc64"); + +#endif // SIMDJSON_PPC64_INTRINSICS_H +/* end file simdjson/ppc64/intrinsics.h */ +/* including simdjson/ppc64/bitmanipulation.h: #include "simdjson/ppc64/bitmanipulation.h" */ +/* begin file simdjson/ppc64/bitmanipulation.h */ +#ifndef SIMDJSON_PPC64_BITMANIPULATION_H +#define SIMDJSON_PPC64_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline int count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num); // Visual Studio wants two underscores + } +#else + simdjson_inline int count_ones(uint64_t input_num) { + return __builtin_popcountll(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + * result = value1 + value2; + return *result < value1; +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_BITMANIPULATION_H +/* end file simdjson/ppc64/bitmanipulation.h */ +/* including simdjson/ppc64/bitmask.h: #include "simdjson/ppc64/bitmask.h" */ +/* begin file simdjson/ppc64/bitmask.h */ +#ifndef SIMDJSON_PPC64_BITMASK_H +#define SIMDJSON_PPC64_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is + // encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(uint64_t bitmask) { + // You can use the version below, however gcc sometimes miscompiles + // vec_pmsum_be, it happens somewhere around between 8 and 9th version. + // The performance boost was not noticeable, falling back to a usual + // implementation. + // __vector unsigned long long all_ones = {~0ull, ~0ull}; + // __vector unsigned long long mask = {bitmask, 0}; + // // Clang and GCC return different values for pmsum for ull so cast it to one. + // // Generally it is not specified by ALTIVEC ISA what is returned by + // // vec_pmsum_be. + // #if defined(__LITTLE_ENDIAN__) + // return (uint64_t)(((__vector unsigned long long)vec_pmsum_be(all_ones, mask))[0]); + // #else + // return (uint64_t)(((__vector unsigned long long)vec_pmsum_be(all_ones, mask))[1]); + // #endif + bitmask ^= bitmask << 1; + bitmask ^= bitmask << 2; + bitmask ^= bitmask << 4; + bitmask ^= bitmask << 8; + bitmask ^= bitmask << 16; + bitmask ^= bitmask << 32; + return bitmask; + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif +/* end file simdjson/ppc64/bitmask.h */ +/* including simdjson/ppc64/numberparsing_defs.h: #include "simdjson/ppc64/numberparsing_defs.h" */ +/* begin file simdjson/ppc64/numberparsing_defs.h */ +#ifndef SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +#define SIMDJSON_PPC64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if defined(__linux__) +#include +#elif defined(__FreeBSD__) +#include +#endif + +namespace simdjson { + namespace ppc64 { + namespace numberparsing { + + // we don't have appropriate instructions, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); +#ifdef __BIG_ENDIAN__ +#if defined(__linux__) + val = bswap_64(val); +#elif defined(__FreeBSD__) + val = bswap64(val); +#endif +#endif + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace ppc64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +/* end file simdjson/ppc64/numberparsing_defs.h */ +/* including simdjson/ppc64/simd.h: #include "simdjson/ppc64/simd.h" */ +/* begin file simdjson/ppc64/simd.h */ +#ifndef SIMDJSON_PPC64_SIMD_H +#define SIMDJSON_PPC64_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace ppc64 { + namespace { + namespace simd { + + using __m128i = __vector unsigned char; + + template struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { + return this->value; + } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { + return vec_or(this->value, (__m128i)other); + } + simdjson_inline Child operator&(const Child other) const { + return vec_and(this->value, (__m128i)other); + } + simdjson_inline Child operator^(const Child other) const { + return vec_xor(this->value, (__m128i)other); + } + simdjson_inline Child bit_andnot(const Child other) const { + return vec_andc(this->value, (__m128i)other); + } + simdjson_inline Child& operator|=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast | other; + return *this_cast; + } + simdjson_inline Child& operator&=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast & other; + return *this_cast; + } + simdjson_inline Child& operator^=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast ^ other; + return *this_cast; + } + }; + + template > + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { + return (__m128i)vec_cmpeq(lhs.value, (__m128i)rhs); + } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(simd8 prev_chunk) const { + __m128i chunk = this->value; +#ifdef __LITTLE_ENDIAN__ + chunk = (__m128i)vec_reve(this->value); + prev_chunk = (__m128i)vec_reve((__m128i)prev_chunk); +#endif + chunk = (__m128i)vec_sld((__m128i)prev_chunk, (__m128i)chunk, 16 - N); +#ifdef __LITTLE_ENDIAN__ + chunk = (__m128i)vec_reve((__m128i)chunk); +#endif + return chunk; + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template <> struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { + return (__m128i)vec_splats((unsigned char)(-(!!_value))); + } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) + : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) + : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { + __vector unsigned long long result; + const __m128i perm_mask = { 0x78, 0x70, 0x68, 0x60, 0x58, 0x50, 0x48, 0x40, + 0x38, 0x30, 0x28, 0x20, 0x18, 0x10, 0x08, 0x00 }; + + result = ((__vector unsigned long long)vec_vbpermq((__m128i)this->value, + (__m128i)perm_mask)); +#ifdef __LITTLE_ENDIAN__ + return static_cast(result[1]); +#else + return static_cast(result[0]); +#endif + } + simdjson_inline bool any() const { + return !vec_all_eq(this->value, (__m128i)vec_splats(0)); + } + simdjson_inline simd8 operator~() const { + return this->value ^ (__m128i)splat(true); + } + }; + + template struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T value) { + (void)value; + return (__m128i)vec_splats(value); + } + static simdjson_inline simd8 zero() { return splat(0); } + static simdjson_inline simd8 load(const T values[16]) { + return (__m128i)(vec_vsx_ld(0, reinterpret_cast(values))); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16(T v0, T v1, T v2, T v3, T v4, + T v5, T v6, T v7, T v8, T v9, + T v10, T v11, T v12, T v13, + T v14, T v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, + v14, v15); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) + : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { + vec_vsx_st(this->value, 0, reinterpret_cast<__m128i*>(dst)); + } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { + return (__m128i)((__m128i)this->value + (__m128i)other); + } + simdjson_inline simd8 operator-(const simd8 other) const { + return (__m128i)((__m128i)this->value - (__m128i)other); + } + simdjson_inline simd8& operator+=(const simd8 other) { + *this = *this + other; + return *static_cast *>(this); + } + simdjson_inline simd8& operator-=(const simd8 other) { + *this = *this - other; + return *static_cast *>(this); + } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior + // for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return (__m128i)vec_perm((__m128i)lookup_table, (__m128i)lookup_table, this->value); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted + // as a bitset). Passing a 0 value for mask would be equivalent to writing out + // every byte to output. Only the first 16 - count_ones(mask) bytes of the + // result are significant but 16 bytes get written. Design consideration: it + // seems like a function with the signature simd8 compress(uint32_t mask) + // would be sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + using internal::thintable_epi8; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. +#ifdef __LITTLE_ENDIAN__ + __m128i shufmask = (__m128i)(__vector unsigned long long) { + thintable_epi8[mask1], thintable_epi8[mask2] + }; +#else + __m128i shufmask = (__m128i)(__vector unsigned long long) { + thintable_epi8[mask2], thintable_epi8[mask1] + }; + shufmask = (__m128i)vec_reve((__m128i)shufmask); +#endif + // we increment by 0x08 the second half of the mask + shufmask = ((__m128i)shufmask) + + ((__m128i)(__vector int) { 0, 0, 0x08080808, 0x08080808 }); + + // this is the version "nearly pruned" + __m128i pruned = vec_perm(this->value, this->value, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + vec_vsx_ld(0, reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = vec_perm(pruned, (__m128i)vec_splats(0), compactmask); + vec_vsx_st(answer, 0, reinterpret_cast<__m128i*>(output)); + } + + template + simdjson_inline simd8 + lookup_16(L replace0, L replace1, L replace2, L replace3, L replace4, + L replace5, L replace6, L replace7, L replace8, L replace9, + L replace10, L replace11, L replace12, L replace13, L replace14, + L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, replace4, replace5, replace6, + replace7, replace8, replace9, replace10, replace11, replace12, + replace13, replace14, replace15)); + } + }; + + // Signed bytes + template <> struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) + : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8(int8_t v0, int8_t v1, int8_t v2, int8_t v3, + int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, + int8_t v12, int8_t v13, int8_t v14, int8_t v15) + : simd8((__m128i)(__vector signed char) { + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, + v15 + }) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, + int8_t v6, int8_t v7, int8_t v8, int8_t v9, int8_t v10, int8_t v11, + int8_t v12, int8_t v13, int8_t v14, int8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } + + // Order-sensitive comparisons + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return (__m128i)vec_cmpgt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return (__m128i)vec_cmplt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + }; + + // Unsigned bytes + template <> struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) + : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline + simd8(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, + uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, uint8_t v10, + uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15) + : simd8((__m128i) { + v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15 + }) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, + uint8_t v5, uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, + uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, + uint8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } + + // Saturated math + simdjson_inline simd8 + saturating_add(const simd8 other) const { + return (__m128i)vec_adds(this->value, (__m128i)other); + } + simdjson_inline simd8 + saturating_sub(const simd8 other) const { + return (__m128i)vec_subs(this->value, (__m128i)other); + } + + // Order-specific operations + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max(this->value, (__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min(this->value, (__m128i)other); + } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + gt_bits(const simd8 other) const { + return this->saturating_sub(other); + } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + lt_bits(const simd8 other) const { + return other.saturating_sub(*this); + } + simdjson_inline simd8 + operator<=(const simd8 other) const { + return other.max_val(*this) == other; + } + simdjson_inline simd8 + operator>=(const simd8 other) const { + return other.min_val(*this) == other; + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { + return (__m128i)vec_cmpeq(this->value, (__m128i)vec_splats(uint8_t(0))); + } + simdjson_inline simd8 bits_not_set(simd8 bits) const { + return (*this & bits).bits_not_set(); + } + simdjson_inline simd8 any_bits_set() const { + return ~this->bits_not_set(); + } + simdjson_inline simd8 any_bits_set(simd8 bits) const { + return ~this->bits_not_set(bits); + } + simdjson_inline bool bits_not_set_anywhere() const { + return vec_all_eq(this->value, (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere() const { + return !bits_not_set_anywhere(); + } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { + return vec_all_eq(vec_and(this->value, (__m128i)bits), + (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { + return !bits_not_set_anywhere(bits); + } + template simdjson_inline simd8 shr() const { + return simd8( + (__m128i)vec_sr(this->value, (__m128i)vec_splat_u8(N))); + } + template simdjson_inline simd8 shl() const { + return simd8( + (__m128i)vec_sl(this->value, (__m128i)vec_splat_u8(N))); + } + }; + + template struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, + "PPC64 kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& + operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, + const simd8 chunk2, const simd8 chunk3) + : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) + : chunks{ simd8::load(ptr), simd8::load(ptr + 16), + simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | + (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), + output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), + output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), + output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64(this->chunks[0] == mask, this->chunks[1] == mask, + this->chunks[2] == mask, this->chunks[3] == mask) + .to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64(this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3]) + .to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64(this->chunks[0] <= mask, this->chunks[1] <= mask, + this->chunks[2] <= mask, this->chunks[3] <= mask) + .to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_SIMD_INPUT_H +/* end file simdjson/ppc64/simd.h */ +/* including simdjson/ppc64/stringparsing_defs.h: #include "simdjson/ppc64/stringparsing_defs.h" */ +/* begin file simdjson/ppc64/stringparsing_defs.h */ +#ifndef SIMDJSON_PPC64_STRINGPARSING_DEFS_H +#define SIMDJSON_PPC64_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/simd.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote + copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { + return ((bs_bits - 1) & quote_bits) != 0; + } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { + return trailing_zeroes(quote_bits); + } + simdjson_inline int backslash_index() { + return trailing_zeroes(bs_bits); + } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote + backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), + "backslash and quote finder must process fewer than " + "SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + sizeof(v0)); + v0.store(dst); + v1.store(dst + sizeof(v0)); + + // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on + // PPC; therefore, we smash them together into a 64-byte mask and get the + // bitmask from there. + uint64_t bs_and_quote = + simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_STRINGPARSING_DEFS_H +/* end file simdjson/ppc64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/ppc64/begin.h */ +/* including generic/amalgamated.h for ppc64: #include */ +/* begin file generic/amalgamated.h for ppc64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_SRC_GENERIC_DEPENDENCIES_H) +#error generic/dependencies.h must be included before generic/amalgamated.h! +#endif + +/* including generic/base.h for ppc64: #include */ +/* begin file generic/base.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + struct json_character_block; + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_BASE_H +/* end file generic/base.h for ppc64 */ +/* including generic/dom_parser_implementation.h for ppc64: #include */ +/* begin file generic/dom_parser_implementation.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// Interface a dom parser implementation must fulfill +namespace simdjson { + namespace ppc64 { + namespace { + + simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3); + simdjson_inline bool is_ascii(const simd8x64& input); + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file generic/dom_parser_implementation.h for ppc64 */ +/* including generic/json_character_block.h for ppc64: #include */ +/* begin file generic/json_character_block.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + struct json_character_block { + static simdjson_inline json_character_block classify(const simd::simd8x64& in); + + simdjson_inline uint64_t whitespace() const noexcept { return _whitespace; } + simdjson_inline uint64_t op() const noexcept { return _op; } + simdjson_inline uint64_t scalar() const noexcept { return ~(op() | whitespace()); } + + uint64_t _whitespace; + uint64_t _op; + }; + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H +/* end file generic/json_character_block.h for ppc64 */ +/* end file generic/amalgamated.h for ppc64 */ +/* including generic/stage1/amalgamated.h for ppc64: #include */ +/* begin file generic/stage1/amalgamated.h for ppc64 */ +// Stuff other things depend on +/* including generic/stage1/base.h for ppc64: #include */ +/* begin file generic/stage1/base.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + class bit_indexer; + template + struct buf_block_reader; + struct json_block; + class json_minifier; + class json_scanner; + struct json_string_block; + class json_string_scanner; + class json_structural_indexer; + + } // namespace stage1 + + namespace utf8_validation { + struct utf8_checker; + } // namespace utf8_validation + + using utf8_validation::utf8_checker; + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BASE_H +/* end file generic/stage1/base.h for ppc64 */ +/* including generic/stage1/buf_block_reader.h for ppc64: #include */ +/* begin file generic/stage1/buf_block_reader.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + // Walks through a buffer in block-sized increments, loading the last part with spaces + template + struct buf_block_reader { + public: + simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); + simdjson_inline size_t block_index(); + simdjson_inline bool has_full_block() const; + simdjson_inline const uint8_t* full_block() const; + /** + * Get the last block, padded with spaces. + * + * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this + * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there + * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. + * + * @return the number of effective characters in the last block. + */ + simdjson_inline size_t get_remainder(uint8_t* dst) const; + simdjson_inline void advance(); + private: + const uint8_t* buf; + const size_t len; + const size_t lenminusstep; + size_t idx; + }; + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text_64(const uint8_t* text) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < sizeof(simd8x64); i++) { + buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text(const simd8x64& in) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] < ' ') { buf[i] = '_'; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_input_text(const simd8x64& in, uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] <= ' ') { buf[i] = '_'; } + if (!(mask & (size_t(1) << i))) { buf[i] = ' '; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_mask(uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < 64; i++) { + buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; + } + buf[64] = '\0'; + return buf; + } + + template + simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} + + template + simdjson_inline size_t buf_block_reader::block_index() { return idx; } + + template + simdjson_inline bool buf_block_reader::has_full_block() const { + return idx < lenminusstep; + } + + template + simdjson_inline const uint8_t* buf_block_reader::full_block() const { + return &buf[idx]; + } + + template + simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { + if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers + std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. + std::memcpy(dst, buf + idx, len - idx); + return len - idx; + } + + template + simdjson_inline void buf_block_reader::advance() { + idx += STEP_SIZE; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H +/* end file generic/stage1/buf_block_reader.h for ppc64 */ +/* including generic/stage1/json_escape_scanner.h for ppc64: #include */ +/* begin file generic/stage1/json_escape_scanner.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + /** + * Scans for escape characters in JSON, taking care with multiple backslashes (\\n vs. \n). + */ + struct json_escape_scanner { + /** The actual escape characters (the backslashes themselves). */ + uint64_t next_is_escaped = 0ULL; + + struct escaped_and_escape { + /** + * Mask of escaped characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 0100100010100101000 + * n \ \ n \ \ + * ``` + */ + uint64_t escaped; + /** + * Mask of escape characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 1001000101001010001 + * \ \ \ \ \ \ \ + * ``` + */ + uint64_t escape; + }; + + /** + * Get a mask of both escape and escaped characters (the characters following a backslash). + * + * @param potential_escape A mask of the character that can escape others (but could be + * escaped itself). e.g. block.eq('\\') + */ + simdjson_really_inline escaped_and_escape next(uint64_t backslash) noexcept { + +#if !SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT + if (!backslash) { return { next_escaped_without_backslashes(), 0 }; } +#endif + + // | | Mask (shows characters instead of 1's) | Depth | Instructions | + // |--------------------------------|----------------------------------------|-------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | | | + // | | ` even odd even odd odd` | | | + // | potential_escape | ` \ \\\ \\\ \\\\ \\\\ \\\` | 1 | 1 (backslash & ~first_is_escaped) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 5 | 5 (next_escape_and_terminal_code()) + // | escaped | `\ \ n \ n \ \ \ \ \ ` X | 6 | 7 (escape_and_terminal_code ^ (potential_escape | first_is_escaped)) + // | escape | ` \ \ \ \ \ \ \ \ \ \` | 6 | 8 (escape_and_terminal_code & backslash) + // | first_is_escaped | `\ ` | 7 (*) | 9 (escape >> 63) () + // (*) this is not needed until the next iteration + uint64_t escape_and_terminal_code = next_escape_and_terminal_code(backslash & ~this->next_is_escaped); + uint64_t escaped = escape_and_terminal_code ^ (backslash | this->next_is_escaped); + uint64_t escape = escape_and_terminal_code & backslash; + this->next_is_escaped = escape >> 63; + return { escaped, escape }; + } + + private: + static constexpr const uint64_t ODD_BITS = 0xAAAAAAAAAAAAAAAAULL; + + simdjson_really_inline uint64_t next_escaped_without_backslashes() noexcept { + uint64_t escaped = this->next_is_escaped; + this->next_is_escaped = 0; + return escaped; + } + + /** + * Returns a mask of the next escape characters (masking out escaped backslashes), along with + * any non-backslash escape codes. + * + * \n \\n \\\n \\\\n returns: + * \n \ \ \n \ \ + * 11 100 1011 10100 + * + * You are expected to mask out the first bit yourself if the previous block had a trailing + * escape. + * + * & the result with potential_escape to get just the escape characters. + * ^ the result with (potential_escape | first_is_escaped) to get escaped characters. + */ + static simdjson_really_inline uint64_t next_escape_and_terminal_code(uint64_t potential_escape) noexcept { + // If we were to just shift and mask out any odd bits, we'd actually get a *half* right answer: + // any even-aligned backslash runs would be correct! Odd-aligned backslash runs would be + // inverted (\\\ would be 010 instead of 101). + // + // ``` + // string: | ____\\\\_\\\\_____ | + // maybe_escaped | ODD | \ \ \ \ | + // even-aligned ^^^ ^^^^ odd-aligned + // ``` + // + // Taking that into account, our basic strategy is: + // + // 1. Use subtraction to produce a mask with 1's for even-aligned runs and 0's for + // odd-aligned runs. + // 2. XOR all odd bits, which masks out the odd bits in even-aligned runs, and brings IN the + // odd bits in odd-aligned runs. + // 3. & with backslash to clean up any stray bits. + // runs are set to 0, and then XORing with "odd": + // + // | | Mask (shows characters instead of 1's) | Instructions | + // |--------------------------------|----------------------------------------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | + // | | ` even odd even odd odd` | + // | maybe_escaped | ` n \\n \\n \\\_ \\\_ \\` X | 1 (potential_escape << 1) + // | maybe_escaped_and_odd | ` \n_ \\n _ \\\n_ _ \\\__ _\\\_ \\\` | 1 (maybe_escaped | odd) + // | even_series_codes_and_odd | ` n_\\\ _ n_ _\\\\ _ _ ` | 1 (maybe_escaped_and_odd - potential_escape) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 1 (^ odd) + // + + // Escaped characters are characters following an escape. + uint64_t maybe_escaped = potential_escape << 1; + + // To distinguish odd from even escape sequences, therefore, we turn on any *starting* + // escapes that are on an odd byte. (We actually bring in all odd bits, for speed.) + // - Odd runs of backslashes are 0000, and the code at the end ("n" in \n or \\n) is 1. + // - Odd runs of backslashes are 1111, and the code at the end ("n" in \n or \\n) is 0. + // - All other odd bytes are 1, and even bytes are 0. + uint64_t maybe_escaped_and_odd_bits = maybe_escaped | ODD_BITS; + uint64_t even_series_codes_and_odd_bits = maybe_escaped_and_odd_bits - potential_escape; + + // Now we flip all odd bytes back with xor. This: + // - Makes odd runs of backslashes go from 0000 to 1010 + // - Makes even runs of backslashes go from 1111 to 1010 + // - Sets actually-escaped codes to 1 (the n in \n and \\n: \n = 11, \\n = 100) + // - Resets all other bytes to 0 + return even_series_codes_and_odd_bits ^ ODD_BITS; + } + }; + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_escape_scanner.h for ppc64 */ +/* including generic/stage1/json_string_scanner.h for ppc64: #include */ +/* begin file generic/stage1/json_string_scanner.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + struct json_string_block { + // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 + simdjson_really_inline json_string_block(uint64_t escaped, uint64_t quote, uint64_t in_string) : + _escaped(escaped), _quote(quote), _in_string(in_string) {} + + // Escaped characters (characters following an escape() character) + simdjson_really_inline uint64_t escaped() const { return _escaped; } + // Real (non-backslashed) quotes + simdjson_really_inline uint64_t quote() const { return _quote; } + // Only characters inside the string (not including the quotes) + simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } + // Tail of string (everything except the start quote) + simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; } + + // escaped characters (backslashed--does not include the hex characters after \u) + uint64_t _escaped; + // real quotes (non-escaped ones) + uint64_t _quote; + // string characters (includes start quote but not end quote) + uint64_t _in_string; + }; + + // Scans blocks for string characters, storing the state necessary to do so + class json_string_scanner { + public: + simdjson_really_inline json_string_block next(const simd::simd8x64& in); + // Returns either UNCLOSED_STRING or SUCCESS + simdjson_really_inline error_code finish(); + + private: + // Scans for escape characters + json_escape_scanner escape_scanner{}; + // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). + uint64_t prev_in_string = 0ULL; + }; + + // + // Return a mask of all string characters plus end quotes. + // + // prev_escaped is overflow saying whether the next character is escaped. + // prev_in_string is overflow saying whether we're still in a string. + // + // Backslash sequences outside of quotes will be detected in stage 2. + // + simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { + const uint64_t backslash = in.eq('\\'); + const uint64_t escaped = escape_scanner.next(backslash).escaped; + const uint64_t quote = in.eq('"') & ~escaped; + + // + // prefix_xor flips on bits inside the string (and flips off the end quote). + // + // Then we xor with prev_in_string: if we were in a string already, its effect is flipped + // (characters inside strings are outside, and characters outside strings are inside). + // + const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; + + // + // Check if we're still in a string at the end of the box so the next block will know + // + prev_in_string = uint64_t(static_cast(in_string) >> 63); + + // Use ^ to turn the beginning quote off, and the end quote on. + + // We are returning a function-local object so either we get a move constructor + // or we get copy elision. + return json_string_block(escaped, quote, in_string); + } + + simdjson_really_inline error_code json_string_scanner::finish() { + if (prev_in_string) { + return UNCLOSED_STRING; + } + return SUCCESS; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_string_scanner.h for ppc64 */ +/* including generic/stage1/utf8_lookup4_algorithm.h for ppc64: #include */ +/* begin file generic/stage1/utf8_lookup4_algorithm.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace utf8_validation { + + using namespace simd; + + simdjson_inline simd8 check_special_cases(const simd8 input, const simd8 prev1) { + // Bit 0 = Too Short (lead byte/ASCII followed by lead byte/ASCII) + // Bit 1 = Too Long (ASCII followed by continuation) + // Bit 2 = Overlong 3-byte + // Bit 4 = Surrogate + // Bit 5 = Overlong 2-byte + // Bit 7 = Two Continuations + constexpr const uint8_t TOO_SHORT = 1 << 0; // 11______ 0_______ + // 11______ 11______ + constexpr const uint8_t TOO_LONG = 1 << 1; // 0_______ 10______ + constexpr const uint8_t OVERLONG_3 = 1 << 2; // 11100000 100_____ + constexpr const uint8_t SURROGATE = 1 << 4; // 11101101 101_____ + constexpr const uint8_t OVERLONG_2 = 1 << 5; // 1100000_ 10______ + constexpr const uint8_t TWO_CONTS = 1 << 7; // 10______ 10______ + constexpr const uint8_t TOO_LARGE = 1 << 3; // 11110100 1001____ + // 11110100 101_____ + // 11110101 1001____ + // 11110101 101_____ + // 1111011_ 1001____ + // 1111011_ 101_____ + // 11111___ 1001____ + // 11111___ 101_____ + constexpr const uint8_t TOO_LARGE_1000 = 1 << 6; + // 11110101 1000____ + // 1111011_ 1000____ + // 11111___ 1000____ + constexpr const uint8_t OVERLONG_4 = 1 << 6; // 11110000 1000____ + + const simd8 byte_1_high = prev1.shr<4>().lookup_16( + // 0_______ ________ + TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG, + TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG, + // 10______ ________ + TWO_CONTS, TWO_CONTS, TWO_CONTS, TWO_CONTS, + // 1100____ ________ + TOO_SHORT | OVERLONG_2, + // 1101____ ________ + TOO_SHORT, + // 1110____ ________ + TOO_SHORT | OVERLONG_3 | SURROGATE, + // 1111____ ________ + TOO_SHORT | TOO_LARGE | TOO_LARGE_1000 | OVERLONG_4 + ); + constexpr const uint8_t CARRY = TOO_SHORT | TOO_LONG | TWO_CONTS; // These all have ____ in byte 1 . + const simd8 byte_1_low = (prev1 & 0x0F).lookup_16( + // ____0000 ________ + CARRY | OVERLONG_3 | OVERLONG_2 | OVERLONG_4, + // ____0001 ________ + CARRY | OVERLONG_2, + // ____001_ ________ + CARRY, + CARRY, + + // ____0100 ________ + CARRY | TOO_LARGE, + // ____0101 ________ + CARRY | TOO_LARGE | TOO_LARGE_1000, + // ____011_ ________ + CARRY | TOO_LARGE | TOO_LARGE_1000, + CARRY | TOO_LARGE | TOO_LARGE_1000, + + // ____1___ ________ + CARRY | TOO_LARGE | TOO_LARGE_1000, + CARRY | TOO_LARGE | TOO_LARGE_1000, + CARRY | TOO_LARGE | TOO_LARGE_1000, + CARRY | TOO_LARGE | TOO_LARGE_1000, + CARRY | TOO_LARGE | TOO_LARGE_1000, + // ____1101 ________ + CARRY | TOO_LARGE | TOO_LARGE_1000 | SURROGATE, + CARRY | TOO_LARGE | TOO_LARGE_1000, + CARRY | TOO_LARGE | TOO_LARGE_1000 + ); + const simd8 byte_2_high = input.shr<4>().lookup_16( + // ________ 0_______ + TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT, + TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT, + + // ________ 1000____ + TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE_1000 | OVERLONG_4, + // ________ 1001____ + TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE, + // ________ 101_____ + TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE, + TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE, + + // ________ 11______ + TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT + ); + return (byte_1_high & byte_1_low & byte_2_high); + } + simdjson_inline simd8 check_multibyte_lengths(const simd8 input, + const simd8 prev_input, const simd8 sc) { + simd8 prev2 = input.prev<2>(prev_input); + simd8 prev3 = input.prev<3>(prev_input); + simd8 must23 = simd8(must_be_2_3_continuation(prev2, prev3)); + simd8 must23_80 = must23 & uint8_t(0x80); + return must23_80 ^ sc; + } + + // + // Return nonzero if there are incomplete multibyte characters at the end of the block: + // e.g. if there is a 4-byte character, but it's 3 bytes from the end. + // + simdjson_inline simd8 is_incomplete(const simd8 input) { + // If the previous input's last 3 bytes match this, they're too short (they ended at EOF): + // ... 1111____ 111_____ 11______ +#if SIMDJSON_IMPLEMENTATION_ICELAKE + static const uint8_t max_array[64] = { + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 0xf0u - 1, 0xe0u - 1, 0xc0u - 1 + }; +#else + static const uint8_t max_array[32] = { + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 0xf0u - 1, 0xe0u - 1, 0xc0u - 1 + }; +#endif + const simd8 max_value(&max_array[sizeof(max_array) - sizeof(simd8)]); + return input.gt_bits(max_value); + } + + struct utf8_checker { + // If this is nonzero, there has been a UTF-8 error. + simd8 error; + // The last input we received + simd8 prev_input_block; + // Whether the last input we received was incomplete (used for ASCII fast path) + simd8 prev_incomplete; + + // + // Check whether the current bytes are valid UTF-8. + // + simdjson_inline void check_utf8_bytes(const simd8 input, const simd8 prev_input) { + // Flip prev1...prev3 so we can easily determine if they are 2+, 3+ or 4+ lead bytes + // (2, 3, 4-byte leads become large positive numbers instead of small negative numbers) + simd8 prev1 = input.prev<1>(prev_input); + simd8 sc = check_special_cases(input, prev1); + this->error |= check_multibyte_lengths(input, prev_input, sc); + } + + // The only problem that can happen at EOF is that a multibyte character is too short + // or a byte value too large in the last bytes: check_special_cases only checks for bytes + // too large in the first of two bytes. + simdjson_inline void check_eof() { + // If the previous block had incomplete UTF-8 characters at the end, an ASCII block can't + // possibly finish them. + this->error |= this->prev_incomplete; + } + + simdjson_inline void check_next_input(const simd8x64& input) { + if (simdjson_likely(is_ascii(input))) { + this->error |= this->prev_incomplete; + } + else { + // you might think that a for-loop would work, but under Visual Studio, it is not good enough. + static_assert((simd8x64::NUM_CHUNKS == 1) + || (simd8x64::NUM_CHUNKS == 2) + || (simd8x64::NUM_CHUNKS == 4), + "We support one, two or four chunks per 64-byte block."); + SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 1) { + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + } +else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + } + else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 4) { + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + this->check_utf8_bytes(input.chunks[2], input.chunks[1]); + this->check_utf8_bytes(input.chunks[3], input.chunks[2]); + } + this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); + this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; + } + } + // do not forget to call check_eof! + simdjson_inline error_code errors() { + return this->error.any_bits_set_anywhere() ? error_code::UTF8_ERROR : error_code::SUCCESS; + } + + }; // struct utf8_checker + } // namespace utf8_validation + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H +/* end file generic/stage1/utf8_lookup4_algorithm.h for ppc64 */ +/* including generic/stage1/json_scanner.h for ppc64: #include */ +/* begin file generic/stage1/json_scanner.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + /** + * A block of scanned json, with information on operators and scalars. + * + * We seek to identify pseudo-structural characters. Anything that is inside + * a string must be omitted (hence & ~_string.string_tail()). + * Otherwise, pseudo-structural characters come in two forms. + * 1. We have the structural characters ([,],{,},:, comma). The + * term 'structural character' is from the JSON RFC. + * 2. We have the 'scalar pseudo-structural characters'. + * Scalars are quotes, and any character except structural characters and white space. + * + * To identify the scalar pseudo-structural characters, we must look at what comes + * before them: it must be a space, a quote or a structural characters. + * Starting with simdjson v0.3, we identify them by + * negation: we identify everything that is followed by a non-quote scalar, + * and we negate that. Whatever remains must be a 'scalar pseudo-structural character'. + */ + struct json_block { + public: + // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 + simdjson_inline json_block(json_string_block&& string, json_character_block characters, uint64_t follows_potential_nonquote_scalar) : + _string(std::move(string)), _characters(characters), _follows_potential_nonquote_scalar(follows_potential_nonquote_scalar) {} + simdjson_inline json_block(json_string_block string, json_character_block characters, uint64_t follows_potential_nonquote_scalar) : + _string(string), _characters(characters), _follows_potential_nonquote_scalar(follows_potential_nonquote_scalar) {} + + /** + * The start of structurals. + * In simdjson prior to v0.3, these were called the pseudo-structural characters. + **/ + simdjson_inline uint64_t structural_start() const noexcept { return potential_structural_start() & ~_string.string_tail(); } + /** All JSON whitespace (i.e. not in a string) */ + simdjson_inline uint64_t whitespace() const noexcept { return non_quote_outside_string(_characters.whitespace()); } + + // Helpers + + /** Whether the given characters are inside a string (only works on non-quotes) */ + simdjson_inline uint64_t non_quote_inside_string(uint64_t mask) const noexcept { return _string.non_quote_inside_string(mask); } + /** Whether the given characters are outside a string (only works on non-quotes) */ + simdjson_inline uint64_t non_quote_outside_string(uint64_t mask) const noexcept { return _string.non_quote_outside_string(mask); } + + // string and escape characters + json_string_block _string; + // whitespace, structural characters ('operators'), scalars + json_character_block _characters; + // whether the previous character was a scalar + uint64_t _follows_potential_nonquote_scalar; + private: + // Potential structurals (i.e. disregarding strings) + + /** + * structural elements ([,],{,},:, comma) plus scalar starts like 123, true and "abc". + * They may reside inside a string. + **/ + simdjson_inline uint64_t potential_structural_start() const noexcept { return _characters.op() | potential_scalar_start(); } + /** + * The start of non-operator runs, like 123, true and "abc". + * It main reside inside a string. + **/ + simdjson_inline uint64_t potential_scalar_start() const noexcept { + // The term "scalar" refers to anything except structural characters and white space + // (so letters, numbers, quotes). + // Whenever it is preceded by something that is not a structural element ({,},[,],:, ") nor a white-space + // then we know that it is irrelevant structurally. + return _characters.scalar() & ~follows_potential_scalar(); + } + /** + * Whether the given character is immediately after a non-operator like 123, true. + * The characters following a quote are not included. + */ + simdjson_inline uint64_t follows_potential_scalar() const noexcept { + // _follows_potential_nonquote_scalar: is defined as marking any character that follows a character + // that is not a structural element ({,},[,],:, comma) nor a quote (") and that is not a + // white space. + // It is understood that within quoted region, anything at all could be marked (irrelevant). + return _follows_potential_nonquote_scalar; + } + }; + + /** + * Scans JSON for important bits: structural characters or 'operators', strings, and scalars. + * + * The scanner starts by calculating two distinct things: + * - string characters (taking \" into account) + * - structural characters or 'operators' ([]{},:, comma) + * and scalars (runs of non-operators like 123, true and "abc") + * + * To minimize data dependency (a key component of the scanner's speed), it finds these in parallel: + * in particular, the operator/scalar bit will find plenty of things that are actually part of + * strings. When we're done, json_block will fuse the two together by masking out tokens that are + * part of a string. + */ + class json_scanner { + public: + json_scanner() = default; + simdjson_inline json_block next(const simd::simd8x64& in); + // Returns either UNCLOSED_STRING or SUCCESS + simdjson_inline error_code finish(); + + private: + // Whether the last character of the previous iteration is part of a scalar token + // (anything except whitespace or a structural character/'operator'). + uint64_t prev_scalar = 0ULL; + json_string_scanner string_scanner{}; + }; + + + // + // Check if the current character immediately follows a matching character. + // + // For example, this checks for quotes with backslashes in front of them: + // + // const uint64_t backslashed_quote = in.eq('"') & immediately_follows(in.eq('\'), prev_backslash); + // + simdjson_inline uint64_t follows(const uint64_t match, uint64_t& overflow) { + const uint64_t result = match << 1 | overflow; + overflow = match >> 63; + return result; + } + + simdjson_inline json_block json_scanner::next(const simd::simd8x64& in) { + json_string_block strings = string_scanner.next(in); + // identifies the white-space and the structural characters + json_character_block characters = json_character_block::classify(in); + // The term "scalar" refers to anything except structural characters and white space + // (so letters, numbers, quotes). + // We want follows_scalar to mark anything that follows a non-quote scalar (so letters and numbers). + // + // A terminal quote should either be followed by a structural character (comma, brace, bracket, colon) + // or nothing. However, we still want ' "a string"true ' to mark the 't' of 'true' as a potential + // pseudo-structural character just like we would if we had ' "a string" true '; otherwise we + // may need to add an extra check when parsing strings. + // + // Performance: there are many ways to skin this cat. + const uint64_t nonquote_scalar = characters.scalar() & ~strings.quote(); + uint64_t follows_nonquote_scalar = follows(nonquote_scalar, prev_scalar); + // We are returning a function-local object so either we get a move constructor + // or we get copy elision. + return json_block( + strings,// strings is a function-local object so either it moves or the copy is elided. + characters, + follows_nonquote_scalar + ); + } + + simdjson_inline error_code json_scanner::finish() { + return string_scanner.finish(); + } + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H +/* end file generic/stage1/json_scanner.h for ppc64 */ + +// All other declarations +/* including generic/stage1/find_next_document_index.h for ppc64: #include */ +/* begin file generic/stage1/find_next_document_index.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + /** + * This algorithm is used to quickly identify the last structural position that + * makes up a complete document. + * + * It does this by going backwards and finding the last *document boundary* (a + * place where one value follows another without a comma between them). If the + * last document (the characters after the boundary) has an equal number of + * start and end brackets, it is considered complete. + * + * Simply put, we iterate over the structural characters, starting from + * the end. We consider that we found the end of a JSON document when the + * first element of the pair is NOT one of these characters: '{' '[' ':' ',' + * and when the second element is NOT one of these characters: '}' ']' ':' ','. + * + * This simple comparison works most of the time, but it does not cover cases + * where the batch's structural indexes contain a perfect amount of documents. + * In such a case, we do not have access to the structural index which follows + * the last document, therefore, we do not have access to the second element in + * the pair, and that means we cannot identify the last document. To fix this + * issue, we keep a count of the open and closed curly/square braces we found + * while searching for the pair. When we find a pair AND the count of open and + * closed curly/square braces is the same, we know that we just passed a + * complete document, therefore the last json buffer location is the end of the + * batch. + */ + simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { + // Variant: do not count separately, just figure out depth + if (parser.n_structural_indexes == 0) { return 0; } + auto arr_cnt = 0; + auto obj_cnt = 0; + for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { + auto idxb = parser.structural_indexes[i]; + switch (parser.buf[idxb]) { + case ':': + case ',': + continue; + case '}': + obj_cnt--; + continue; + case ']': + arr_cnt--; + continue; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + auto idxa = parser.structural_indexes[i - 1]; + switch (parser.buf[idxa]) { + case '{': + case '[': + case ':': + case ',': + continue; + } + // Last document is complete, so the next document will appear after! + if (!arr_cnt && !obj_cnt) { + return parser.n_structural_indexes; + } + // Last document is incomplete; mark the document at i + 1 as the next one + return i; + } + // If we made it to the end, we want to finish counting to see if we have a full document. + switch (parser.buf[parser.structural_indexes[0]]) { + case '}': + obj_cnt--; + break; + case ']': + arr_cnt--; + break; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + if (!arr_cnt && !obj_cnt) { + // We have a complete document. + return parser.n_structural_indexes; + } + return 0; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H +/* end file generic/stage1/find_next_document_index.h for ppc64 */ +/* including generic/stage1/json_minifier.h for ppc64: #include */ +/* begin file generic/stage1/json_minifier.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses in stage1 +// It is intended to be included multiple times and compiled multiple times +// We assume the file in which it is included already includes +// "simdjson/stage1.h" (this simplifies amalgation) + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + class json_minifier { + public: + template + static error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) noexcept; + + private: + simdjson_inline json_minifier(uint8_t* _dst) + : dst{ _dst } + {} + template + simdjson_inline void step(const uint8_t* block_buf, buf_block_reader& reader) noexcept; + simdjson_inline void next(const simd::simd8x64& in, const json_block& block); + simdjson_inline error_code finish(uint8_t* dst_start, size_t& dst_len); + json_scanner scanner{}; + uint8_t* dst; + }; + + simdjson_inline void json_minifier::next(const simd::simd8x64& in, const json_block& block) { + uint64_t mask = block.whitespace(); + dst += in.compress(mask, dst); + } + + simdjson_inline error_code json_minifier::finish(uint8_t* dst_start, size_t& dst_len) { + error_code error = scanner.finish(); + if (error) { dst_len = 0; return error; } + dst_len = dst - dst_start; + return SUCCESS; + } + + template<> + simdjson_inline void json_minifier::step<128>(const uint8_t* block_buf, buf_block_reader<128>& reader) noexcept { + simd::simd8x64 in_1(block_buf); + simd::simd8x64 in_2(block_buf + 64); + json_block block_1 = scanner.next(in_1); + json_block block_2 = scanner.next(in_2); + this->next(in_1, block_1); + this->next(in_2, block_2); + reader.advance(); + } + + template<> + simdjson_inline void json_minifier::step<64>(const uint8_t* block_buf, buf_block_reader<64>& reader) noexcept { + simd::simd8x64 in_1(block_buf); + json_block block_1 = scanner.next(in_1); + this->next(block_buf, block_1); + reader.advance(); + } + + template + error_code json_minifier::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) noexcept { + buf_block_reader reader(buf, len); + json_minifier minifier(dst); + + // Index the first n-1 blocks + while (reader.has_full_block()) { + minifier.step(reader.full_block(), reader); + } + + // Index the last (remainder) block, padded with spaces + uint8_t block[STEP_SIZE]; + size_t remaining_bytes = reader.get_remainder(block); + if (remaining_bytes > 0) { + // We do not want to write directly to the output stream. Rather, we write + // to a local buffer (for safety). + uint8_t out_block[STEP_SIZE]; + uint8_t* const guarded_dst{ minifier.dst }; + minifier.dst = out_block; + minifier.step(block, reader); + size_t to_write = minifier.dst - out_block; + // In some cases, we could be enticed to consider the padded spaces + // as part of the string. This is fine as long as we do not write more + // than we consumed. + if (to_write > remaining_bytes) { to_write = remaining_bytes; } + memcpy(guarded_dst, out_block, to_write); + minifier.dst = guarded_dst + to_write; + } + return minifier.finish(dst, dst_len); + } + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H +/* end file generic/stage1/json_minifier.h for ppc64 */ +/* including generic/stage1/json_structural_indexer.h for ppc64: #include */ +/* begin file generic/stage1/json_structural_indexer.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses in stage1 +// It is intended to be included multiple times and compiled multiple times +// We assume the file in which it is included already includes +// "simdjson/stage1.h" (this simplifies amalgation) + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + class bit_indexer { + public: + uint32_t* tail; + + simdjson_inline bit_indexer(uint32_t* index_buf) : tail(index_buf) {} + +#if SIMDJSON_PREFER_REVERSE_BITS + /** + * ARM lacks a fast trailing zero instruction, but it has a fast + * bit reversal instruction and a fast leading zero instruction. + * Thus it may be profitable to reverse the bits (once) and then + * to rely on a sequence of instructions that call the leading + * zero instruction. + * + * Performance notes: + * The chosen routine is not optimal in terms of data dependency + * since zero_leading_bit might require two instructions. However, + * it tends to minimize the total number of instructions which is + * beneficial. + */ + simdjson_inline void write_index(uint32_t idx, uint64_t& rev_bits, int i) { + int lz = leading_zeroes(rev_bits); + this->tail[i] = static_cast(idx) + lz; + rev_bits = zero_leading_bit(rev_bits, lz); + } +#else + /** + * Under recent x64 systems, we often have both a fast trailing zero + * instruction and a fast 'clear-lower-bit' instruction so the following + * algorithm can be competitive. + */ + + simdjson_inline void write_index(uint32_t idx, uint64_t& bits, int i) { + this->tail[i] = idx + trailing_zeroes(bits); + bits = clear_lowest_bit(bits); + } +#endif // SIMDJSON_PREFER_REVERSE_BITS + + template + simdjson_inline int write_indexes(uint32_t idx, uint64_t& bits) { + write_index(idx, bits, START); + SIMDJSON_IF_CONSTEXPR(N > 1) { + write_indexes<(N - 1 > 0 ? START + 1 : START), (N - 1 >= 0 ? N - 1 : 1)>(idx, bits); + } + return START + N; + } + + template + simdjson_inline int write_indexes_stepped(uint32_t idx, uint64_t& bits, int cnt) { + write_indexes(idx, bits); + SIMDJSON_IF_CONSTEXPR((START + STEP) < END) { + if (simdjson_unlikely((START + STEP) < cnt)) { + write_indexes_stepped<(START + STEP < END ? START + STEP : END), END, STEP>(idx, bits, cnt); + } + } + return ((END - START) % STEP) == 0 ? END : (END - START) - ((END - START) % STEP) + STEP; + } + + // flatten out values in 'bits' assuming that they are are to have values of idx + // plus their position in the bitvector, and store these indexes at + // base_ptr[base] incrementing base as we go + // will potentially store extra values beyond end of valid bits, so base_ptr + // needs to be large enough to handle this + // + // If the kernel sets SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER, then it + // will provide its own version of the code. +#ifdef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + simdjson_inline void write(uint32_t idx, uint64_t bits); +#else + simdjson_inline void write(uint32_t idx, uint64_t bits) { + // In some instances, the next branch is expensive because it is mispredicted. + // Unfortunately, in other cases, + // it helps tremendously. + if (bits == 0) + return; + + int cnt = static_cast(count_ones(bits)); + +#if SIMDJSON_PREFER_REVERSE_BITS + bits = reverse_bits(bits); +#endif +#ifdef SIMDJSON_STRUCTURAL_INDEXER_STEP + static constexpr const int STEP = SIMDJSON_STRUCTURAL_INDEXER_STEP; +#else + static constexpr const int STEP = 4; +#endif + static constexpr const int STEP_UNTIL = 24; + + write_indexes_stepped<0, STEP_UNTIL, STEP>(idx, bits, cnt); + SIMDJSON_IF_CONSTEXPR(STEP_UNTIL < 64) { + if (simdjson_unlikely(STEP_UNTIL < cnt)) { + for (int i = STEP_UNTIL; i < cnt; i++) { + write_index(idx, bits, i); + } + } + } + + this->tail += cnt; + } +#endif // SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + + }; + + class json_structural_indexer { + public: + /** + * Find the important bits of JSON in a 128-byte chunk, and add them to structural_indexes. + * + * @param partial Setting the partial parameter to true allows the find_structural_bits to + * tolerate unclosed strings. The caller should still ensure that the input is valid UTF-8. If + * you are processing substrings, you may want to call on a function like trimmed_length_safe_utf8. + */ + template + static error_code index(const uint8_t* buf, size_t len, dom_parser_implementation& parser, stage1_mode partial) noexcept; + + private: + simdjson_inline json_structural_indexer(uint32_t* structural_indexes); + template + simdjson_inline void step(const uint8_t* block, buf_block_reader& reader) noexcept; + simdjson_inline void next(const simd::simd8x64& in, const json_block& block, size_t idx); + simdjson_inline error_code finish(dom_parser_implementation& parser, size_t idx, size_t len, stage1_mode partial); + + json_scanner scanner{}; + utf8_checker checker{}; + bit_indexer indexer; + uint64_t prev_structurals = 0; + uint64_t unescaped_chars_error = 0; + }; + + simdjson_inline json_structural_indexer::json_structural_indexer(uint32_t* structural_indexes) : indexer{ structural_indexes } {} + + // Skip the last character if it is partial + simdjson_inline size_t trim_partial_utf8(const uint8_t* buf, size_t len) { + if (simdjson_unlikely(len < 3)) { + switch (len) { + case 2: + if (buf[len - 1] >= 0xc0) { return len - 1; } // 2-, 3- and 4-byte characters with only 1 byte left + if (buf[len - 2] >= 0xe0) { return len - 2; } // 3- and 4-byte characters with only 2 bytes left + return len; + case 1: + if (buf[len - 1] >= 0xc0) { return len - 1; } // 2-, 3- and 4-byte characters with only 1 byte left + return len; + case 0: + return len; + } + } + if (buf[len - 1] >= 0xc0) { return len - 1; } // 2-, 3- and 4-byte characters with only 1 byte left + if (buf[len - 2] >= 0xe0) { return len - 2; } // 3- and 4-byte characters with only 1 byte left + if (buf[len - 3] >= 0xf0) { return len - 3; } // 4-byte characters with only 3 bytes left + return len; + } + + // + // PERF NOTES: + // We pipe 2 inputs through these stages: + // 1. Load JSON into registers. This takes a long time and is highly parallelizable, so we load + // 2 inputs' worth at once so that by the time step 2 is looking for them input, it's available. + // 2. Scan the JSON for critical data: strings, scalars and operators. This is the critical path. + // The output of step 1 depends entirely on this information. These functions don't quite use + // up enough CPU: the second half of the functions is highly serial, only using 1 execution core + // at a time. The second input's scans has some dependency on the first ones finishing it, but + // they can make a lot of progress before they need that information. + // 3. Step 1 doesn't use enough capacity, so we run some extra stuff while we're waiting for that + // to finish: utf-8 checks and generating the output from the last iteration. + // + // The reason we run 2 inputs at a time, is steps 2 and 3 are *still* not enough to soak up all + // available capacity with just one input. Running 2 at a time seems to give the CPU a good enough + // workout. + // + template + error_code json_structural_indexer::index(const uint8_t* buf, size_t len, dom_parser_implementation& parser, stage1_mode partial) noexcept { + if (simdjson_unlikely(len > parser.capacity())) { return CAPACITY; } + // We guard the rest of the code so that we can assume that len > 0 throughout. + if (len == 0) { return EMPTY; } + if (is_streaming(partial)) { + len = trim_partial_utf8(buf, len); + // If you end up with an empty window after trimming + // the partial UTF-8 bytes, then chances are good that you + // have an UTF-8 formatting error. + if (len == 0) { return UTF8_ERROR; } + } + buf_block_reader reader(buf, len); + json_structural_indexer indexer(parser.structural_indexes.get()); + + // Read all but the last block + while (reader.has_full_block()) { + indexer.step(reader.full_block(), reader); + } + // Take care of the last block (will always be there unless file is empty which is + // not supposed to happen.) + uint8_t block[STEP_SIZE]; + if (simdjson_unlikely(reader.get_remainder(block) == 0)) { return UNEXPECTED_ERROR; } + indexer.step(block, reader); + return indexer.finish(parser, reader.block_index(), len, partial); + } + + template<> + simdjson_inline void json_structural_indexer::step<128>(const uint8_t* block, buf_block_reader<128>& reader) noexcept { + simd::simd8x64 in_1(block); + simd::simd8x64 in_2(block + 64); + json_block block_1 = scanner.next(in_1); + json_block block_2 = scanner.next(in_2); + this->next(in_1, block_1, reader.block_index()); + this->next(in_2, block_2, reader.block_index() + 64); + reader.advance(); + } + + template<> + simdjson_inline void json_structural_indexer::step<64>(const uint8_t* block, buf_block_reader<64>& reader) noexcept { + simd::simd8x64 in_1(block); + json_block block_1 = scanner.next(in_1); + this->next(in_1, block_1, reader.block_index()); + reader.advance(); + } + + simdjson_inline void json_structural_indexer::next(const simd::simd8x64& in, const json_block& block, size_t idx) { + uint64_t unescaped = in.lteq(0x1F); +#if SIMDJSON_UTF8VALIDATION + checker.check_next_input(in); +#endif + indexer.write(uint32_t(idx - 64), prev_structurals); // Output *last* iteration's structurals to the parser + prev_structurals = block.structural_start(); + unescaped_chars_error |= block.non_quote_inside_string(unescaped); + } + + simdjson_inline error_code json_structural_indexer::finish(dom_parser_implementation& parser, size_t idx, size_t len, stage1_mode partial) { + // Write out the final iteration's structurals + indexer.write(uint32_t(idx - 64), prev_structurals); + error_code error = scanner.finish(); + // We deliberately break down the next expression so that it is + // human readable. + const bool should_we_exit = is_streaming(partial) ? + ((error != SUCCESS) && (error != UNCLOSED_STRING)) // when partial we tolerate UNCLOSED_STRING + : (error != SUCCESS); // if partial is false, we must have SUCCESS + const bool have_unclosed_string = (error == UNCLOSED_STRING); + if (simdjson_unlikely(should_we_exit)) { return error; } + + if (unescaped_chars_error) { + return UNESCAPED_CHARS; + } + parser.n_structural_indexes = uint32_t(indexer.tail - parser.structural_indexes.get()); + /*** + * The On Demand API requires special padding. + * + * This is related to https://github.com/simdjson/simdjson/issues/906 + * Basically, we want to make sure that if the parsing continues beyond the last (valid) + * structural character, it quickly stops. + * Only three structural characters can be repeated without triggering an error in JSON: [,] and }. + * We repeat the padding character (at 'len'). We don't know what it is, but if the parsing + * continues, then it must be [,] or }. + * Suppose it is ] or }. We backtrack to the first character, what could it be that would + * not trigger an error? It could be ] or } but no, because you can't start a document that way. + * It can't be a comma, a colon or any simple value. So the only way we could continue is + * if the repeated character is [. But if so, the document must start with [. But if the document + * starts with [, it should end with ]. If we enforce that rule, then we would get + * ][[ which is invalid. + * + * This is illustrated with the test array_iterate_unclosed_error() on the following input: + * R"({ "a": [,,)" + **/ + parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len); // used later in partial == stage1_mode::streaming_final + parser.structural_indexes[parser.n_structural_indexes + 1] = uint32_t(len); + parser.structural_indexes[parser.n_structural_indexes + 2] = 0; + parser.next_structural_index = 0; + // a valid JSON file cannot have zero structural indexes - we should have found something + if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { + return EMPTY; + } + if (simdjson_unlikely(parser.structural_indexes[parser.n_structural_indexes - 1] > len)) { + return UNEXPECTED_ERROR; + } + if (partial == stage1_mode::streaming_partial) { + // If we have an unclosed string, then the last structural + // will be the quote and we want to make sure to omit it. + if (have_unclosed_string) { + parser.n_structural_indexes--; + // a valid JSON file cannot have zero structural indexes - we should have found something + if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { return CAPACITY; } + } + // We truncate the input to the end of the last complete document (or zero). + auto new_structural_indexes = find_next_document_index(parser); + if (new_structural_indexes == 0 && parser.n_structural_indexes > 0) { + if (parser.structural_indexes[0] == 0) { + // If the buffer is partial and we started at index 0 but the document is + // incomplete, it's too big to parse. + return CAPACITY; + } + else { + // It is possible that the document could be parsed, we just had a lot + // of white space. + parser.n_structural_indexes = 0; + return EMPTY; + } + } + + parser.n_structural_indexes = new_structural_indexes; + } + else if (partial == stage1_mode::streaming_final) { + if (have_unclosed_string) { parser.n_structural_indexes--; } + // We truncate the input to the end of the last complete document (or zero). + // Because partial == stage1_mode::streaming_final, it means that we may + // silently ignore trailing garbage. Though it sounds bad, we do it + // deliberately because many people who have streams of JSON documents + // will truncate them for processing. E.g., imagine that you are uncompressing + // the data from a size file or receiving it in chunks from the network. You + // may not know where exactly the last document will be. Meanwhile the + // document_stream instances allow people to know the JSON documents they are + // parsing (see the iterator.source() method). + parser.n_structural_indexes = find_next_document_index(parser); + // We store the initial n_structural_indexes so that the client can see + // whether we used truncation. If initial_n_structural_indexes == parser.n_structural_indexes, + // then this will query parser.structural_indexes[parser.n_structural_indexes] which is len, + // otherwise, it will copy some prior index. + parser.structural_indexes[parser.n_structural_indexes + 1] = parser.structural_indexes[parser.n_structural_indexes]; + // This next line is critical, do not change it unless you understand what you are + // doing. + parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len); + if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { + // We tolerate an unclosed string at the very end of the stream. Indeed, users + // often load their data in bulk without being careful and they want us to ignore + // the trailing garbage. + return EMPTY; + } + } + checker.check_eof(); + return checker.errors(); + } + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +// Clear CUSTOM_BIT_INDEXER so other implementations can set it if they need to. +#undef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H +/* end file generic/stage1/json_structural_indexer.h for ppc64 */ +/* including generic/stage1/utf8_validator.h for ppc64: #include */ +/* begin file generic/stage1/utf8_validator.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage1 { + + /** + * Validates that the string is actual UTF-8. + */ + template + bool generic_validate_utf8(const uint8_t* input, size_t length) { + checker c{}; + buf_block_reader<64> reader(input, length); + while (reader.has_full_block()) { + simd::simd8x64 in(reader.full_block()); + c.check_next_input(in); + reader.advance(); + } + uint8_t block[64]{}; + reader.get_remainder(block); + simd::simd8x64 in(block); + c.check_next_input(in); + reader.advance(); + c.check_eof(); + return c.errors() == error_code::SUCCESS; + } + + bool generic_validate_utf8(const char* input, size_t length) { + return generic_validate_utf8(reinterpret_cast(input), length); + } + + } // namespace stage1 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H +/* end file generic/stage1/utf8_validator.h for ppc64 */ +/* end file generic/stage1/amalgamated.h for ppc64 */ +/* including generic/stage2/amalgamated.h for ppc64: #include */ +/* begin file generic/stage2/amalgamated.h for ppc64 */ +// Stuff other things depend on +/* including generic/stage2/base.h for ppc64: #include */ +/* begin file generic/stage2/base.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage2 { + + class json_iterator; + class structural_iterator; + struct tape_builder; + struct tape_writer; + + } // namespace stage2 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_BASE_H +/* end file generic/stage2/base.h for ppc64 */ +/* including generic/stage2/tape_writer.h for ppc64: #include */ +/* begin file generic/stage2/tape_writer.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage2 { + + struct tape_writer { + /** The next place to write to tape */ + uint64_t* next_tape_loc; + + /** Write a signed 64-bit value to tape. */ + simdjson_inline void append_s64(int64_t value) noexcept; + + /** Write an unsigned 64-bit value to tape. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + + /** Write a double value to tape. */ + simdjson_inline void append_double(double value) noexcept; + + /** + * Append a tape entry (an 8-bit type,and 56 bits worth of value). + */ + simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; + + /** + * Skip the current tape entry without writing. + * + * Used to skip the start of the container, since we'll come back later to fill it in when the + * container ends. + */ + simdjson_inline void skip() noexcept; + + /** + * Skip the number of tape entries necessary to write a large u64 or i64. + */ + simdjson_inline void skip_large_integer() noexcept; + + /** + * Skip the number of tape entries necessary to write a double. + */ + simdjson_inline void skip_double() noexcept; + + /** + * Write a value to a known location on tape. + * + * Used to go back and write out the start of a container after the container ends. + */ + simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; + + private: + /** + * Append both the tape entry, and a supplementary value following it. Used for types that need + * all 64 bits, such as double and uint64_t. + */ + template + simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; + }; // struct tape_writer + + simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { + append2(0, value, internal::tape_type::INT64); + } + + simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { + append(0, internal::tape_type::UINT64); + *next_tape_loc = value; + next_tape_loc++; + } + + /** Write a double value to tape. */ + simdjson_inline void tape_writer::append_double(double value) noexcept { + append2(0, value, internal::tape_type::DOUBLE); + } + + simdjson_inline void tape_writer::skip() noexcept { + next_tape_loc++; + } + + simdjson_inline void tape_writer::skip_large_integer() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::skip_double() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { + *next_tape_loc = val | ((uint64_t(char(t))) << 56); + next_tape_loc++; + } + + template + simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { + append(val, t); + static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); + memcpy(next_tape_loc, &val2, sizeof(val2)); + next_tape_loc++; + } + + simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { + tape_loc = val | ((uint64_t(char(t))) << 56); + } + + } // namespace stage2 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H +/* end file generic/stage2/tape_writer.h for ppc64 */ +/* including generic/stage2/logger.h for ppc64: #include */ +/* begin file generic/stage2/logger.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + + +// This is for an internal-only stage 2 specific logger. +// Set LOG_ENABLED = true to log what stage 2 is doing! +namespace simdjson { + namespace ppc64 { + namespace { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static constexpr const int LOG_INDEX_LEN = 5; + + static int log_depth; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static simdjson_inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + // Print the header and set up log_start + static simdjson_inline void log_start() { + if (LOG_ENABLED) { + log_depth = 0; + printf("\n"); + printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#"); + printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN + 2, DASHES, LOG_BUFFER_LEN + 2, DASHES, LOG_SMALL_BUFFER_LEN + 2, DASHES, 5 + 2, DASHES); + } + } + + simdjson_unused static simdjson_inline void log_string(const char* message) { + if (LOG_ENABLED) { + printf("%s\n", message); + } + } + + // Logs a single line from the stage 2 DOM parser + template + static simdjson_inline void log_line(S& structurals, const char* title_prefix, const char* title, const char* detail) { + if (LOG_ENABLED) { + printf("| %*s%s%-*s ", log_depth * 2, "", title_prefix, LOG_EVENT_LEN - log_depth * 2 - int(strlen(title_prefix)), title); + auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural - 1; + auto next_index = structurals.next_structural; + auto current = current_index ? &structurals.buf[*current_index] : reinterpret_cast(" "); + auto next = &structurals.buf[*next_index]; + { + // Print the next N characters in the buffer. + printf("| "); + // Otherwise, print the characters starting from the buffer position. + // Print spaces for unprintable or newline characters. + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current[i])); + } + printf(" "); + // Print the next N characters in the buffer. + printf("| "); + // Otherwise, print the characters starting from the buffer position. + // Print spaces for unprintable or newline characters. + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next[i])); + } + printf(" "); + } + if (current_index) { + printf("| %*u ", LOG_INDEX_LEN, *current_index); + } + else { + printf("| %-*s ", LOG_INDEX_LEN, ""); + } + // printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index()); + printf("| %-s ", detail); + printf("|\n"); + } + } + + } // namespace logger + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H +/* end file generic/stage2/logger.h for ppc64 */ + +// All other declarations +/* including generic/stage2/json_iterator.h for ppc64: #include */ +/* begin file generic/stage2/json_iterator.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage2 { + + class json_iterator { + public: + const uint8_t* const buf; + uint32_t* next_structural; + dom_parser_implementation& dom_parser; + uint32_t depth{ 0 }; + + /** + * Walk the JSON document. + * + * The visitor receives callbacks when values are encountered. All callbacks pass the iterator as + * the first parameter; some callbacks have other parameters as well: + * + * - visit_document_start() - at the beginning. + * - visit_document_end() - at the end (if things were successful). + * + * - visit_array_start() - at the start `[` of a non-empty array. + * - visit_array_end() - at the end `]` of a non-empty array. + * - visit_empty_array() - when an empty array is encountered. + * + * - visit_object_end() - at the start `]` of a non-empty object. + * - visit_object_start() - at the end `]` of a non-empty object. + * - visit_empty_object() - when an empty object is encountered. + * - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is + * guaranteed to point at the first quote of the string (`"key"`). + * - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null. + * - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null. + * + * - increment_count(iter) - each time a value is found in an array or object. + */ + template + simdjson_warn_unused simdjson_inline error_code walk_document(V& visitor) noexcept; + + /** + * Create an iterator capable of walking a JSON document. + * + * The document must have already passed through stage 1. + */ + simdjson_inline json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index); + + /** + * Look at the next token. + * + * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). + * + * They may include invalid JSON as well (such as `1.2.3` or `ture`). + */ + simdjson_inline const uint8_t* peek() const noexcept; + /** + * Advance to the next token. + * + * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). + * + * They may include invalid JSON as well (such as `1.2.3` or `ture`). + */ + simdjson_inline const uint8_t* advance() noexcept; + /** + * Get the remaining length of the document, from the start of the current token. + */ + simdjson_inline size_t remaining_len() const noexcept; + /** + * Check if we are at the end of the document. + * + * If this is true, there are no more tokens. + */ + simdjson_inline bool at_eof() const noexcept; + /** + * Check if we are at the beginning of the document. + */ + simdjson_inline bool at_beginning() const noexcept; + simdjson_inline uint8_t last_structural() const noexcept; + + /** + * Log that a value has been found. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_value(const char* type) const noexcept; + /** + * Log the start of a multipart value. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_start_value(const char* type) const noexcept; + /** + * Log the end of a multipart value. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_end_value(const char* type) const noexcept; + /** + * Log an error. + * + * Set LOG_ENABLED=true in logger.h to see logging. + */ + simdjson_inline void log_error(const char* error) const noexcept; + + template + simdjson_warn_unused simdjson_inline error_code visit_root_primitive(V& visitor, const uint8_t* value) noexcept; + template + simdjson_warn_unused simdjson_inline error_code visit_primitive(V& visitor, const uint8_t* value) noexcept; + }; + + template + simdjson_warn_unused simdjson_inline error_code json_iterator::walk_document(V& visitor) noexcept { + logger::log_start(); + + // + // Start the document + // + if (at_eof()) { return EMPTY; } + log_start_value("document"); + SIMDJSON_TRY(visitor.visit_document_start(*this)); + + // + // Read first value + // + { + auto value = advance(); + + // Make sure the outer object or array is closed before continuing; otherwise, there are ways we + // could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906 + if (!STREAMING) { + switch (*value) { + case '{': if (last_structural() != '}') { log_value("starting brace unmatched"); return TAPE_ERROR; }; break; + case '[': if (last_structural() != ']') { log_value("starting bracket unmatched"); return TAPE_ERROR; }; break; + } + } + + switch (*value) { + case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; + case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; + default: SIMDJSON_TRY(visitor.visit_root_primitive(*this, value)); break; + } + } + goto document_end; + + // + // Object parser states + // + object_begin: + log_start_value("object"); + depth++; + if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } + dom_parser.is_array[depth] = false; + SIMDJSON_TRY(visitor.visit_object_start(*this)); + + { + auto key = advance(); + if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; } + SIMDJSON_TRY(visitor.increment_count(*this)); + SIMDJSON_TRY(visitor.visit_key(*this, key)); + } + + object_field: + if (simdjson_unlikely(*advance() != ':')) { log_error("Missing colon after key in object"); return TAPE_ERROR; } + { + auto value = advance(); + switch (*value) { + case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; + case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; + default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; + } + } + + object_continue: + switch (*advance()) { + case ',': + SIMDJSON_TRY(visitor.increment_count(*this)); + { + auto key = advance(); + if (simdjson_unlikely(*key != '"')) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; } + SIMDJSON_TRY(visitor.visit_key(*this, key)); + } + goto object_field; + case '}': log_end_value("object"); SIMDJSON_TRY(visitor.visit_object_end(*this)); goto scope_end; + default: log_error("No comma between object fields"); return TAPE_ERROR; + } + + scope_end: + depth--; + if (depth == 0) { goto document_end; } + if (dom_parser.is_array[depth]) { goto array_continue; } + goto object_continue; + + // + // Array parser states + // + array_begin: + log_start_value("array"); + depth++; + if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } + dom_parser.is_array[depth] = true; + SIMDJSON_TRY(visitor.visit_array_start(*this)); + SIMDJSON_TRY(visitor.increment_count(*this)); + + array_value: + { + auto value = advance(); + switch (*value) { + case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; + case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; + default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; + } + } + + array_continue: + switch (*advance()) { + case ',': SIMDJSON_TRY(visitor.increment_count(*this)); goto array_value; + case ']': log_end_value("array"); SIMDJSON_TRY(visitor.visit_array_end(*this)); goto scope_end; + default: log_error("Missing comma between array values"); return TAPE_ERROR; + } + + document_end: + log_end_value("document"); + SIMDJSON_TRY(visitor.visit_document_end(*this)); + + dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]); + + // If we didn't make it to the end, it's an error + if (!STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes) { + log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!"); + return TAPE_ERROR; + } + + return SUCCESS; + + } // walk_document() + + simdjson_inline json_iterator::json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) + : buf{ _dom_parser.buf }, + next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, + dom_parser{ _dom_parser } { + } + + simdjson_inline const uint8_t* json_iterator::peek() const noexcept { + return &buf[*(next_structural)]; + } + simdjson_inline const uint8_t* json_iterator::advance() noexcept { + return &buf[*(next_structural++)]; + } + simdjson_inline size_t json_iterator::remaining_len() const noexcept { + return dom_parser.len - *(next_structural - 1); + } + + simdjson_inline bool json_iterator::at_eof() const noexcept { + return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; + } + simdjson_inline bool json_iterator::at_beginning() const noexcept { + return next_structural == dom_parser.structural_indexes.get(); + } + simdjson_inline uint8_t json_iterator::last_structural() const noexcept { + return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]]; + } + + simdjson_inline void json_iterator::log_value(const char* type) const noexcept { + logger::log_line(*this, "", type, ""); + } + + simdjson_inline void json_iterator::log_start_value(const char* type) const noexcept { + logger::log_line(*this, "+", type, ""); + if (logger::LOG_ENABLED) { logger::log_depth++; } + } + + simdjson_inline void json_iterator::log_end_value(const char* type) const noexcept { + if (logger::LOG_ENABLED) { logger::log_depth--; } + logger::log_line(*this, "-", type, ""); + } + + simdjson_inline void json_iterator::log_error(const char* error) const noexcept { + logger::log_line(*this, "", "ERROR", error); + } + + template + simdjson_warn_unused simdjson_inline error_code json_iterator::visit_root_primitive(V& visitor, const uint8_t* value) noexcept { + switch (*value) { + case '"': return visitor.visit_root_string(*this, value); + case 't': return visitor.visit_root_true_atom(*this, value); + case 'f': return visitor.visit_root_false_atom(*this, value); + case 'n': return visitor.visit_root_null_atom(*this, value); + case '-': + case '0': case '1': case '2': case '3': case '4': + case '5': case '6': case '7': case '8': case '9': + return visitor.visit_root_number(*this, value); + default: + log_error("Document starts with a non-value character"); + return TAPE_ERROR; + } + } + template + simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { + // Use the fact that most scalars are going to be either strings or numbers. + if (*value == '"') { + return visitor.visit_string(*this, value); + } + else if (((*value - '0') < 10) || (*value == '-')) { + return visitor.visit_number(*this, value); + } + // true, false, null are uncommon. + switch (*value) { + case 't': return visitor.visit_true_atom(*this, value); + case 'f': return visitor.visit_false_atom(*this, value); + case 'n': return visitor.visit_null_atom(*this, value); + default: + log_error("Non-value found when value was expected!"); + return TAPE_ERROR; + } + } + + } // namespace stage2 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H +/* end file generic/stage2/json_iterator.h for ppc64 */ +/* including generic/stage2/stringparsing.h for ppc64: #include */ +/* begin file generic/stage2/stringparsing.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses +// It is intended to be included multiple times and compiled multiple times + +namespace simdjson { + namespace ppc64 { + namespace { + /// @private + namespace stringparsing { + + // begin copypasta + // These chars yield themselves: " \ / + // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab + // u not handled in this table as it's complex + static const uint8_t escape_map[256] = { + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. + 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. + 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + }; + + // handle a unicode codepoint + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, + uint8_t** dst_ptr, bool allow_replacement) { + // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) + constexpr uint32_t substitution_code_point = 0xfffd; + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + + // We have already checked that the high surrogate is valid and + // (code_point - 0xd800) < 1024. + // + // Check that code_point_2 is in the range 0xdc00..0xdfff + // and that code_point_2 was parsed from valid hex. + uint32_t low_bit = code_point_2 - 0xdc00; + if (low_bit >> 10) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + + } + } + else if (code_point >= 0xdc00 && code_point <= 0xdfff) { + // If we encounter a low surrogate (not preceded by a high surrogate) + // then we have an error. + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + // handle a unicode codepoint using the wobbly convention + // https://simonsapin.github.io/wtf-8/ + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, + uint8_t** dst_ptr) { + // It is not ideal that this function is nearly identical to handle_unicode_codepoint. + // + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + uint32_t low_bit = code_point_2 - 0xdc00; + if ((low_bit >> 10) == 0) { + code_point = + (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + } + } + + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + /** + * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + */ + simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { + // It is not ideal that this function is nearly identical to parse_string. + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint_wobbly(&src, &dst)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + } // namespace stringparsing + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H +/* end file generic/stage2/stringparsing.h for ppc64 */ +/* including generic/stage2/structural_iterator.h for ppc64: #include */ +/* begin file generic/stage2/structural_iterator.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage2 { + + class structural_iterator { + public: + const uint8_t* const buf; + uint32_t* next_structural; + dom_parser_implementation& dom_parser; + + // Start a structural + simdjson_inline structural_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) + : buf{ _dom_parser.buf }, + next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, + dom_parser{ _dom_parser } { + } + // Get the buffer position of the current structural character + simdjson_inline const uint8_t* current() { + return &buf[*(next_structural - 1)]; + } + // Get the current structural character + simdjson_inline char current_char() { + return buf[*(next_structural - 1)]; + } + // Get the next structural character without advancing + simdjson_inline char peek_next_char() { + return buf[*next_structural]; + } + simdjson_inline const uint8_t* peek() { + return &buf[*next_structural]; + } + simdjson_inline const uint8_t* advance() { + return &buf[*(next_structural++)]; + } + simdjson_inline char advance_char() { + return buf[*(next_structural++)]; + } + simdjson_inline size_t remaining_len() { + return dom_parser.len - *(next_structural - 1); + } + + simdjson_inline bool at_end() { + return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; + } + simdjson_inline bool at_beginning() { + return next_structural == dom_parser.structural_indexes.get(); + } + }; + + } // namespace stage2 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H +/* end file generic/stage2/structural_iterator.h for ppc64 */ +/* including generic/stage2/tape_builder.h for ppc64: #include */ +/* begin file generic/stage2/tape_builder.h for ppc64 */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + + +namespace simdjson { + namespace ppc64 { + namespace { + namespace stage2 { + + struct tape_builder { + template + simdjson_warn_unused static simdjson_inline error_code parse_document( + dom_parser_implementation& dom_parser, + dom::document& doc) noexcept; + + /** Called when a non-empty document starts. */ + simdjson_warn_unused simdjson_inline error_code visit_document_start(json_iterator& iter) noexcept; + /** Called when a non-empty document ends without error. */ + simdjson_warn_unused simdjson_inline error_code visit_document_end(json_iterator& iter) noexcept; + + /** Called when a non-empty array starts. */ + simdjson_warn_unused simdjson_inline error_code visit_array_start(json_iterator& iter) noexcept; + /** Called when a non-empty array ends. */ + simdjson_warn_unused simdjson_inline error_code visit_array_end(json_iterator& iter) noexcept; + /** Called when an empty array is found. */ + simdjson_warn_unused simdjson_inline error_code visit_empty_array(json_iterator& iter) noexcept; + + /** Called when a non-empty object starts. */ + simdjson_warn_unused simdjson_inline error_code visit_object_start(json_iterator& iter) noexcept; + /** + * Called when a key in a field is encountered. + * + * primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array + * will be called after this with the field value. + */ + simdjson_warn_unused simdjson_inline error_code visit_key(json_iterator& iter, const uint8_t* key) noexcept; + /** Called when a non-empty object ends. */ + simdjson_warn_unused simdjson_inline error_code visit_object_end(json_iterator& iter) noexcept; + /** Called when an empty object is found. */ + simdjson_warn_unused simdjson_inline error_code visit_empty_object(json_iterator& iter) noexcept; + + /** + * Called when a string, number, boolean or null is found. + */ + simdjson_warn_unused simdjson_inline error_code visit_primitive(json_iterator& iter, const uint8_t* value) noexcept; + /** + * Called when a string, number, boolean or null is found at the top level of a document (i.e. + * when there is no array or object and the entire document is a single string, number, boolean or + * null. + * + * This is separate from primitive() because simdjson's normal primitive parsing routines assume + * there is at least one more token after the value, which is only true in an array or object. + */ + simdjson_warn_unused simdjson_inline error_code visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept; + + simdjson_warn_unused simdjson_inline error_code visit_string(json_iterator& iter, const uint8_t* value, bool key = false) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_number(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept; + + simdjson_warn_unused simdjson_inline error_code visit_root_string(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_number(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept; + simdjson_warn_unused simdjson_inline error_code visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept; + + /** Called each time a new field or element in an array or object is found. */ + simdjson_warn_unused simdjson_inline error_code increment_count(json_iterator& iter) noexcept; + + /** Next location to write to tape */ + tape_writer tape; + private: + /** Next write location in the string buf for stage 2 parsing */ + uint8_t* current_string_buf_loc; + + simdjson_inline tape_builder(dom::document& doc) noexcept; + + simdjson_inline uint32_t next_tape_index(json_iterator& iter) const noexcept; + simdjson_inline void start_container(json_iterator& iter) noexcept; + simdjson_warn_unused simdjson_inline error_code end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; + simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; + simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; + simdjson_inline void on_end_string(uint8_t* dst) noexcept; + }; // struct tape_builder + + template + simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( + dom_parser_implementation& dom_parser, + dom::document& doc) noexcept { + dom_parser.doc = &doc; + json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0); + tape_builder builder(doc); + return iter.walk_document(builder); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept { + return iter.visit_root_primitive(*this, value); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_primitive(json_iterator& iter, const uint8_t* value) noexcept { + return iter.visit_primitive(*this, value); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_object(json_iterator& iter) noexcept { + return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_array(json_iterator& iter) noexcept { + return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_start(json_iterator& iter) noexcept { + start_container(iter); + return SUCCESS; + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_start(json_iterator& iter) noexcept { + start_container(iter); + return SUCCESS; + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_start(json_iterator& iter) noexcept { + start_container(iter); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_end(json_iterator& iter) noexcept { + return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_end(json_iterator& iter) noexcept { + return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_end(json_iterator& iter) noexcept { + constexpr uint32_t start_tape_index = 0; + tape.append(start_tape_index, internal::tape_type::ROOT); + tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT); + return SUCCESS; + } + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_key(json_iterator& iter, const uint8_t* key) noexcept { + return visit_string(iter, key, true); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::increment_count(json_iterator& iter) noexcept { + iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1 + return SUCCESS; + } + + simdjson_inline tape_builder::tape_builder(dom::document& doc) noexcept : tape{ doc.tape.get() }, current_string_buf_loc{ doc.string_buf.get() } {} + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_string(json_iterator& iter, const uint8_t* value, bool key) noexcept { + iter.log_value(key ? "key" : "string"); + uint8_t* dst = on_start_string(iter); + dst = stringparsing::parse_string(value + 1, dst, false); // We do not allow replacement when the escape characters are invalid. + if (dst == nullptr) { + iter.log_error("Invalid escape in string"); + return STRING_ERROR; + } + on_end_string(dst); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_string(json_iterator& iter, const uint8_t* value) noexcept { + return visit_string(iter, value); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_number(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("number"); + return numberparsing::parse_number(value, tape); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_number(json_iterator& iter, const uint8_t* value) noexcept { + // + // We need to make a copy to make sure that the string is space terminated. + // This is not about padding the input, which should already padded up + // to len + SIMDJSON_PADDING. However, we have no control at this stage + // on how the padding was done. What if the input string was padded with nulls? + // It is quite common for an input string to have an extra null character (C string). + // We do not want to allow 9\0 (where \0 is the null character) inside a JSON + // document, but the string "9\0" by itself is fine. So we make a copy and + // pad the input with spaces when we know that there is just one input element. + // This copy is relatively expensive, but it will almost never be called in + // practice unless you are in the strange scenario where you have many JSON + // documents made of single atoms. + // + std::unique_ptrcopy(new (std::nothrow) uint8_t[iter.remaining_len() + SIMDJSON_PADDING]); + if (copy.get() == nullptr) { return MEMALLOC; } + std::memcpy(copy.get(), value, iter.remaining_len()); + std::memset(copy.get() + iter.remaining_len(), ' ', SIMDJSON_PADDING); + error_code error = visit_number(iter, copy.get()); + return error; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("true"); + if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; } + tape.append(0, internal::tape_type::TRUE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("true"); + if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; } + tape.append(0, internal::tape_type::TRUE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("false"); + if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; } + tape.append(0, internal::tape_type::FALSE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("false"); + if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; } + tape.append(0, internal::tape_type::FALSE_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("null"); + if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; } + tape.append(0, internal::tape_type::NULL_VALUE); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept { + iter.log_value("null"); + if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; } + tape.append(0, internal::tape_type::NULL_VALUE); + return SUCCESS; + } + + // private: + + simdjson_inline uint32_t tape_builder::next_tape_index(json_iterator& iter) const noexcept { + return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get()); + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { + auto start_index = next_tape_index(iter); + tape.append(start_index + 2, start); + tape.append(start_index, end); + return SUCCESS; + } + + simdjson_inline void tape_builder::start_container(json_iterator& iter) noexcept { + iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter); + iter.dom_parser.open_containers[iter.depth].count = 0; + tape.skip(); // We don't actually *write* the start element until the end. + } + + simdjson_warn_unused simdjson_inline error_code tape_builder::end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { + // Write the ending tape element, pointing at the start location + const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index; + tape.append(start_tape_index, end); + // Write the start tape element, pointing at the end location (and including count) + // count can overflow if it exceeds 24 bits... so we saturate + // the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff). + const uint32_t count = iter.dom_parser.open_containers[iter.depth].count; + const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count; + tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start); + return SUCCESS; + } + + simdjson_inline uint8_t* tape_builder::on_start_string(json_iterator& iter) noexcept { + // we advance the point, accounting for the fact that we have a NULL termination + tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING); + return current_string_buf_loc + sizeof(uint32_t); + } + + simdjson_inline void tape_builder::on_end_string(uint8_t* dst) noexcept { + uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t))); + // TODO check for overflow in case someone has a crazy string (>=4GB?) + // But only add the overflow check when the document itself exceeds 4GB + // Currently unneeded because we refuse to parse docs larger or equal to 4GB. + memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t)); + // NULL termination is still handy if you expect all your strings to + // be NULL terminated? It comes at a small cost + *dst = 0; + current_string_buf_loc = dst + 1; + } + + } // namespace stage2 + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H +/* end file generic/stage2/tape_builder.h for ppc64 */ +/* end file generic/stage2/amalgamated.h for ppc64 */ + +// +// Stage 1 +// namespace simdjson { namespace ppc64 { @@ -11842,38 +36471,10 @@ namespace simdjson { return SUCCESS; } - } // namespace ppc64 -} // namespace simdjson - -/* begin file include/simdjson/ppc64/end.h */ -/* end file include/simdjson/ppc64/end.h */ -/* end file src/ppc64/implementation.cpp */ -/* begin file src/ppc64/dom_parser_implementation.cpp */ -/* begin file include/simdjson/ppc64/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "ppc64" -// #define SIMDJSON_IMPLEMENTATION ppc64 -/* end file include/simdjson/ppc64/begin.h */ - -// -// Stage 1 -// -namespace simdjson { - namespace ppc64 { namespace { using namespace simd; - struct json_character_block { - static simdjson_inline json_character_block classify(const simd::simd8x64& in); - - simdjson_inline uint64_t whitespace() const noexcept { return _whitespace; } - simdjson_inline uint64_t op() const noexcept { return _op; } - simdjson_inline uint64_t scalar() const noexcept { return ~(op() | whitespace()); } - - uint64_t _whitespace; - uint64_t _op; - }; - simdjson_inline json_character_block json_character_block::classify(const simd::simd8x64& in) { const simd8 table1(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0); const simd8 table2(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0); @@ -11926,9 +36527,4747 @@ namespace simdjson { } // namespace ppc64 } // namespace simdjson -/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */ +// +// Stage 2 +// + +// +// Implementation-specific overrides +// namespace simdjson { namespace ppc64 { + + simdjson_warn_unused error_code implementation::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept { + return ppc64::stage1::json_minifier::minify<64>(buf, len, dst, dst_len); + } + + simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t* _buf, size_t _len, stage1_mode streaming) noexcept { + this->buf = _buf; + this->len = _len; + return ppc64::stage1::json_structural_indexer::index<64>(buf, len, *this, streaming); + } + + simdjson_warn_unused bool implementation::validate_utf8(const char* buf, size_t len) const noexcept { + return ppc64::stage1::generic_validate_utf8(buf, len); + } + + simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document& _doc) noexcept { + return stage2::tape_builder::parse_document(*this, _doc); + } + + simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document& _doc) noexcept { + return stage2::tape_builder::parse_document(*this, _doc); + } + + simdjson_warn_unused uint8_t* dom_parser_implementation::parse_string(const uint8_t* src, uint8_t* dst, bool replacement_char) const noexcept { + return ppc64::stringparsing::parse_string(src, dst, replacement_char); + } + + simdjson_warn_unused uint8_t* dom_parser_implementation::parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept { + return ppc64::stringparsing::parse_wobbly_string(src, dst); + } + + simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t* _buf, size_t _len, dom::document& _doc) noexcept { + auto error = stage1(_buf, _len, stage1_mode::regular); + if (error) { return error; } + return stage2(_doc); + } + + } // namespace ppc64 +} // namespace simdjson + +/* including simdjson/ppc64/end.h: #include */ +/* begin file simdjson/ppc64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "ppc64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/ppc64/end.h */ + +#endif // SIMDJSON_SRC_PPC64_CPP +/* end file ppc64.cpp */ +#endif +#if SIMDJSON_IMPLEMENTATION_WESTMERE +/* including westmere.cpp: #include */ +/* begin file westmere.cpp */ +#ifndef SIMDJSON_SRC_WESTMERE_CPP +#define SIMDJSON_SRC_WESTMERE_CPP + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* including simdjson/westmere.h: #include */ +/* begin file simdjson/westmere.h */ +#ifndef SIMDJSON_WESTMERE_H +#define SIMDJSON_WESTMERE_H + +/* including simdjson/westmere/begin.h: #include "simdjson/westmere/begin.h" */ +/* begin file simdjson/westmere/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "westmere" */ +#define SIMDJSON_IMPLEMENTATION westmere +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + /** + * Implementation for Westmere (Intel SSE4.2). + */ + namespace westmere { + + class implementation; + + namespace { + namespace simd { + + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ +#ifndef SIMDJSON_WESTMERE_INTRINSICS_H +#define SIMDJSON_WESTMERE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + */ +#include // for _mm_alignr_epi8 +#include // for _mm_clmulepi64_si128 +#endif + +static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); + +#endif // SIMDJSON_WESTMERE_INTRINSICS_H +/* end file simdjson/westmere/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_TARGET_REGION("sse4.2,pclmul,popcnt") +#endif + +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ +#ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H +#define SIMDJSON_WESTMERE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMANIPULATION_H +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/bitmask.h: #include "simdjson/westmere/bitmask.h" */ +/* begin file simdjson/westmere/bitmask.h */ +#ifndef SIMDJSON_WESTMERE_BITMASK_H +#define SIMDJSON_WESTMERE_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processing supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMASK_H +/* end file simdjson/westmere/bitmask.h */ +/* including simdjson/westmere/numberparsing_defs.h: #include "simdjson/westmere/numberparsing_defs.h" */ +/* begin file simdjson/westmere/numberparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +#define SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H + +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + /** + * Implementation for Westmere (Intel SSE4.2). + */ + namespace westmere { + + class implementation; + + namespace { + namespace simd { + + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ +#ifndef SIMDJSON_WESTMERE_INTRINSICS_H +#define SIMDJSON_WESTMERE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + */ +#include // for _mm_alignr_epi8 +#include // for _mm_clmulepi64_si128 +#endif + +static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); + +#endif // SIMDJSON_WESTMERE_INTRINSICS_H +/* end file simdjson/westmere/intrinsics.h */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace westmere +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +/* end file simdjson/westmere/numberparsing_defs.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ +#ifndef SIMDJSON_WESTMERE_SIMD_H +#define SIMDJSON_WESTMERE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace simd { + + template + struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { return this->value; } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm_or_si128(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm_and_si128(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm_xor_si128(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm_andnot_si128(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + template> + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm_alignr_epi8(*this, prev_chunk, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm_testz_si128(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm_setzero_si128(); } + static simdjson_inline simd8 load(const T values[16]) { + return _mm_loadu_si128(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { return _mm_storeu_si128(reinterpret_cast<__m128i*>(dst), *this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m128i shufmask = _mm_set_epi64x(thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask + shufmask = + _mm_add_epi8(shufmask, _mm_set_epi32(0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m128i pruned = _mm_shuffle_epi8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = _mm_shuffle_epi8(pruned, compactmask); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), answer); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epu8(*this, other); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm_testz_si128(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm_testz_si128(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm_movemask_epi8(_mm_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "Westmere kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_SIMD_INPUT_H +/* end file simdjson/westmere/simd.h */ +/* including simdjson/westmere/stringparsing_defs.h: #include "simdjson/westmere/stringparsing_defs.h" */ +/* begin file simdjson/westmere/stringparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +#define SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H + +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ +#ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H +#define SIMDJSON_WESTMERE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMANIPULATION_H +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ +#ifndef SIMDJSON_WESTMERE_SIMD_H +#define SIMDJSON_WESTMERE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace simd { + + template + struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { return this->value; } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm_or_si128(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm_and_si128(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm_xor_si128(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm_andnot_si128(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + template> + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm_alignr_epi8(*this, prev_chunk, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm_testz_si128(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm_setzero_si128(); } + static simdjson_inline simd8 load(const T values[16]) { + return _mm_loadu_si128(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { return _mm_storeu_si128(reinterpret_cast<__m128i*>(dst), *this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m128i shufmask = _mm_set_epi64x(thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask + shufmask = + _mm_add_epi8(shufmask, _mm_set_epi32(0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m128i pruned = _mm_shuffle_epi8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = _mm_shuffle_epi8(pruned, compactmask); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), answer); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epu8(*this, other); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm_testz_si128(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm_testz_si128(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm_movemask_epi8(_mm_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "Westmere kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_SIMD_INPUT_H +/* end file simdjson/westmere/simd.h */ + +namespace simdjson { + namespace westmere { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + 16); + v0.store(dst); + v1.store(dst + 16); + uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +/* end file simdjson/westmere/stringparsing_defs.h */ +/* end file simdjson/westmere/begin.h */ +/* including simdjson/generic/amalgamated.h for westmere: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for westmere */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for westmere: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for westmere */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for westmere */ +/* including simdjson/generic/jsoncharutils.h for westmere: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for westmere */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace jsoncharutils { + + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for westmere */ +/* including simdjson/generic/atomparsing.h for westmere: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for westmere */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace westmere { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for westmere */ +/* including simdjson/generic/dom_parser_implementation.h for westmere: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for westmere */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container + + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); + + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; + + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; + + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; + + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + namespace westmere { + + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; + } + + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for westmere */ +/* including simdjson/generic/implementation_simdjson_result_base.h for westmere: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for westmere */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); + + +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for westmere */ +/* including simdjson/generic/numberparsing.h for westmere: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for westmere */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace westmere { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing +// +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. +// +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for westmere */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for westmere: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for westmere */ +/* end file simdjson/generic/amalgamated.h for westmere */ +/* including simdjson/westmere/end.h: #include "simdjson/westmere/end.h" */ +/* begin file simdjson/westmere/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "westmere" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/westmere/end.h */ + +#endif // SIMDJSON_WESTMERE_H +/* end file simdjson/westmere.h */ +/* including simdjson/westmere/implementation.h: #include */ +/* begin file simdjson/westmere/implementation.h */ +#ifndef SIMDJSON_WESTMERE_IMPLEMENTATION_H +#define SIMDJSON_WESTMERE_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + namespace westmere { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation("westmere", "Intel/AMD SSE4.2", internal::instruction_set::SSE42 | internal::instruction_set::PCLMULQDQ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_IMPLEMENTATION_H +/* end file simdjson/westmere/implementation.h */ + +/* including simdjson/westmere/begin.h: #include */ +/* begin file simdjson/westmere/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "westmere" */ +#define SIMDJSON_IMPLEMENTATION westmere +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + /** + * Implementation for Westmere (Intel SSE4.2). + */ + namespace westmere { + + class implementation; + + namespace { + namespace simd { + + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ +#ifndef SIMDJSON_WESTMERE_INTRINSICS_H +#define SIMDJSON_WESTMERE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + */ +#include // for _mm_alignr_epi8 +#include // for _mm_clmulepi64_si128 +#endif + +static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); + +#endif // SIMDJSON_WESTMERE_INTRINSICS_H +/* end file simdjson/westmere/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_TARGET_REGION("sse4.2,pclmul,popcnt") +#endif + +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ +#ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H +#define SIMDJSON_WESTMERE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMANIPULATION_H +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/bitmask.h: #include "simdjson/westmere/bitmask.h" */ +/* begin file simdjson/westmere/bitmask.h */ +#ifndef SIMDJSON_WESTMERE_BITMASK_H +#define SIMDJSON_WESTMERE_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processing supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMASK_H +/* end file simdjson/westmere/bitmask.h */ +/* including simdjson/westmere/numberparsing_defs.h: #include "simdjson/westmere/numberparsing_defs.h" */ +/* begin file simdjson/westmere/numberparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +#define SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H + +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + /** + * Implementation for Westmere (Intel SSE4.2). + */ + namespace westmere { + + class implementation; + + namespace { + namespace simd { + + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ +#ifndef SIMDJSON_WESTMERE_INTRINSICS_H +#define SIMDJSON_WESTMERE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + */ +#include // for _mm_alignr_epi8 +#include // for _mm_clmulepi64_si128 +#endif + +static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); + +#endif // SIMDJSON_WESTMERE_INTRINSICS_H +/* end file simdjson/westmere/intrinsics.h */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace westmere +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +/* end file simdjson/westmere/numberparsing_defs.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ +#ifndef SIMDJSON_WESTMERE_SIMD_H +#define SIMDJSON_WESTMERE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace simd { + + template + struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { return this->value; } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm_or_si128(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm_and_si128(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm_xor_si128(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm_andnot_si128(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + template> + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm_alignr_epi8(*this, prev_chunk, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm_testz_si128(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm_setzero_si128(); } + static simdjson_inline simd8 load(const T values[16]) { + return _mm_loadu_si128(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { return _mm_storeu_si128(reinterpret_cast<__m128i*>(dst), *this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m128i shufmask = _mm_set_epi64x(thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask + shufmask = + _mm_add_epi8(shufmask, _mm_set_epi32(0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m128i pruned = _mm_shuffle_epi8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = _mm_shuffle_epi8(pruned, compactmask); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), answer); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epu8(*this, other); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm_testz_si128(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm_testz_si128(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm_movemask_epi8(_mm_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "Westmere kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_SIMD_INPUT_H +/* end file simdjson/westmere/simd.h */ +/* including simdjson/westmere/stringparsing_defs.h: #include "simdjson/westmere/stringparsing_defs.h" */ +/* begin file simdjson/westmere/stringparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +#define SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H + +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ +#ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H +#define SIMDJSON_WESTMERE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMANIPULATION_H +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ +#ifndef SIMDJSON_WESTMERE_SIMD_H +#define SIMDJSON_WESTMERE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace simd { + + template + struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { return this->value; } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm_or_si128(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm_and_si128(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm_xor_si128(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm_andnot_si128(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + template> + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm_alignr_epi8(*this, prev_chunk, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm_testz_si128(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm_setzero_si128(); } + static simdjson_inline simd8 load(const T values[16]) { + return _mm_loadu_si128(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { return _mm_storeu_si128(reinterpret_cast<__m128i*>(dst), *this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m128i shufmask = _mm_set_epi64x(thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask + shufmask = + _mm_add_epi8(shufmask, _mm_set_epi32(0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m128i pruned = _mm_shuffle_epi8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = _mm_shuffle_epi8(pruned, compactmask); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), answer); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epu8(*this, other); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm_testz_si128(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm_testz_si128(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm_movemask_epi8(_mm_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "Westmere kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_SIMD_INPUT_H +/* end file simdjson/westmere/simd.h */ + +namespace simdjson { + namespace westmere { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + 16); + v0.store(dst); + v1.store(dst + 16); + uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +/* end file simdjson/westmere/stringparsing_defs.h */ +/* end file simdjson/westmere/begin.h */ +/* including generic/amalgamated.h for westmere: #include */ +/* begin file generic/amalgamated.h for westmere */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_SRC_GENERIC_DEPENDENCIES_H) +#error generic/dependencies.h must be included before generic/amalgamated.h! +#endif + +/* including generic/base.h for westmere: #include */ +/* begin file generic/base.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + struct json_character_block; + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_BASE_H +/* end file generic/base.h for westmere */ +/* including generic/dom_parser_implementation.h for westmere: #include */ +/* begin file generic/dom_parser_implementation.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// Interface a dom parser implementation must fulfill +namespace simdjson { + namespace westmere { + namespace { + + simdjson_inline simd8 must_be_2_3_continuation(const simd8 prev2, const simd8 prev3); + simdjson_inline bool is_ascii(const simd8x64& input); + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file generic/dom_parser_implementation.h for westmere */ +/* including generic/json_character_block.h for westmere: #include */ +/* begin file generic/json_character_block.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + struct json_character_block { + static simdjson_inline json_character_block classify(const simd::simd8x64& in); + + simdjson_inline uint64_t whitespace() const noexcept { return _whitespace; } + simdjson_inline uint64_t op() const noexcept { return _op; } + simdjson_inline uint64_t scalar() const noexcept { return ~(op() | whitespace()); } + + uint64_t _whitespace; + uint64_t _op; + }; + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_JSON_CHARACTER_BLOCK_H +/* end file generic/json_character_block.h for westmere */ +/* end file generic/amalgamated.h for westmere */ +/* including generic/stage1/amalgamated.h for westmere: #include */ +/* begin file generic/stage1/amalgamated.h for westmere */ +// Stuff other things depend on +/* including generic/stage1/base.h for westmere: #include */ +/* begin file generic/stage1/base.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace stage1 { + + class bit_indexer; + template + struct buf_block_reader; + struct json_block; + class json_minifier; + class json_scanner; + struct json_string_block; + class json_string_scanner; + class json_structural_indexer; + + } // namespace stage1 + + namespace utf8_validation { + struct utf8_checker; + } // namespace utf8_validation + + using utf8_validation::utf8_checker; + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BASE_H +/* end file generic/stage1/base.h for westmere */ +/* including generic/stage1/buf_block_reader.h for westmere: #include */ +/* begin file generic/stage1/buf_block_reader.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace westmere { + namespace { + namespace stage1 { + + // Walks through a buffer in block-sized increments, loading the last part with spaces + template + struct buf_block_reader { + public: + simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); + simdjson_inline size_t block_index(); + simdjson_inline bool has_full_block() const; + simdjson_inline const uint8_t* full_block() const; + /** + * Get the last block, padded with spaces. + * + * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this + * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there + * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. + * + * @return the number of effective characters in the last block. + */ + simdjson_inline size_t get_remainder(uint8_t* dst) const; + simdjson_inline void advance(); + private: + const uint8_t* buf; + const size_t len; + const size_t lenminusstep; + size_t idx; + }; + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text_64(const uint8_t* text) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < sizeof(simd8x64); i++) { + buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + // Routines to print masks and text for debugging bitmask operations + simdjson_unused static char* format_input_text(const simd8x64& in) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] < ' ') { buf[i] = '_'; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_input_text(const simd8x64& in, uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + in.store(reinterpret_cast(buf)); + for (size_t i = 0; i < sizeof(simd8x64); i++) { + if (buf[i] <= ' ') { buf[i] = '_'; } + if (!(mask & (size_t(1) << i))) { buf[i] = ' '; } + } + buf[sizeof(simd8x64)] = '\0'; + return buf; + } + + simdjson_unused static char* format_mask(uint64_t mask) { + static char buf[sizeof(simd8x64) + 1]; + for (size_t i = 0; i < 64; i++) { + buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; + } + buf[64] = '\0'; + return buf; + } + + template + simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} + + template + simdjson_inline size_t buf_block_reader::block_index() { return idx; } + + template + simdjson_inline bool buf_block_reader::has_full_block() const { + return idx < lenminusstep; + } + + template + simdjson_inline const uint8_t* buf_block_reader::full_block() const { + return &buf[idx]; + } + + template + simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { + if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers + std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. + std::memcpy(dst, buf + idx, len - idx); + return len - idx; + } + + template + simdjson_inline void buf_block_reader::advance() { + idx += STEP_SIZE; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_BUF_BLOCK_READER_H +/* end file generic/stage1/buf_block_reader.h for westmere */ +/* including generic/stage1/json_escape_scanner.h for westmere: #include */ +/* begin file generic/stage1/json_escape_scanner.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_ESCAPE_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace stage1 { + + /** + * Scans for escape characters in JSON, taking care with multiple backslashes (\\n vs. \n). + */ + struct json_escape_scanner { + /** The actual escape characters (the backslashes themselves). */ + uint64_t next_is_escaped = 0ULL; + + struct escaped_and_escape { + /** + * Mask of escaped characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 0100100010100101000 + * n \ \ n \ \ + * ``` + */ + uint64_t escaped; + /** + * Mask of escape characters. + * + * ``` + * \n \\n \\\n \\\\n \ + * 1001000101001010001 + * \ \ \ \ \ \ \ + * ``` + */ + uint64_t escape; + }; + + /** + * Get a mask of both escape and escaped characters (the characters following a backslash). + * + * @param potential_escape A mask of the character that can escape others (but could be + * escaped itself). e.g. block.eq('\\') + */ + simdjson_really_inline escaped_and_escape next(uint64_t backslash) noexcept { + +#if !SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT + if (!backslash) { return { next_escaped_without_backslashes(), 0 }; } +#endif + + // | | Mask (shows characters instead of 1's) | Depth | Instructions | + // |--------------------------------|----------------------------------------|-------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | | | + // | | ` even odd even odd odd` | | | + // | potential_escape | ` \ \\\ \\\ \\\\ \\\\ \\\` | 1 | 1 (backslash & ~first_is_escaped) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 5 | 5 (next_escape_and_terminal_code()) + // | escaped | `\ \ n \ n \ \ \ \ \ ` X | 6 | 7 (escape_and_terminal_code ^ (potential_escape | first_is_escaped)) + // | escape | ` \ \ \ \ \ \ \ \ \ \` | 6 | 8 (escape_and_terminal_code & backslash) + // | first_is_escaped | `\ ` | 7 (*) | 9 (escape >> 63) () + // (*) this is not needed until the next iteration + uint64_t escape_and_terminal_code = next_escape_and_terminal_code(backslash & ~this->next_is_escaped); + uint64_t escaped = escape_and_terminal_code ^ (backslash | this->next_is_escaped); + uint64_t escape = escape_and_terminal_code & backslash; + this->next_is_escaped = escape >> 63; + return { escaped, escape }; + } + + private: + static constexpr const uint64_t ODD_BITS = 0xAAAAAAAAAAAAAAAAULL; + + simdjson_really_inline uint64_t next_escaped_without_backslashes() noexcept { + uint64_t escaped = this->next_is_escaped; + this->next_is_escaped = 0; + return escaped; + } + + /** + * Returns a mask of the next escape characters (masking out escaped backslashes), along with + * any non-backslash escape codes. + * + * \n \\n \\\n \\\\n returns: + * \n \ \ \n \ \ + * 11 100 1011 10100 + * + * You are expected to mask out the first bit yourself if the previous block had a trailing + * escape. + * + * & the result with potential_escape to get just the escape characters. + * ^ the result with (potential_escape | first_is_escaped) to get escaped characters. + */ + static simdjson_really_inline uint64_t next_escape_and_terminal_code(uint64_t potential_escape) noexcept { + // If we were to just shift and mask out any odd bits, we'd actually get a *half* right answer: + // any even-aligned backslash runs would be correct! Odd-aligned backslash runs would be + // inverted (\\\ would be 010 instead of 101). + // + // ``` + // string: | ____\\\\_\\\\_____ | + // maybe_escaped | ODD | \ \ \ \ | + // even-aligned ^^^ ^^^^ odd-aligned + // ``` + // + // Taking that into account, our basic strategy is: + // + // 1. Use subtraction to produce a mask with 1's for even-aligned runs and 0's for + // odd-aligned runs. + // 2. XOR all odd bits, which masks out the odd bits in even-aligned runs, and brings IN the + // odd bits in odd-aligned runs. + // 3. & with backslash to clean up any stray bits. + // runs are set to 0, and then XORing with "odd": + // + // | | Mask (shows characters instead of 1's) | Instructions | + // |--------------------------------|----------------------------------------|---------------------| + // | string | `\\n_\\\n___\\\n___\\\\___\\\\__\\\` | + // | | ` even odd even odd odd` | + // | maybe_escaped | ` n \\n \\n \\\_ \\\_ \\` X | 1 (potential_escape << 1) + // | maybe_escaped_and_odd | ` \n_ \\n _ \\\n_ _ \\\__ _\\\_ \\\` | 1 (maybe_escaped | odd) + // | even_series_codes_and_odd | ` n_\\\ _ n_ _\\\\ _ _ ` | 1 (maybe_escaped_and_odd - potential_escape) + // | escape_and_terminal_code | ` \n \ \n \ \n \ \ \ \ \ \` | 1 (^ odd) + // + + // Escaped characters are characters following an escape. + uint64_t maybe_escaped = potential_escape << 1; + + // To distinguish odd from even escape sequences, therefore, we turn on any *starting* + // escapes that are on an odd byte. (We actually bring in all odd bits, for speed.) + // - Odd runs of backslashes are 0000, and the code at the end ("n" in \n or \\n) is 1. + // - Odd runs of backslashes are 1111, and the code at the end ("n" in \n or \\n) is 0. + // - All other odd bytes are 1, and even bytes are 0. + uint64_t maybe_escaped_and_odd_bits = maybe_escaped | ODD_BITS; + uint64_t even_series_codes_and_odd_bits = maybe_escaped_and_odd_bits - potential_escape; + + // Now we flip all odd bytes back with xor. This: + // - Makes odd runs of backslashes go from 0000 to 1010 + // - Makes even runs of backslashes go from 1111 to 1010 + // - Sets actually-escaped codes to 1 (the n in \n and \\n: \n = 11, \\n = 100) + // - Resets all other bytes to 0 + return even_series_codes_and_odd_bits ^ ODD_BITS; + } + }; + + } // namespace stage1 + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_escape_scanner.h for westmere */ +/* including generic/stage1/json_string_scanner.h for westmere: #include */ +/* begin file generic/stage1/json_string_scanner.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace stage1 { + + struct json_string_block { + // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 + simdjson_really_inline json_string_block(uint64_t escaped, uint64_t quote, uint64_t in_string) : + _escaped(escaped), _quote(quote), _in_string(in_string) {} + + // Escaped characters (characters following an escape() character) + simdjson_really_inline uint64_t escaped() const { return _escaped; } + // Real (non-backslashed) quotes + simdjson_really_inline uint64_t quote() const { return _quote; } + // Only characters inside the string (not including the quotes) + simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } + // Return a mask of whether the given characters are inside a string (only works on non-quotes) + simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } + // Tail of string (everything except the start quote) + simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; } + + // escaped characters (backslashed--does not include the hex characters after \u) + uint64_t _escaped; + // real quotes (non-escaped ones) + uint64_t _quote; + // string characters (includes start quote but not end quote) + uint64_t _in_string; + }; + + // Scans blocks for string characters, storing the state necessary to do so + class json_string_scanner { + public: + simdjson_really_inline json_string_block next(const simd::simd8x64& in); + // Returns either UNCLOSED_STRING or SUCCESS + simdjson_really_inline error_code finish(); + + private: + // Scans for escape characters + json_escape_scanner escape_scanner{}; + // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). + uint64_t prev_in_string = 0ULL; + }; + + // + // Return a mask of all string characters plus end quotes. + // + // prev_escaped is overflow saying whether the next character is escaped. + // prev_in_string is overflow saying whether we're still in a string. + // + // Backslash sequences outside of quotes will be detected in stage 2. + // + simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { + const uint64_t backslash = in.eq('\\'); + const uint64_t escaped = escape_scanner.next(backslash).escaped; + const uint64_t quote = in.eq('"') & ~escaped; + + // + // prefix_xor flips on bits inside the string (and flips off the end quote). + // + // Then we xor with prev_in_string: if we were in a string already, its effect is flipped + // (characters inside strings are outside, and characters outside strings are inside). + // + const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; + + // + // Check if we're still in a string at the end of the box so the next block will know + // + prev_in_string = uint64_t(static_cast(in_string) >> 63); + + // Use ^ to turn the beginning quote off, and the end quote on. + + // We are returning a function-local object so either we get a move constructor + // or we get copy elision. + return json_string_block(escaped, quote, in_string); + } + + simdjson_really_inline error_code json_string_scanner::finish() { + if (prev_in_string) { + return UNCLOSED_STRING; + } + return SUCCESS; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRING_SCANNER_H +/* end file generic/stage1/json_string_scanner.h for westmere */ +/* including generic/stage1/utf8_lookup4_algorithm.h for westmere: #include */ +/* begin file generic/stage1/utf8_lookup4_algorithm.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { namespace { namespace utf8_validation { @@ -12091,14 +41430,6 @@ namespace simdjson { this->error |= this->prev_incomplete; } -#ifndef SIMDJSON_IF_CONSTEXPR -#if SIMDJSON_CPLUSPLUS17 -#define SIMDJSON_IF_CONSTEXPR if constexpr -#else -#define SIMDJSON_IF_CONSTEXPR if -#endif -#endif - simdjson_inline void check_next_input(const simd8x64& input) { if (simdjson_likely(is_ascii(input))) { this->error |= this->prev_incomplete; @@ -12113,17 +41444,17 @@ namespace simdjson { this->check_utf8_bytes(input.chunks[0], this->prev_input_block); } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - } + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + } else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 4) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - this->check_utf8_bytes(input.chunks[2], input.chunks[1]); - this->check_utf8_bytes(input.chunks[3], input.chunks[2]); - } - this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); - this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; + this->check_utf8_bytes(input.chunks[0], this->prev_input_block); + this->check_utf8_bytes(input.chunks[1], input.chunks[0]); + this->check_utf8_bytes(input.chunks[2], input.chunks[1]); + this->check_utf8_bytes(input.chunks[3], input.chunks[2]); + } + this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); + this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; } } // do not forget to call check_eof! @@ -12134,270 +41465,25 @@ else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { }; // struct utf8_checker } // namespace utf8_validation - using utf8_validation::utf8_checker; - } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage1/utf8_lookup4_algorithm.h */ -/* begin file src/generic/stage1/json_structural_indexer.h */ -// This file contains the common code every implementation uses in stage1 -// It is intended to be included multiple times and compiled multiple times -// We assume the file in which it is included already includes -// "simdjson/stage1.h" (this simplifies amalgation) -/* begin file src/generic/stage1/buf_block_reader.h */ +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_LOOKUP4_ALGORITHM_H +/* end file generic/stage1/utf8_lookup4_algorithm.h for westmere */ +/* including generic/stage1/json_scanner.h for westmere: #include */ +/* begin file generic/stage1/json_scanner.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace ppc64 { - namespace { - - // Walks through a buffer in block-sized increments, loading the last part with spaces - template - struct buf_block_reader { - public: - simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); - simdjson_inline size_t block_index(); - simdjson_inline bool has_full_block() const; - simdjson_inline const uint8_t* full_block() const; - /** - * Get the last block, padded with spaces. - * - * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this - * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there - * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. - * - * @return the number of effective characters in the last block. - */ - simdjson_inline size_t get_remainder(uint8_t* dst) const; - simdjson_inline void advance(); - private: - const uint8_t* buf; - const size_t len; - const size_t lenminusstep; - size_t idx; - }; - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text_64(const uint8_t* text) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < sizeof(simd8x64); i++) { - buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text(const simd8x64& in) { - static char buf[sizeof(simd8x64) + 1]; - in.store(reinterpret_cast(buf)); - for (size_t i = 0; i < sizeof(simd8x64); i++) { - if (buf[i] < ' ') { buf[i] = '_'; } - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - simdjson_unused static char* format_mask(uint64_t mask) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < 64; i++) { - buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; - } - buf[64] = '\0'; - return buf; - } - - template - simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} - - template - simdjson_inline size_t buf_block_reader::block_index() { return idx; } - - template - simdjson_inline bool buf_block_reader::has_full_block() const { - return idx < lenminusstep; - } - - template - simdjson_inline const uint8_t* buf_block_reader::full_block() const { - return &buf[idx]; - } - - template - simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { - if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers - std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. - std::memcpy(dst, buf + idx, len - idx); - return len - idx; - } - - template - simdjson_inline void buf_block_reader::advance() { - idx += STEP_SIZE; - } - - } // unnamed namespace - } // namespace ppc64 -} // namespace simdjson -/* end file src/generic/stage1/buf_block_reader.h */ -/* begin file src/generic/stage1/json_string_scanner.h */ -namespace simdjson { - namespace ppc64 { - namespace { - namespace stage1 { - - struct json_string_block { - // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 - simdjson_inline json_string_block(uint64_t backslash, uint64_t escaped, uint64_t quote, uint64_t in_string) : - _backslash(backslash), _escaped(escaped), _quote(quote), _in_string(in_string) {} - - // Escaped characters (characters following an escape() character) - simdjson_inline uint64_t escaped() const { return _escaped; } - // Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \) - simdjson_inline uint64_t escape() const { return _backslash & ~_escaped; } - // Real (non-backslashed) quotes - simdjson_inline uint64_t quote() const { return _quote; } - // Start quotes of strings - simdjson_inline uint64_t string_start() const { return _quote & _in_string; } - // End quotes of strings - simdjson_inline uint64_t string_end() const { return _quote & ~_in_string; } - // Only characters inside the string (not including the quotes) - simdjson_inline uint64_t string_content() const { return _in_string & ~_quote; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } - // Tail of string (everything except the start quote) - simdjson_inline uint64_t string_tail() const { return _in_string ^ _quote; } - - // backslash characters - uint64_t _backslash; - // escaped characters (backslashed--does not include the hex characters after \u) - uint64_t _escaped; - // real quotes (non-backslashed ones) - uint64_t _quote; - // string characters (includes start quote but not end quote) - uint64_t _in_string; - }; - - // Scans blocks for string characters, storing the state necessary to do so - class json_string_scanner { - public: - simdjson_inline json_string_block next(const simd::simd8x64& in); - // Returns either UNCLOSED_STRING or SUCCESS - simdjson_inline error_code finish(); - - private: - // Intended to be defined by the implementation - simdjson_inline uint64_t find_escaped(uint64_t escape); - simdjson_inline uint64_t find_escaped_branchless(uint64_t escape); - - // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). - uint64_t prev_in_string = 0ULL; - // Whether the first character of the next iteration is escaped. - uint64_t prev_escaped = 0ULL; - }; - - // - // Finds escaped characters (characters following \). - // - // Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively). - // - // Does this by: - // - Shift the escape mask to get potentially escaped characters (characters after backslashes). - // - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not) - // - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not) - // - // To distinguish between escaped sequences starting on even/odd bits, it finds the start of all - // escape sequences, filters out the ones that start on even bits, and adds that to the mask of - // escape sequences. This causes the addition to clear out the sequences starting on odd bits (since - // the start bit causes a carry), and leaves even-bit sequences alone. - // - // Example: - // - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape - // odd_starts | x | x x x | escape & ~even_bits & ~follows_escape - // even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later - // invert_mask | | cxxx c xx c| even_seq << 1 - // follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit - // escaped | x | x x x x x x x x | - // desired | x | x x x x x x x x | - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // - simdjson_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) { - // If there was overflow, pretend the first character isn't a backslash - backslash &= ~prev_escaped; - uint64_t follows_escape = backslash << 1 | prev_escaped; - - // Get sequences starting on even bits by clearing out the odd series using + - const uint64_t even_bits = 0x5555555555555555ULL; - uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape; - uint64_t sequences_starting_on_even_bits; - prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits); - uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes. - - // Mask every other backslashed character as an escaped character - // Flip the mask for sequences that start on even bits, to correct them - return (even_bits ^ invert_mask) & follows_escape; - } - - // - // Return a mask of all string characters plus end quotes. - // - // prev_escaped is overflow saying whether the next character is escaped. - // prev_in_string is overflow saying whether we're still in a string. - // - // Backslash sequences outside of quotes will be detected in stage 2. - // - simdjson_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { - const uint64_t backslash = in.eq('\\'); - const uint64_t escaped = find_escaped(backslash); - const uint64_t quote = in.eq('"') & ~escaped; - - // - // prefix_xor flips on bits inside the string (and flips off the end quote). - // - // Then we xor with prev_in_string: if we were in a string already, its effect is flipped - // (characters inside strings are outside, and characters outside strings are inside). - // - const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; - - // - // Check if we're still in a string at the end of the box so the next block will know - // - // right shift of a signed value expected to be well-defined and standard - // compliant as of C++20, John Regher from Utah U. says this is fine code - // - prev_in_string = uint64_t(static_cast(in_string) >> 63); - - // Use ^ to turn the beginning quote off, and the end quote on. - - // We are returning a function-local object so either we get a move constructor - // or we get copy elision. - return json_string_block( - backslash, - escaped, - quote, - in_string - ); - } - - simdjson_inline error_code json_string_scanner::finish() { - if (prev_in_string) { - return UNCLOSED_STRING; - } - return SUCCESS; - } - - } // namespace stage1 - } // unnamed namespace - } // namespace ppc64 -} // namespace simdjson -/* end file src/generic/stage1/json_string_scanner.h */ -/* begin file src/generic/stage1/json_scanner.h */ -namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { namespace stage1 { @@ -12551,17 +41637,139 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage1/json_scanner.h */ -/* begin file src/generic/stage1/json_minifier.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_SCANNER_H +/* end file generic/stage1/json_scanner.h for westmere */ + +// All other declarations +/* including generic/stage1/find_next_document_index.h for westmere: #include */ +/* begin file generic/stage1/find_next_document_index.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace stage1 { + + /** + * This algorithm is used to quickly identify the last structural position that + * makes up a complete document. + * + * It does this by going backwards and finding the last *document boundary* (a + * place where one value follows another without a comma between them). If the + * last document (the characters after the boundary) has an equal number of + * start and end brackets, it is considered complete. + * + * Simply put, we iterate over the structural characters, starting from + * the end. We consider that we found the end of a JSON document when the + * first element of the pair is NOT one of these characters: '{' '[' ':' ',' + * and when the second element is NOT one of these characters: '}' ']' ':' ','. + * + * This simple comparison works most of the time, but it does not cover cases + * where the batch's structural indexes contain a perfect amount of documents. + * In such a case, we do not have access to the structural index which follows + * the last document, therefore, we do not have access to the second element in + * the pair, and that means we cannot identify the last document. To fix this + * issue, we keep a count of the open and closed curly/square braces we found + * while searching for the pair. When we find a pair AND the count of open and + * closed curly/square braces is the same, we know that we just passed a + * complete document, therefore the last json buffer location is the end of the + * batch. + */ + simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { + // Variant: do not count separately, just figure out depth + if (parser.n_structural_indexes == 0) { return 0; } + auto arr_cnt = 0; + auto obj_cnt = 0; + for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { + auto idxb = parser.structural_indexes[i]; + switch (parser.buf[idxb]) { + case ':': + case ',': + continue; + case '}': + obj_cnt--; + continue; + case ']': + arr_cnt--; + continue; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + auto idxa = parser.structural_indexes[i - 1]; + switch (parser.buf[idxa]) { + case '{': + case '[': + case ':': + case ',': + continue; + } + // Last document is complete, so the next document will appear after! + if (!arr_cnt && !obj_cnt) { + return parser.n_structural_indexes; + } + // Last document is incomplete; mark the document at i + 1 as the next one + return i; + } + // If we made it to the end, we want to finish counting to see if we have a full document. + switch (parser.buf[parser.structural_indexes[0]]) { + case '}': + obj_cnt--; + break; + case ']': + arr_cnt--; + break; + case '{': + obj_cnt++; + break; + case '[': + arr_cnt++; + break; + } + if (!arr_cnt && !obj_cnt) { + // We have a complete document. + return parser.n_structural_indexes; + } + return 0; + } + + } // namespace stage1 + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_FIND_NEXT_DOCUMENT_INDEX_H +/* end file generic/stage1/find_next_document_index.h for westmere */ +/* including generic/stage1/json_minifier.h for westmere: #include */ +/* begin file generic/stage1/json_minifier.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + // This file contains the common code every implementation uses in stage1 // It is intended to be included multiple times and compiled multiple times // We assume the file in which it is included already includes // "simdjson/stage1.h" (this simplifies amalgation) namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { namespace stage1 { @@ -12646,107 +41854,33 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage1/json_minifier.h */ -/* begin file src/generic/stage1/find_next_document_index.h */ -namespace simdjson { - namespace ppc64 { - namespace { - /** - * This algorithm is used to quickly identify the last structural position that - * makes up a complete document. - * - * It does this by going backwards and finding the last *document boundary* (a - * place where one value follows another without a comma between them). If the - * last document (the characters after the boundary) has an equal number of - * start and end brackets, it is considered complete. - * - * Simply put, we iterate over the structural characters, starting from - * the end. We consider that we found the end of a JSON document when the - * first element of the pair is NOT one of these characters: '{' '[' ':' ',' - * and when the second element is NOT one of these characters: '}' ']' ':' ','. - * - * This simple comparison works most of the time, but it does not cover cases - * where the batch's structural indexes contain a perfect amount of documents. - * In such a case, we do not have access to the structural index which follows - * the last document, therefore, we do not have access to the second element in - * the pair, and that means we cannot identify the last document. To fix this - * issue, we keep a count of the open and closed curly/square braces we found - * while searching for the pair. When we find a pair AND the count of open and - * closed curly/square braces is the same, we know that we just passed a - * complete document, therefore the last json buffer location is the end of the - * batch. - */ - simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { - // Variant: do not count separately, just figure out depth - if (parser.n_structural_indexes == 0) { return 0; } - auto arr_cnt = 0; - auto obj_cnt = 0; - for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { - auto idxb = parser.structural_indexes[i]; - switch (parser.buf[idxb]) { - case ':': - case ',': - continue; - case '}': - obj_cnt--; - continue; - case ']': - arr_cnt--; - continue; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - auto idxa = parser.structural_indexes[i - 1]; - switch (parser.buf[idxa]) { - case '{': - case '[': - case ':': - case ',': - continue; - } - // Last document is complete, so the next document will appear after! - if (!arr_cnt && !obj_cnt) { - return parser.n_structural_indexes; - } - // Last document is incomplete; mark the document at i + 1 as the next one - return i; - } - // If we made it to the end, we want to finish counting to see if we have a full document. - switch (parser.buf[parser.structural_indexes[0]]) { - case '}': - obj_cnt--; - break; - case ']': - arr_cnt--; - break; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - if (!arr_cnt && !obj_cnt) { - // We have a complete document. - return parser.n_structural_indexes; - } - return 0; - } +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_MINIFIER_H +/* end file generic/stage1/json_minifier.h for westmere */ +/* including generic/stage1/json_structural_indexer.h for westmere: #include */ +/* begin file generic/stage1/json_structural_indexer.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H - } // unnamed namespace - } // namespace ppc64 -} // namespace simdjson -/* end file src/generic/stage1/find_next_document_index.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses in stage1 +// It is intended to be included multiple times and compiled multiple times +// We assume the file in which it is included already includes +// "simdjson/stage1.h" (this simplifies amalgation) namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { namespace stage1 { @@ -12756,15 +41890,67 @@ namespace simdjson { simdjson_inline bit_indexer(uint32_t* index_buf) : tail(index_buf) {} +#if SIMDJSON_PREFER_REVERSE_BITS + /** + * ARM lacks a fast trailing zero instruction, but it has a fast + * bit reversal instruction and a fast leading zero instruction. + * Thus it may be profitable to reverse the bits (once) and then + * to rely on a sequence of instructions that call the leading + * zero instruction. + * + * Performance notes: + * The chosen routine is not optimal in terms of data dependency + * since zero_leading_bit might require two instructions. However, + * it tends to minimize the total number of instructions which is + * beneficial. + */ + simdjson_inline void write_index(uint32_t idx, uint64_t& rev_bits, int i) { + int lz = leading_zeroes(rev_bits); + this->tail[i] = static_cast(idx) + lz; + rev_bits = zero_leading_bit(rev_bits, lz); + } +#else + /** + * Under recent x64 systems, we often have both a fast trailing zero + * instruction and a fast 'clear-lower-bit' instruction so the following + * algorithm can be competitive. + */ + + simdjson_inline void write_index(uint32_t idx, uint64_t& bits, int i) { + this->tail[i] = idx + trailing_zeroes(bits); + bits = clear_lowest_bit(bits); + } +#endif // SIMDJSON_PREFER_REVERSE_BITS + + template + simdjson_inline int write_indexes(uint32_t idx, uint64_t& bits) { + write_index(idx, bits, START); + SIMDJSON_IF_CONSTEXPR(N > 1) { + write_indexes<(N - 1 > 0 ? START + 1 : START), (N - 1 >= 0 ? N - 1 : 1)>(idx, bits); + } + return START + N; + } + + template + simdjson_inline int write_indexes_stepped(uint32_t idx, uint64_t& bits, int cnt) { + write_indexes(idx, bits); + SIMDJSON_IF_CONSTEXPR((START + STEP) < END) { + if (simdjson_unlikely((START + STEP) < cnt)) { + write_indexes_stepped<(START + STEP < END ? START + STEP : END), END, STEP>(idx, bits, cnt); + } + } + return ((END - START) % STEP) == 0 ? END : (END - START) - ((END - START) % STEP) + STEP; + } + // flatten out values in 'bits' assuming that they are are to have values of idx // plus their position in the bitvector, and store these indexes at // base_ptr[base] incrementing base as we go // will potentially store extra values beyond end of valid bits, so base_ptr // needs to be large enough to handle this // - // If the kernel sets SIMDJSON_CUSTOM_BIT_INDEXER, then it will provide its own - // version of the code. -#ifdef SIMDJSON_CUSTOM_BIT_INDEXER + // If the kernel sets SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER, then it + // will provide its own version of the code. +#ifdef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER simdjson_inline void write(uint32_t idx, uint64_t bits); #else simdjson_inline void write(uint32_t idx, uint64_t bits) { @@ -12773,93 +41959,31 @@ namespace simdjson { // it helps tremendously. if (bits == 0) return; -#if SIMDJSON_PREFER_REVERSE_BITS - /** - * ARM lacks a fast trailing zero instruction, but it has a fast - * bit reversal instruction and a fast leading zero instruction. - * Thus it may be profitable to reverse the bits (once) and then - * to rely on a sequence of instructions that call the leading - * zero instruction. - * - * Performance notes: - * The chosen routine is not optimal in terms of data dependency - * since zero_leading_bit might require two instructions. However, - * it tends to minimize the total number of instructions which is - * beneficial. - */ - uint64_t rev_bits = reverse_bits(bits); int cnt = static_cast(count_ones(bits)); - int i = 0; - // Do the first 8 all together - for (; i < 8; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - i = 8; - for (; i < 16; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } +#if SIMDJSON_PREFER_REVERSE_BITS + bits = reverse_bits(bits); +#endif +#ifdef SIMDJSON_STRUCTURAL_INDEXER_STEP + static constexpr const int STEP = SIMDJSON_STRUCTURAL_INDEXER_STEP; +#else + static constexpr const int STEP = 4; +#endif + static constexpr const int STEP_UNTIL = 24; - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - i = 16; - while (rev_bits != 0) { - int lz = leading_zeroes(rev_bits); - this->tail[i++] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); + write_indexes_stepped<0, STEP_UNTIL, STEP>(idx, bits, cnt); + SIMDJSON_IF_CONSTEXPR(STEP_UNTIL < 64) { + if (simdjson_unlikely(STEP_UNTIL < cnt)) { + for (int i = STEP_UNTIL; i < cnt; i++) { + write_index(idx, bits, i); } } } - this->tail += cnt; -#else // SIMDJSON_PREFER_REVERSE_BITS - /** - * Under recent x64 systems, we often have both a fast trailing zero - * instruction and a fast 'clear-lower-bit' instruction so the following - * algorithm can be competitive. - */ - - int cnt = static_cast(count_ones(bits)); - // Do the first 8 all together - for (int i = 0; i < 8; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - for (int i = 8; i < 16; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - int i = 16; - do { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - i++; - } while (i < cnt); - } - } this->tail += cnt; -#endif } -#endif // SIMDJSON_CUSTOM_BIT_INDEXER +#endif // SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER }; @@ -13090,12 +42214,27 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage1/json_structural_indexer.h */ -/* begin file src/generic/stage1/utf8_validator.h */ + +// Clear CUSTOM_BIT_INDEXER so other implementations can set it if they need to. +#undef SIMDJSON_GENERIC_JSON_STRUCTURAL_INDEXER_CUSTOM_BIT_INDEXER + +#endif // SIMDJSON_SRC_GENERIC_STAGE1_JSON_STRUCTURAL_INDEXER_H +/* end file generic/stage1/json_structural_indexer.h for westmere */ +/* including generic/stage1/utf8_validator.h for westmere: #include */ +/* begin file generic/stage1/utf8_validator.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { namespace stage1 { @@ -13126,267 +42265,177 @@ namespace simdjson { } // namespace stage1 } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage1/utf8_validator.h */ -// -// Stage 2 -// -/* begin file src/generic/stage2/stringparsing.h */ -// This file contains the common code every implementation uses -// It is intended to be included multiple times and compiled multiple times +#endif // SIMDJSON_SRC_GENERIC_STAGE1_UTF8_VALIDATOR_H +/* end file generic/stage1/utf8_validator.h for westmere */ +/* end file generic/stage1/amalgamated.h for westmere */ +/* including generic/stage2/amalgamated.h for westmere: #include */ +/* begin file generic/stage2/amalgamated.h for westmere */ +// Stuff other things depend on +/* including generic/stage2/base.h for westmere: #include */ +/* begin file generic/stage2/base.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_BASE_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { - /// @private - namespace stringparsing { + namespace stage2 { - // begin copypasta - // These chars yield themselves: " \ / - // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab - // u not handled in this table as it's complex - static const uint8_t escape_map[256] = { - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + class json_iterator; + class structural_iterator; + struct tape_builder; + struct tape_writer; - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. - 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. - 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - }; - - // handle a unicode codepoint - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, - uint8_t** dst_ptr, bool allow_replacement) { - // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) - constexpr uint32_t substitution_code_point = 0xfffd; - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - - // We have already checked that the high surrogate is valid and - // (code_point - 0xd800) < 1024. - // - // Check that code_point_2 is in the range 0xdc00..0xdfff - // and that code_point_2 was parsed from valid hex. - uint32_t low_bit = code_point_2 - 0xdc00; - if (low_bit >> 10) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - - } - } - else if (code_point >= 0xdc00 && code_point <= 0xdfff) { - // If we encounter a low surrogate (not preceded by a high surrogate) - // then we have an error. - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - // handle a unicode codepoint using the wobbly convention - // https://simonsapin.github.io/wtf-8/ - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, - uint8_t** dst_ptr) { - // It is not ideal that this function is nearly identical to handle_unicode_codepoint. - // - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - uint32_t low_bit = code_point_2 - 0xdc00; - if ((low_bit >> 10) == 0) { - code_point = - (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - } - } - - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - /** - * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There - * must be an unescaped quote terminating the string. It returns the final output - * position as pointer. In case of error (e.g., the string has bad escaped codes), - * then null_nullptrptr is returned. It is assumed that the output buffer is large - * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + - * SIMDJSON_PADDING bytes. - */ - simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { - // It is not ideal that this function is nearly identical to parse_string. - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint_wobbly(&src, &dst)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - } // namespace stringparsing + } // namespace stage2 } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage2/stringparsing.h */ -/* begin file src/generic/stage2/tape_builder.h */ -/* begin file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_BASE_H +/* end file generic/stage2/base.h for westmere */ +/* including generic/stage2/tape_writer.h for westmere: #include */ +/* begin file generic/stage2/tape_writer.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace westmere { + namespace { + namespace stage2 { + + struct tape_writer { + /** The next place to write to tape */ + uint64_t* next_tape_loc; + + /** Write a signed 64-bit value to tape. */ + simdjson_inline void append_s64(int64_t value) noexcept; + + /** Write an unsigned 64-bit value to tape. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + + /** Write a double value to tape. */ + simdjson_inline void append_double(double value) noexcept; + + /** + * Append a tape entry (an 8-bit type,and 56 bits worth of value). + */ + simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; + + /** + * Skip the current tape entry without writing. + * + * Used to skip the start of the container, since we'll come back later to fill it in when the + * container ends. + */ + simdjson_inline void skip() noexcept; + + /** + * Skip the number of tape entries necessary to write a large u64 or i64. + */ + simdjson_inline void skip_large_integer() noexcept; + + /** + * Skip the number of tape entries necessary to write a double. + */ + simdjson_inline void skip_double() noexcept; + + /** + * Write a value to a known location on tape. + * + * Used to go back and write out the start of a container after the container ends. + */ + simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; + + private: + /** + * Append both the tape entry, and a supplementary value following it. Used for types that need + * all 64 bits, such as double and uint64_t. + */ + template + simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; + }; // struct tape_writer + + simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { + append2(0, value, internal::tape_type::INT64); + } + + simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { + append(0, internal::tape_type::UINT64); + *next_tape_loc = value; + next_tape_loc++; + } + + /** Write a double value to tape. */ + simdjson_inline void tape_writer::append_double(double value) noexcept { + append2(0, value, internal::tape_type::DOUBLE); + } + + simdjson_inline void tape_writer::skip() noexcept { + next_tape_loc++; + } + + simdjson_inline void tape_writer::skip_large_integer() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::skip_double() noexcept { + next_tape_loc += 2; + } + + simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { + *next_tape_loc = val | ((uint64_t(char(t))) << 56); + next_tape_loc++; + } + + template + simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { + append(val, t); + static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); + memcpy(next_tape_loc, &val2, sizeof(val2)); + next_tape_loc++; + } + + simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { + tape_loc = val | ((uint64_t(char(t))) << 56); + } + + } // namespace stage2 + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_WRITER_H +/* end file generic/stage2/tape_writer.h for westmere */ +/* including generic/stage2/logger.h for westmere: #include */ +/* begin file generic/stage2/logger.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + + // This is for an internal-only stage 2 specific logger. // Set LOG_ENABLED = true to log what stage 2 is doing! namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { namespace logger { @@ -13471,12 +42520,26 @@ namespace simdjson { } // namespace logger } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage2/logger.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_LOGGER_H +/* end file generic/stage2/logger.h for westmere */ + +// All other declarations +/* including generic/stage2/json_iterator.h for westmere: #include */ +/* begin file generic/stage2/json_iterator.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { namespace stage2 { @@ -13771,15 +42834,18 @@ namespace simdjson { } template simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { + // Use the fact that most scalars are going to be either strings or numbers. + if (*value == '"') { + return visitor.visit_string(*this, value); + } + else if (((*value - '0') < 10) || (*value == '-')) { + return visitor.visit_number(*this, value); + } + // true, false, null are uncommon. switch (*value) { - case '"': return visitor.visit_string(*this, value); case 't': return visitor.visit_true_atom(*this, value); case 'f': return visitor.visit_false_atom(*this, value); case 'n': return visitor.visit_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_number(*this, value); default: log_error("Non-value found when value was expected!"); return TAPE_ERROR; @@ -13788,119 +42854,351 @@ namespace simdjson { } // namespace stage2 } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_JSON_ITERATOR_H +/* end file generic/stage2/json_iterator.h for westmere */ +/* including generic/stage2/stringparsing.h for westmere: #include */ +/* begin file generic/stage2/stringparsing.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This file contains the common code every implementation uses +// It is intended to be included multiple times and compiled multiple times + namespace simdjson { - namespace ppc64 { + namespace westmere { + namespace { + /// @private + namespace stringparsing { + + // begin copypasta + // These chars yield themselves: " \ / + // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab + // u not handled in this table as it's complex + static const uint8_t escape_map[256] = { + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. + 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. + 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, + }; + + // handle a unicode codepoint + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, + uint8_t** dst_ptr, bool allow_replacement) { + // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) + constexpr uint32_t substitution_code_point = 0xfffd; + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + + // We have already checked that the high surrogate is valid and + // (code_point - 0xd800) < 1024. + // + // Check that code_point_2 is in the range 0xdc00..0xdfff + // and that code_point_2 was parsed from valid hex. + uint32_t low_bit = code_point_2 - 0xdc00; + if (low_bit >> 10) { + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + else { + code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + + } + } + else if (code_point >= 0xdc00 && code_point <= 0xdfff) { + // If we encounter a low surrogate (not preceded by a high surrogate) + // then we have an error. + if (!allow_replacement) { return false; } + code_point = substitution_code_point; + } + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + // handle a unicode codepoint using the wobbly convention + // https://simonsapin.github.io/wtf-8/ + // write appropriate values into dest + // src will advance 6 bytes or 12 bytes + // dest will advance a variable amount (return via pointer) + // return true if the unicode codepoint was valid + // We work in little-endian then swap at write time + simdjson_warn_unused + simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, + uint8_t** dst_ptr) { + // It is not ideal that this function is nearly identical to handle_unicode_codepoint. + // + // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the + // conversion isn't valid; we defer the check for this to inside the + // multilingual plane check + uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); + *src_ptr += 6; + // If we found a high surrogate, we must + // check for low surrogate for characters + // outside the Basic + // Multilingual Plane. + if (code_point >= 0xd800 && code_point < 0xdc00) { + const uint8_t* src_data = *src_ptr; + /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ + if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { + uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); + uint32_t low_bit = code_point_2 - 0xdc00; + if ((low_bit >> 10) == 0) { + code_point = + (((code_point - 0xd800) << 10) | low_bit) + 0x10000; + *src_ptr += 6; + } + } + } + + size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); + *dst_ptr += offset; + return offset > 0; + } + + + /** + * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There + * must be an unescaped quote terminating the string. It returns the final output + * position as pointer. In case of error (e.g., the string has bad escaped codes), + * then null_nullptrptr is returned. It is assumed that the output buffer is large + * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + + * SIMDJSON_PADDING bytes. + */ + simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { + // It is not ideal that this function is nearly identical to parse_string. + while (1) { + // Copy the next n bytes, and find the backslash and quote in them. + auto bs_quote = backslash_and_quote::copy_and_find(src, dst); + // If the next thing is the end quote, copy and return + if (bs_quote.has_quote_first()) { + // we encountered quotes first. Move dst to point to quotes and exit + return dst + bs_quote.quote_index(); + } + if (bs_quote.has_backslash()) { + /* find out where the backspace is */ + auto bs_dist = bs_quote.backslash_index(); + uint8_t escape_char = src[bs_dist + 1]; + /* we encountered backslash first. Handle backslash */ + if (escape_char == 'u') { + /* move src/dst up to the start; they will be further adjusted + within the unicode codepoint handling code. */ + src += bs_dist; + dst += bs_dist; + if (!handle_unicode_codepoint_wobbly(&src, &dst)) { + return nullptr; + } + } + else { + /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and + * write bs_dist+1 characters to output + * note this may reach beyond the part of the buffer we've actually + * seen. I think this is ok */ + uint8_t escape_result = escape_map[escape_char]; + if (escape_result == 0u) { + return nullptr; /* bogus escape value is an error */ + } + dst[bs_dist] = escape_result; + src += bs_dist + 2; + dst += bs_dist + 1; + } + } + else { + /* they are the same. Since they can't co-occur, it means we + * encountered neither. */ + src += backslash_and_quote::BYTES_PROCESSED; + dst += backslash_and_quote::BYTES_PROCESSED; + } + } + } + + } // namespace stringparsing + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRINGPARSING_H +/* end file generic/stage2/stringparsing.h for westmere */ +/* including generic/stage2/structural_iterator.h for westmere: #include */ +/* begin file generic/stage2/structural_iterator.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { namespace { namespace stage2 { - struct tape_writer { - /** The next place to write to tape */ - uint64_t* next_tape_loc; + class structural_iterator { + public: + const uint8_t* const buf; + uint32_t* next_structural; + dom_parser_implementation& dom_parser; - /** Write a signed 64-bit value to tape. */ - simdjson_inline void append_s64(int64_t value) noexcept; + // Start a structural + simdjson_inline structural_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) + : buf{ _dom_parser.buf }, + next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, + dom_parser{ _dom_parser } { + } + // Get the buffer position of the current structural character + simdjson_inline const uint8_t* current() { + return &buf[*(next_structural - 1)]; + } + // Get the current structural character + simdjson_inline char current_char() { + return buf[*(next_structural - 1)]; + } + // Get the next structural character without advancing + simdjson_inline char peek_next_char() { + return buf[*next_structural]; + } + simdjson_inline const uint8_t* peek() { + return &buf[*next_structural]; + } + simdjson_inline const uint8_t* advance() { + return &buf[*(next_structural++)]; + } + simdjson_inline char advance_char() { + return buf[*(next_structural++)]; + } + simdjson_inline size_t remaining_len() { + return dom_parser.len - *(next_structural - 1); + } - /** Write an unsigned 64-bit value to tape. */ - simdjson_inline void append_u64(uint64_t value) noexcept; - - /** Write a double value to tape. */ - simdjson_inline void append_double(double value) noexcept; - - /** - * Append a tape entry (an 8-bit type,and 56 bits worth of value). - */ - simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; - - /** - * Skip the current tape entry without writing. - * - * Used to skip the start of the container, since we'll come back later to fill it in when the - * container ends. - */ - simdjson_inline void skip() noexcept; - - /** - * Skip the number of tape entries necessary to write a large u64 or i64. - */ - simdjson_inline void skip_large_integer() noexcept; - - /** - * Skip the number of tape entries necessary to write a double. - */ - simdjson_inline void skip_double() noexcept; - - /** - * Write a value to a known location on tape. - * - * Used to go back and write out the start of a container after the container ends. - */ - simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; - - private: - /** - * Append both the tape entry, and a supplementary value following it. Used for types that need - * all 64 bits, such as double and uint64_t. - */ - template - simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; - }; // struct number_writer - - simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { - append2(0, value, internal::tape_type::INT64); - } - - simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { - append(0, internal::tape_type::UINT64); - *next_tape_loc = value; - next_tape_loc++; - } - - /** Write a double value to tape. */ - simdjson_inline void tape_writer::append_double(double value) noexcept { - append2(0, value, internal::tape_type::DOUBLE); - } - - simdjson_inline void tape_writer::skip() noexcept { - next_tape_loc++; - } - - simdjson_inline void tape_writer::skip_large_integer() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::skip_double() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { - *next_tape_loc = val | ((uint64_t(char(t))) << 56); - next_tape_loc++; - } - - template - simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { - append(val, t); - static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); - memcpy(next_tape_loc, &val2, sizeof(val2)); - next_tape_loc++; - } - - simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { - tape_loc = val | ((uint64_t(char(t))) << 56); - } + simdjson_inline bool at_end() { + return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; + } + simdjson_inline bool at_beginning() { + return next_structural == dom_parser.structural_indexes.get(); + } + }; } // namespace stage2 } // unnamed namespace - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* end file src/generic/stage2/tape_writer.h */ + +#endif // SIMDJSON_SRC_GENERIC_STAGE2_STRUCTURAL_ITERATOR_H +/* end file generic/stage2/structural_iterator.h for westmere */ +/* including generic/stage2/tape_builder.h for westmere: #include */ +/* begin file generic/stage2/tape_builder.h for westmere */ +#ifndef SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #include */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace ppc64 { + namespace westmere { namespace { namespace stage2 { @@ -13979,7 +43277,7 @@ namespace simdjson { simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; simdjson_inline void on_end_string(uint8_t* dst) noexcept; - }; // class tape_builder + }; // struct tape_builder template simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( @@ -14177,78 +43475,16 @@ namespace simdjson { } // namespace stage2 } // unnamed namespace - } // namespace ppc64 -} // namespace simdjson -/* end file src/generic/stage2/tape_builder.h */ - -// -// Implementation-specific overrides -// -namespace simdjson { - namespace ppc64 { - namespace { - namespace stage1 { - - simdjson_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) { - // On PPC, we don't short-circuit this if there are no backslashes, because the branch gives us no - // benefit and therefore makes things worse. - // if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; } - return find_escaped_branchless(backslash); - } - - } // namespace stage1 - } // unnamed namespace - - simdjson_warn_unused error_code implementation::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept { - return ppc64::stage1::json_minifier::minify<64>(buf, len, dst, dst_len); - } - - simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t* _buf, size_t _len, stage1_mode streaming) noexcept { - this->buf = _buf; - this->len = _len; - return ppc64::stage1::json_structural_indexer::index<64>(buf, len, *this, streaming); - } - - simdjson_warn_unused bool implementation::validate_utf8(const char* buf, size_t len) const noexcept { - return ppc64::stage1::generic_validate_utf8(buf, len); - } - - simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document& _doc) noexcept { - return stage2::tape_builder::parse_document(*this, _doc); - } - - simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document& _doc) noexcept { - return stage2::tape_builder::parse_document(*this, _doc); - } - - simdjson_warn_unused uint8_t* dom_parser_implementation::parse_string(const uint8_t* src, uint8_t* dst, bool replacement_char) const noexcept { - return ppc64::stringparsing::parse_string(src, dst, replacement_char); - } - - simdjson_warn_unused uint8_t* dom_parser_implementation::parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept { - return ppc64::stringparsing::parse_wobbly_string(src, dst); - } - - simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t* _buf, size_t _len, dom::document& _doc) noexcept { - auto error = stage1(_buf, _len, stage1_mode::regular); - if (error) { return error; } - return stage2(_doc); - } - - } // namespace ppc64 + } // namespace westmere } // namespace simdjson -/* begin file include/simdjson/ppc64/end.h */ -/* end file include/simdjson/ppc64/end.h */ -/* end file src/ppc64/dom_parser_implementation.cpp */ -#endif -#if SIMDJSON_IMPLEMENTATION_WESTMERE -/* begin file src/westmere/implementation.cpp */ -/* begin file include/simdjson/westmere/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "westmere" -// #define SIMDJSON_IMPLEMENTATION westmere -SIMDJSON_TARGET_WESTMERE -/* end file include/simdjson/westmere/begin.h */ +#endif // SIMDJSON_SRC_GENERIC_STAGE2_TAPE_BUILDER_H +/* end file generic/stage2/tape_builder.h for westmere */ +/* end file generic/stage2/amalgamated.h for westmere */ + +// +// Stage 1 +// namespace simdjson { namespace westmere { @@ -14267,41 +43503,10 @@ namespace simdjson { return SUCCESS; } - } // namespace westmere -} // namespace simdjson - -/* begin file include/simdjson/westmere/end.h */ -SIMDJSON_UNTARGET_WESTMERE -/* end file include/simdjson/westmere/end.h */ -/* end file src/westmere/implementation.cpp */ -/* begin file src/westmere/dom_parser_implementation.cpp */ -/* begin file include/simdjson/westmere/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "westmere" -// #define SIMDJSON_IMPLEMENTATION westmere -SIMDJSON_TARGET_WESTMERE -/* end file include/simdjson/westmere/begin.h */ - -// -// Stage 1 -// - -namespace simdjson { - namespace westmere { namespace { using namespace simd; - struct json_character_block { - static simdjson_inline json_character_block classify(const simd::simd8x64& in); - - simdjson_inline uint64_t whitespace() const noexcept { return _whitespace; } - simdjson_inline uint64_t op() const noexcept { return _op; } - simdjson_inline uint64_t scalar() const noexcept { return ~(op() | whitespace()); } - - uint64_t _whitespace; - uint64_t _op; - }; - simdjson_inline json_character_block json_character_block::classify(const simd::simd8x64& in) { // These lookups rely on the fact that anything < 127 will match the lower 4 bits, which is why // we can't use the generic lookup_16. @@ -14384,2260 +43589,9 @@ namespace simdjson { } // namespace westmere } // namespace simdjson -/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */ -namespace simdjson { - namespace westmere { - namespace { - namespace utf8_validation { - - using namespace simd; - - simdjson_inline simd8 check_special_cases(const simd8 input, const simd8 prev1) { - // Bit 0 = Too Short (lead byte/ASCII followed by lead byte/ASCII) - // Bit 1 = Too Long (ASCII followed by continuation) - // Bit 2 = Overlong 3-byte - // Bit 4 = Surrogate - // Bit 5 = Overlong 2-byte - // Bit 7 = Two Continuations - constexpr const uint8_t TOO_SHORT = 1 << 0; // 11______ 0_______ - // 11______ 11______ - constexpr const uint8_t TOO_LONG = 1 << 1; // 0_______ 10______ - constexpr const uint8_t OVERLONG_3 = 1 << 2; // 11100000 100_____ - constexpr const uint8_t SURROGATE = 1 << 4; // 11101101 101_____ - constexpr const uint8_t OVERLONG_2 = 1 << 5; // 1100000_ 10______ - constexpr const uint8_t TWO_CONTS = 1 << 7; // 10______ 10______ - constexpr const uint8_t TOO_LARGE = 1 << 3; // 11110100 1001____ - // 11110100 101_____ - // 11110101 1001____ - // 11110101 101_____ - // 1111011_ 1001____ - // 1111011_ 101_____ - // 11111___ 1001____ - // 11111___ 101_____ - constexpr const uint8_t TOO_LARGE_1000 = 1 << 6; - // 11110101 1000____ - // 1111011_ 1000____ - // 11111___ 1000____ - constexpr const uint8_t OVERLONG_4 = 1 << 6; // 11110000 1000____ - - const simd8 byte_1_high = prev1.shr<4>().lookup_16( - // 0_______ ________ - TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG, - TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG, - // 10______ ________ - TWO_CONTS, TWO_CONTS, TWO_CONTS, TWO_CONTS, - // 1100____ ________ - TOO_SHORT | OVERLONG_2, - // 1101____ ________ - TOO_SHORT, - // 1110____ ________ - TOO_SHORT | OVERLONG_3 | SURROGATE, - // 1111____ ________ - TOO_SHORT | TOO_LARGE | TOO_LARGE_1000 | OVERLONG_4 - ); - constexpr const uint8_t CARRY = TOO_SHORT | TOO_LONG | TWO_CONTS; // These all have ____ in byte 1 . - const simd8 byte_1_low = (prev1 & 0x0F).lookup_16( - // ____0000 ________ - CARRY | OVERLONG_3 | OVERLONG_2 | OVERLONG_4, - // ____0001 ________ - CARRY | OVERLONG_2, - // ____001_ ________ - CARRY, - CARRY, - - // ____0100 ________ - CARRY | TOO_LARGE, - // ____0101 ________ - CARRY | TOO_LARGE | TOO_LARGE_1000, - // ____011_ ________ - CARRY | TOO_LARGE | TOO_LARGE_1000, - CARRY | TOO_LARGE | TOO_LARGE_1000, - - // ____1___ ________ - CARRY | TOO_LARGE | TOO_LARGE_1000, - CARRY | TOO_LARGE | TOO_LARGE_1000, - CARRY | TOO_LARGE | TOO_LARGE_1000, - CARRY | TOO_LARGE | TOO_LARGE_1000, - CARRY | TOO_LARGE | TOO_LARGE_1000, - // ____1101 ________ - CARRY | TOO_LARGE | TOO_LARGE_1000 | SURROGATE, - CARRY | TOO_LARGE | TOO_LARGE_1000, - CARRY | TOO_LARGE | TOO_LARGE_1000 - ); - const simd8 byte_2_high = input.shr<4>().lookup_16( - // ________ 0_______ - TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT, - TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT, - - // ________ 1000____ - TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE_1000 | OVERLONG_4, - // ________ 1001____ - TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE, - // ________ 101_____ - TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE, - TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE, - - // ________ 11______ - TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT - ); - return (byte_1_high & byte_1_low & byte_2_high); - } - simdjson_inline simd8 check_multibyte_lengths(const simd8 input, - const simd8 prev_input, const simd8 sc) { - simd8 prev2 = input.prev<2>(prev_input); - simd8 prev3 = input.prev<3>(prev_input); - simd8 must23 = simd8(must_be_2_3_continuation(prev2, prev3)); - simd8 must23_80 = must23 & uint8_t(0x80); - return must23_80 ^ sc; - } - - // - // Return nonzero if there are incomplete multibyte characters at the end of the block: - // e.g. if there is a 4-byte character, but it's 3 bytes from the end. - // - simdjson_inline simd8 is_incomplete(const simd8 input) { - // If the previous input's last 3 bytes match this, they're too short (they ended at EOF): - // ... 1111____ 111_____ 11______ -#if SIMDJSON_IMPLEMENTATION_ICELAKE - static const uint8_t max_array[64] = { - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 0xf0u - 1, 0xe0u - 1, 0xc0u - 1 - }; -#else - static const uint8_t max_array[32] = { - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 255, 255, 255, - 255, 255, 255, 255, 255, 0xf0u - 1, 0xe0u - 1, 0xc0u - 1 - }; -#endif - const simd8 max_value(&max_array[sizeof(max_array) - sizeof(simd8)]); - return input.gt_bits(max_value); - } - - struct utf8_checker { - // If this is nonzero, there has been a UTF-8 error. - simd8 error; - // The last input we received - simd8 prev_input_block; - // Whether the last input we received was incomplete (used for ASCII fast path) - simd8 prev_incomplete; - - // - // Check whether the current bytes are valid UTF-8. - // - simdjson_inline void check_utf8_bytes(const simd8 input, const simd8 prev_input) { - // Flip prev1...prev3 so we can easily determine if they are 2+, 3+ or 4+ lead bytes - // (2, 3, 4-byte leads become large positive numbers instead of small negative numbers) - simd8 prev1 = input.prev<1>(prev_input); - simd8 sc = check_special_cases(input, prev1); - this->error |= check_multibyte_lengths(input, prev_input, sc); - } - - // The only problem that can happen at EOF is that a multibyte character is too short - // or a byte value too large in the last bytes: check_special_cases only checks for bytes - // too large in the first of two bytes. - simdjson_inline void check_eof() { - // If the previous block had incomplete UTF-8 characters at the end, an ASCII block can't - // possibly finish them. - this->error |= this->prev_incomplete; - } - -#ifndef SIMDJSON_IF_CONSTEXPR -#if SIMDJSON_CPLUSPLUS17 -#define SIMDJSON_IF_CONSTEXPR if constexpr -#else -#define SIMDJSON_IF_CONSTEXPR if -#endif -#endif - - simdjson_inline void check_next_input(const simd8x64& input) { - if (simdjson_likely(is_ascii(input))) { - this->error |= this->prev_incomplete; - } - else { - // you might think that a for-loop would work, but under Visual Studio, it is not good enough. - static_assert((simd8x64::NUM_CHUNKS == 1) - || (simd8x64::NUM_CHUNKS == 2) - || (simd8x64::NUM_CHUNKS == 4), - "We support one, two or four chunks per 64-byte block."); - SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 1) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - } -else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 2) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - } - else SIMDJSON_IF_CONSTEXPR(simd8x64::NUM_CHUNKS == 4) { - this->check_utf8_bytes(input.chunks[0], this->prev_input_block); - this->check_utf8_bytes(input.chunks[1], input.chunks[0]); - this->check_utf8_bytes(input.chunks[2], input.chunks[1]); - this->check_utf8_bytes(input.chunks[3], input.chunks[2]); - } - this->prev_incomplete = is_incomplete(input.chunks[simd8x64::NUM_CHUNKS - 1]); - this->prev_input_block = input.chunks[simd8x64::NUM_CHUNKS - 1]; - } - } - // do not forget to call check_eof! - simdjson_inline error_code errors() { - return this->error.any_bits_set_anywhere() ? error_code::UTF8_ERROR : error_code::SUCCESS; - } - - }; // struct utf8_checker - } // namespace utf8_validation - - using utf8_validation::utf8_checker; - - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/utf8_lookup4_algorithm.h */ -/* begin file src/generic/stage1/json_structural_indexer.h */ -// This file contains the common code every implementation uses in stage1 -// It is intended to be included multiple times and compiled multiple times -// We assume the file in which it is included already includes -// "simdjson/stage1.h" (this simplifies amalgation) - -/* begin file src/generic/stage1/buf_block_reader.h */ -namespace simdjson { - namespace westmere { - namespace { - - // Walks through a buffer in block-sized increments, loading the last part with spaces - template - struct buf_block_reader { - public: - simdjson_inline buf_block_reader(const uint8_t* _buf, size_t _len); - simdjson_inline size_t block_index(); - simdjson_inline bool has_full_block() const; - simdjson_inline const uint8_t* full_block() const; - /** - * Get the last block, padded with spaces. - * - * There will always be a last block, with at least 1 byte, unless len == 0 (in which case this - * function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there - * will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding. - * - * @return the number of effective characters in the last block. - */ - simdjson_inline size_t get_remainder(uint8_t* dst) const; - simdjson_inline void advance(); - private: - const uint8_t* buf; - const size_t len; - const size_t lenminusstep; - size_t idx; - }; - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text_64(const uint8_t* text) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < sizeof(simd8x64); i++) { - buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]); - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - // Routines to print masks and text for debugging bitmask operations - simdjson_unused static char* format_input_text(const simd8x64& in) { - static char buf[sizeof(simd8x64) + 1]; - in.store(reinterpret_cast(buf)); - for (size_t i = 0; i < sizeof(simd8x64); i++) { - if (buf[i] < ' ') { buf[i] = '_'; } - } - buf[sizeof(simd8x64)] = '\0'; - return buf; - } - - simdjson_unused static char* format_mask(uint64_t mask) { - static char buf[sizeof(simd8x64) + 1]; - for (size_t i = 0; i < 64; i++) { - buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' '; - } - buf[64] = '\0'; - return buf; - } - - template - simdjson_inline buf_block_reader::buf_block_reader(const uint8_t* _buf, size_t _len) : buf{ _buf }, len{ _len }, lenminusstep{ len < STEP_SIZE ? 0 : len - STEP_SIZE }, idx{ 0 } {} - - template - simdjson_inline size_t buf_block_reader::block_index() { return idx; } - - template - simdjson_inline bool buf_block_reader::has_full_block() const { - return idx < lenminusstep; - } - - template - simdjson_inline const uint8_t* buf_block_reader::full_block() const { - return &buf[idx]; - } - - template - simdjson_inline size_t buf_block_reader::get_remainder(uint8_t* dst) const { - if (len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers - std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once. - std::memcpy(dst, buf + idx, len - idx); - return len - idx; - } - - template - simdjson_inline void buf_block_reader::advance() { - idx += STEP_SIZE; - } - - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/buf_block_reader.h */ -/* begin file src/generic/stage1/json_string_scanner.h */ -namespace simdjson { - namespace westmere { - namespace { - namespace stage1 { - - struct json_string_block { - // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 - simdjson_inline json_string_block(uint64_t backslash, uint64_t escaped, uint64_t quote, uint64_t in_string) : - _backslash(backslash), _escaped(escaped), _quote(quote), _in_string(in_string) {} - - // Escaped characters (characters following an escape() character) - simdjson_inline uint64_t escaped() const { return _escaped; } - // Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \) - simdjson_inline uint64_t escape() const { return _backslash & ~_escaped; } - // Real (non-backslashed) quotes - simdjson_inline uint64_t quote() const { return _quote; } - // Start quotes of strings - simdjson_inline uint64_t string_start() const { return _quote & _in_string; } - // End quotes of strings - simdjson_inline uint64_t string_end() const { return _quote & ~_in_string; } - // Only characters inside the string (not including the quotes) - simdjson_inline uint64_t string_content() const { return _in_string & ~_quote; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; } - // Return a mask of whether the given characters are inside a string (only works on non-quotes) - simdjson_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; } - // Tail of string (everything except the start quote) - simdjson_inline uint64_t string_tail() const { return _in_string ^ _quote; } - - // backslash characters - uint64_t _backslash; - // escaped characters (backslashed--does not include the hex characters after \u) - uint64_t _escaped; - // real quotes (non-backslashed ones) - uint64_t _quote; - // string characters (includes start quote but not end quote) - uint64_t _in_string; - }; - - // Scans blocks for string characters, storing the state necessary to do so - class json_string_scanner { - public: - simdjson_inline json_string_block next(const simd::simd8x64& in); - // Returns either UNCLOSED_STRING or SUCCESS - simdjson_inline error_code finish(); - - private: - // Intended to be defined by the implementation - simdjson_inline uint64_t find_escaped(uint64_t escape); - simdjson_inline uint64_t find_escaped_branchless(uint64_t escape); - - // Whether the last iteration was still inside a string (all 1's = true, all 0's = false). - uint64_t prev_in_string = 0ULL; - // Whether the first character of the next iteration is escaped. - uint64_t prev_escaped = 0ULL; - }; - - // - // Finds escaped characters (characters following \). - // - // Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively). - // - // Does this by: - // - Shift the escape mask to get potentially escaped characters (characters after backslashes). - // - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not) - // - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not) - // - // To distinguish between escaped sequences starting on even/odd bits, it finds the start of all - // escape sequences, filters out the ones that start on even bits, and adds that to the mask of - // escape sequences. This causes the addition to clear out the sequences starting on odd bits (since - // the start bit causes a carry), and leaves even-bit sequences alone. - // - // Example: - // - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape - // odd_starts | x | x x x | escape & ~even_bits & ~follows_escape - // even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later - // invert_mask | | cxxx c xx c| even_seq << 1 - // follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit - // escaped | x | x x x x x x x x | - // desired | x | x x x x x x x x | - // text | \\\ | \\\"\\\" \\\" \\"\\" | - // - simdjson_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) { - // If there was overflow, pretend the first character isn't a backslash - backslash &= ~prev_escaped; - uint64_t follows_escape = backslash << 1 | prev_escaped; - - // Get sequences starting on even bits by clearing out the odd series using + - const uint64_t even_bits = 0x5555555555555555ULL; - uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape; - uint64_t sequences_starting_on_even_bits; - prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits); - uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes. - - // Mask every other backslashed character as an escaped character - // Flip the mask for sequences that start on even bits, to correct them - return (even_bits ^ invert_mask) & follows_escape; - } - - // - // Return a mask of all string characters plus end quotes. - // - // prev_escaped is overflow saying whether the next character is escaped. - // prev_in_string is overflow saying whether we're still in a string. - // - // Backslash sequences outside of quotes will be detected in stage 2. - // - simdjson_inline json_string_block json_string_scanner::next(const simd::simd8x64& in) { - const uint64_t backslash = in.eq('\\'); - const uint64_t escaped = find_escaped(backslash); - const uint64_t quote = in.eq('"') & ~escaped; - - // - // prefix_xor flips on bits inside the string (and flips off the end quote). - // - // Then we xor with prev_in_string: if we were in a string already, its effect is flipped - // (characters inside strings are outside, and characters outside strings are inside). - // - const uint64_t in_string = prefix_xor(quote) ^ prev_in_string; - - // - // Check if we're still in a string at the end of the box so the next block will know - // - // right shift of a signed value expected to be well-defined and standard - // compliant as of C++20, John Regher from Utah U. says this is fine code - // - prev_in_string = uint64_t(static_cast(in_string) >> 63); - - // Use ^ to turn the beginning quote off, and the end quote on. - - // We are returning a function-local object so either we get a move constructor - // or we get copy elision. - return json_string_block( - backslash, - escaped, - quote, - in_string - ); - } - - simdjson_inline error_code json_string_scanner::finish() { - if (prev_in_string) { - return UNCLOSED_STRING; - } - return SUCCESS; - } - - } // namespace stage1 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/json_string_scanner.h */ -/* begin file src/generic/stage1/json_scanner.h */ -namespace simdjson { - namespace westmere { - namespace { - namespace stage1 { - - /** - * A block of scanned json, with information on operators and scalars. - * - * We seek to identify pseudo-structural characters. Anything that is inside - * a string must be omitted (hence & ~_string.string_tail()). - * Otherwise, pseudo-structural characters come in two forms. - * 1. We have the structural characters ([,],{,},:, comma). The - * term 'structural character' is from the JSON RFC. - * 2. We have the 'scalar pseudo-structural characters'. - * Scalars are quotes, and any character except structural characters and white space. - * - * To identify the scalar pseudo-structural characters, we must look at what comes - * before them: it must be a space, a quote or a structural characters. - * Starting with simdjson v0.3, we identify them by - * negation: we identify everything that is followed by a non-quote scalar, - * and we negate that. Whatever remains must be a 'scalar pseudo-structural character'. - */ - struct json_block { - public: - // We spell out the constructors in the hope of resolving inlining issues with Visual Studio 2017 - simdjson_inline json_block(json_string_block&& string, json_character_block characters, uint64_t follows_potential_nonquote_scalar) : - _string(std::move(string)), _characters(characters), _follows_potential_nonquote_scalar(follows_potential_nonquote_scalar) {} - simdjson_inline json_block(json_string_block string, json_character_block characters, uint64_t follows_potential_nonquote_scalar) : - _string(string), _characters(characters), _follows_potential_nonquote_scalar(follows_potential_nonquote_scalar) {} - - /** - * The start of structurals. - * In simdjson prior to v0.3, these were called the pseudo-structural characters. - **/ - simdjson_inline uint64_t structural_start() const noexcept { return potential_structural_start() & ~_string.string_tail(); } - /** All JSON whitespace (i.e. not in a string) */ - simdjson_inline uint64_t whitespace() const noexcept { return non_quote_outside_string(_characters.whitespace()); } - - // Helpers - - /** Whether the given characters are inside a string (only works on non-quotes) */ - simdjson_inline uint64_t non_quote_inside_string(uint64_t mask) const noexcept { return _string.non_quote_inside_string(mask); } - /** Whether the given characters are outside a string (only works on non-quotes) */ - simdjson_inline uint64_t non_quote_outside_string(uint64_t mask) const noexcept { return _string.non_quote_outside_string(mask); } - - // string and escape characters - json_string_block _string; - // whitespace, structural characters ('operators'), scalars - json_character_block _characters; - // whether the previous character was a scalar - uint64_t _follows_potential_nonquote_scalar; - private: - // Potential structurals (i.e. disregarding strings) - - /** - * structural elements ([,],{,},:, comma) plus scalar starts like 123, true and "abc". - * They may reside inside a string. - **/ - simdjson_inline uint64_t potential_structural_start() const noexcept { return _characters.op() | potential_scalar_start(); } - /** - * The start of non-operator runs, like 123, true and "abc". - * It main reside inside a string. - **/ - simdjson_inline uint64_t potential_scalar_start() const noexcept { - // The term "scalar" refers to anything except structural characters and white space - // (so letters, numbers, quotes). - // Whenever it is preceded by something that is not a structural element ({,},[,],:, ") nor a white-space - // then we know that it is irrelevant structurally. - return _characters.scalar() & ~follows_potential_scalar(); - } - /** - * Whether the given character is immediately after a non-operator like 123, true. - * The characters following a quote are not included. - */ - simdjson_inline uint64_t follows_potential_scalar() const noexcept { - // _follows_potential_nonquote_scalar: is defined as marking any character that follows a character - // that is not a structural element ({,},[,],:, comma) nor a quote (") and that is not a - // white space. - // It is understood that within quoted region, anything at all could be marked (irrelevant). - return _follows_potential_nonquote_scalar; - } - }; - - /** - * Scans JSON for important bits: structural characters or 'operators', strings, and scalars. - * - * The scanner starts by calculating two distinct things: - * - string characters (taking \" into account) - * - structural characters or 'operators' ([]{},:, comma) - * and scalars (runs of non-operators like 123, true and "abc") - * - * To minimize data dependency (a key component of the scanner's speed), it finds these in parallel: - * in particular, the operator/scalar bit will find plenty of things that are actually part of - * strings. When we're done, json_block will fuse the two together by masking out tokens that are - * part of a string. - */ - class json_scanner { - public: - json_scanner() = default; - simdjson_inline json_block next(const simd::simd8x64& in); - // Returns either UNCLOSED_STRING or SUCCESS - simdjson_inline error_code finish(); - - private: - // Whether the last character of the previous iteration is part of a scalar token - // (anything except whitespace or a structural character/'operator'). - uint64_t prev_scalar = 0ULL; - json_string_scanner string_scanner{}; - }; - - - // - // Check if the current character immediately follows a matching character. - // - // For example, this checks for quotes with backslashes in front of them: - // - // const uint64_t backslashed_quote = in.eq('"') & immediately_follows(in.eq('\'), prev_backslash); - // - simdjson_inline uint64_t follows(const uint64_t match, uint64_t& overflow) { - const uint64_t result = match << 1 | overflow; - overflow = match >> 63; - return result; - } - - simdjson_inline json_block json_scanner::next(const simd::simd8x64& in) { - json_string_block strings = string_scanner.next(in); - // identifies the white-space and the structural characters - json_character_block characters = json_character_block::classify(in); - // The term "scalar" refers to anything except structural characters and white space - // (so letters, numbers, quotes). - // We want follows_scalar to mark anything that follows a non-quote scalar (so letters and numbers). - // - // A terminal quote should either be followed by a structural character (comma, brace, bracket, colon) - // or nothing. However, we still want ' "a string"true ' to mark the 't' of 'true' as a potential - // pseudo-structural character just like we would if we had ' "a string" true '; otherwise we - // may need to add an extra check when parsing strings. - // - // Performance: there are many ways to skin this cat. - const uint64_t nonquote_scalar = characters.scalar() & ~strings.quote(); - uint64_t follows_nonquote_scalar = follows(nonquote_scalar, prev_scalar); - // We are returning a function-local object so either we get a move constructor - // or we get copy elision. - return json_block( - strings,// strings is a function-local object so either it moves or the copy is elided. - characters, - follows_nonquote_scalar - ); - } - - simdjson_inline error_code json_scanner::finish() { - return string_scanner.finish(); - } - - } // namespace stage1 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/json_scanner.h */ -/* begin file src/generic/stage1/json_minifier.h */ -// This file contains the common code every implementation uses in stage1 -// It is intended to be included multiple times and compiled multiple times -// We assume the file in which it is included already includes -// "simdjson/stage1.h" (this simplifies amalgation) - -namespace simdjson { - namespace westmere { - namespace { - namespace stage1 { - - class json_minifier { - public: - template - static error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) noexcept; - - private: - simdjson_inline json_minifier(uint8_t* _dst) - : dst{ _dst } - {} - template - simdjson_inline void step(const uint8_t* block_buf, buf_block_reader& reader) noexcept; - simdjson_inline void next(const simd::simd8x64& in, const json_block& block); - simdjson_inline error_code finish(uint8_t* dst_start, size_t& dst_len); - json_scanner scanner{}; - uint8_t* dst; - }; - - simdjson_inline void json_minifier::next(const simd::simd8x64& in, const json_block& block) { - uint64_t mask = block.whitespace(); - dst += in.compress(mask, dst); - } - - simdjson_inline error_code json_minifier::finish(uint8_t* dst_start, size_t& dst_len) { - error_code error = scanner.finish(); - if (error) { dst_len = 0; return error; } - dst_len = dst - dst_start; - return SUCCESS; - } - - template<> - simdjson_inline void json_minifier::step<128>(const uint8_t* block_buf, buf_block_reader<128>& reader) noexcept { - simd::simd8x64 in_1(block_buf); - simd::simd8x64 in_2(block_buf + 64); - json_block block_1 = scanner.next(in_1); - json_block block_2 = scanner.next(in_2); - this->next(in_1, block_1); - this->next(in_2, block_2); - reader.advance(); - } - - template<> - simdjson_inline void json_minifier::step<64>(const uint8_t* block_buf, buf_block_reader<64>& reader) noexcept { - simd::simd8x64 in_1(block_buf); - json_block block_1 = scanner.next(in_1); - this->next(block_buf, block_1); - reader.advance(); - } - - template - error_code json_minifier::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) noexcept { - buf_block_reader reader(buf, len); - json_minifier minifier(dst); - - // Index the first n-1 blocks - while (reader.has_full_block()) { - minifier.step(reader.full_block(), reader); - } - - // Index the last (remainder) block, padded with spaces - uint8_t block[STEP_SIZE]; - size_t remaining_bytes = reader.get_remainder(block); - if (remaining_bytes > 0) { - // We do not want to write directly to the output stream. Rather, we write - // to a local buffer (for safety). - uint8_t out_block[STEP_SIZE]; - uint8_t* const guarded_dst{ minifier.dst }; - minifier.dst = out_block; - minifier.step(block, reader); - size_t to_write = minifier.dst - out_block; - // In some cases, we could be enticed to consider the padded spaces - // as part of the string. This is fine as long as we do not write more - // than we consumed. - if (to_write > remaining_bytes) { to_write = remaining_bytes; } - memcpy(guarded_dst, out_block, to_write); - minifier.dst = guarded_dst + to_write; - } - return minifier.finish(dst, dst_len); - } - - } // namespace stage1 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/json_minifier.h */ -/* begin file src/generic/stage1/find_next_document_index.h */ -namespace simdjson { - namespace westmere { - namespace { - - /** - * This algorithm is used to quickly identify the last structural position that - * makes up a complete document. - * - * It does this by going backwards and finding the last *document boundary* (a - * place where one value follows another without a comma between them). If the - * last document (the characters after the boundary) has an equal number of - * start and end brackets, it is considered complete. - * - * Simply put, we iterate over the structural characters, starting from - * the end. We consider that we found the end of a JSON document when the - * first element of the pair is NOT one of these characters: '{' '[' ':' ',' - * and when the second element is NOT one of these characters: '}' ']' ':' ','. - * - * This simple comparison works most of the time, but it does not cover cases - * where the batch's structural indexes contain a perfect amount of documents. - * In such a case, we do not have access to the structural index which follows - * the last document, therefore, we do not have access to the second element in - * the pair, and that means we cannot identify the last document. To fix this - * issue, we keep a count of the open and closed curly/square braces we found - * while searching for the pair. When we find a pair AND the count of open and - * closed curly/square braces is the same, we know that we just passed a - * complete document, therefore the last json buffer location is the end of the - * batch. - */ - simdjson_inline uint32_t find_next_document_index(dom_parser_implementation& parser) { - // Variant: do not count separately, just figure out depth - if (parser.n_structural_indexes == 0) { return 0; } - auto arr_cnt = 0; - auto obj_cnt = 0; - for (auto i = parser.n_structural_indexes - 1; i > 0; i--) { - auto idxb = parser.structural_indexes[i]; - switch (parser.buf[idxb]) { - case ':': - case ',': - continue; - case '}': - obj_cnt--; - continue; - case ']': - arr_cnt--; - continue; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - auto idxa = parser.structural_indexes[i - 1]; - switch (parser.buf[idxa]) { - case '{': - case '[': - case ':': - case ',': - continue; - } - // Last document is complete, so the next document will appear after! - if (!arr_cnt && !obj_cnt) { - return parser.n_structural_indexes; - } - // Last document is incomplete; mark the document at i + 1 as the next one - return i; - } - // If we made it to the end, we want to finish counting to see if we have a full document. - switch (parser.buf[parser.structural_indexes[0]]) { - case '}': - obj_cnt--; - break; - case ']': - arr_cnt--; - break; - case '{': - obj_cnt++; - break; - case '[': - arr_cnt++; - break; - } - if (!arr_cnt && !obj_cnt) { - // We have a complete document. - return parser.n_structural_indexes; - } - return 0; - } - - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/find_next_document_index.h */ - -namespace simdjson { - namespace westmere { - namespace { - namespace stage1 { - - class bit_indexer { - public: - uint32_t* tail; - - simdjson_inline bit_indexer(uint32_t* index_buf) : tail(index_buf) {} - - // flatten out values in 'bits' assuming that they are are to have values of idx - // plus their position in the bitvector, and store these indexes at - // base_ptr[base] incrementing base as we go - // will potentially store extra values beyond end of valid bits, so base_ptr - // needs to be large enough to handle this - // - // If the kernel sets SIMDJSON_CUSTOM_BIT_INDEXER, then it will provide its own - // version of the code. -#ifdef SIMDJSON_CUSTOM_BIT_INDEXER - simdjson_inline void write(uint32_t idx, uint64_t bits); -#else - simdjson_inline void write(uint32_t idx, uint64_t bits) { - // In some instances, the next branch is expensive because it is mispredicted. - // Unfortunately, in other cases, - // it helps tremendously. - if (bits == 0) - return; -#if SIMDJSON_PREFER_REVERSE_BITS - /** - * ARM lacks a fast trailing zero instruction, but it has a fast - * bit reversal instruction and a fast leading zero instruction. - * Thus it may be profitable to reverse the bits (once) and then - * to rely on a sequence of instructions that call the leading - * zero instruction. - * - * Performance notes: - * The chosen routine is not optimal in terms of data dependency - * since zero_leading_bit might require two instructions. However, - * it tends to minimize the total number of instructions which is - * beneficial. - */ - - uint64_t rev_bits = reverse_bits(bits); - int cnt = static_cast(count_ones(bits)); - int i = 0; - // Do the first 8 all together - for (; i < 8; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - i = 8; - for (; i < 16; i++) { - int lz = leading_zeroes(rev_bits); - this->tail[i] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } - - - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - i = 16; - while (rev_bits != 0) { - int lz = leading_zeroes(rev_bits); - this->tail[i++] = static_cast(idx) + lz; - rev_bits = zero_leading_bit(rev_bits, lz); - } - } - } - this->tail += cnt; -#else // SIMDJSON_PREFER_REVERSE_BITS - /** - * Under recent x64 systems, we often have both a fast trailing zero - * instruction and a fast 'clear-lower-bit' instruction so the following - * algorithm can be competitive. - */ - - int cnt = static_cast(count_ones(bits)); - // Do the first 8 all together - for (int i = 0; i < 8; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Do the next 8 all together (we hope in most cases it won't happen at all - // and the branch is easily predicted). - if (simdjson_unlikely(cnt > 8)) { - for (int i = 8; i < 16; i++) { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - } - - // Most files don't have 16+ structurals per block, so we take several basically guaranteed - // branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :) - // or the start of a value ("abc" true 123) every four characters. - if (simdjson_unlikely(cnt > 16)) { - int i = 16; - do { - this->tail[i] = idx + trailing_zeroes(bits); - bits = clear_lowest_bit(bits); - i++; - } while (i < cnt); - } - } - - this->tail += cnt; -#endif - } -#endif // SIMDJSON_CUSTOM_BIT_INDEXER - - }; - - class json_structural_indexer { - public: - /** - * Find the important bits of JSON in a 128-byte chunk, and add them to structural_indexes. - * - * @param partial Setting the partial parameter to true allows the find_structural_bits to - * tolerate unclosed strings. The caller should still ensure that the input is valid UTF-8. If - * you are processing substrings, you may want to call on a function like trimmed_length_safe_utf8. - */ - template - static error_code index(const uint8_t* buf, size_t len, dom_parser_implementation& parser, stage1_mode partial) noexcept; - - private: - simdjson_inline json_structural_indexer(uint32_t* structural_indexes); - template - simdjson_inline void step(const uint8_t* block, buf_block_reader& reader) noexcept; - simdjson_inline void next(const simd::simd8x64& in, const json_block& block, size_t idx); - simdjson_inline error_code finish(dom_parser_implementation& parser, size_t idx, size_t len, stage1_mode partial); - - json_scanner scanner{}; - utf8_checker checker{}; - bit_indexer indexer; - uint64_t prev_structurals = 0; - uint64_t unescaped_chars_error = 0; - }; - - simdjson_inline json_structural_indexer::json_structural_indexer(uint32_t* structural_indexes) : indexer{ structural_indexes } {} - - // Skip the last character if it is partial - simdjson_inline size_t trim_partial_utf8(const uint8_t* buf, size_t len) { - if (simdjson_unlikely(len < 3)) { - switch (len) { - case 2: - if (buf[len - 1] >= 0xc0) { return len - 1; } // 2-, 3- and 4-byte characters with only 1 byte left - if (buf[len - 2] >= 0xe0) { return len - 2; } // 3- and 4-byte characters with only 2 bytes left - return len; - case 1: - if (buf[len - 1] >= 0xc0) { return len - 1; } // 2-, 3- and 4-byte characters with only 1 byte left - return len; - case 0: - return len; - } - } - if (buf[len - 1] >= 0xc0) { return len - 1; } // 2-, 3- and 4-byte characters with only 1 byte left - if (buf[len - 2] >= 0xe0) { return len - 2; } // 3- and 4-byte characters with only 1 byte left - if (buf[len - 3] >= 0xf0) { return len - 3; } // 4-byte characters with only 3 bytes left - return len; - } - - // - // PERF NOTES: - // We pipe 2 inputs through these stages: - // 1. Load JSON into registers. This takes a long time and is highly parallelizable, so we load - // 2 inputs' worth at once so that by the time step 2 is looking for them input, it's available. - // 2. Scan the JSON for critical data: strings, scalars and operators. This is the critical path. - // The output of step 1 depends entirely on this information. These functions don't quite use - // up enough CPU: the second half of the functions is highly serial, only using 1 execution core - // at a time. The second input's scans has some dependency on the first ones finishing it, but - // they can make a lot of progress before they need that information. - // 3. Step 1 doesn't use enough capacity, so we run some extra stuff while we're waiting for that - // to finish: utf-8 checks and generating the output from the last iteration. - // - // The reason we run 2 inputs at a time, is steps 2 and 3 are *still* not enough to soak up all - // available capacity with just one input. Running 2 at a time seems to give the CPU a good enough - // workout. - // - template - error_code json_structural_indexer::index(const uint8_t* buf, size_t len, dom_parser_implementation& parser, stage1_mode partial) noexcept { - if (simdjson_unlikely(len > parser.capacity())) { return CAPACITY; } - // We guard the rest of the code so that we can assume that len > 0 throughout. - if (len == 0) { return EMPTY; } - if (is_streaming(partial)) { - len = trim_partial_utf8(buf, len); - // If you end up with an empty window after trimming - // the partial UTF-8 bytes, then chances are good that you - // have an UTF-8 formatting error. - if (len == 0) { return UTF8_ERROR; } - } - buf_block_reader reader(buf, len); - json_structural_indexer indexer(parser.structural_indexes.get()); - - // Read all but the last block - while (reader.has_full_block()) { - indexer.step(reader.full_block(), reader); - } - // Take care of the last block (will always be there unless file is empty which is - // not supposed to happen.) - uint8_t block[STEP_SIZE]; - if (simdjson_unlikely(reader.get_remainder(block) == 0)) { return UNEXPECTED_ERROR; } - indexer.step(block, reader); - return indexer.finish(parser, reader.block_index(), len, partial); - } - - template<> - simdjson_inline void json_structural_indexer::step<128>(const uint8_t* block, buf_block_reader<128>& reader) noexcept { - simd::simd8x64 in_1(block); - simd::simd8x64 in_2(block + 64); - json_block block_1 = scanner.next(in_1); - json_block block_2 = scanner.next(in_2); - this->next(in_1, block_1, reader.block_index()); - this->next(in_2, block_2, reader.block_index() + 64); - reader.advance(); - } - - template<> - simdjson_inline void json_structural_indexer::step<64>(const uint8_t* block, buf_block_reader<64>& reader) noexcept { - simd::simd8x64 in_1(block); - json_block block_1 = scanner.next(in_1); - this->next(in_1, block_1, reader.block_index()); - reader.advance(); - } - - simdjson_inline void json_structural_indexer::next(const simd::simd8x64& in, const json_block& block, size_t idx) { - uint64_t unescaped = in.lteq(0x1F); -#if SIMDJSON_UTF8VALIDATION - checker.check_next_input(in); -#endif - indexer.write(uint32_t(idx - 64), prev_structurals); // Output *last* iteration's structurals to the parser - prev_structurals = block.structural_start(); - unescaped_chars_error |= block.non_quote_inside_string(unescaped); - } - - simdjson_inline error_code json_structural_indexer::finish(dom_parser_implementation& parser, size_t idx, size_t len, stage1_mode partial) { - // Write out the final iteration's structurals - indexer.write(uint32_t(idx - 64), prev_structurals); - error_code error = scanner.finish(); - // We deliberately break down the next expression so that it is - // human readable. - const bool should_we_exit = is_streaming(partial) ? - ((error != SUCCESS) && (error != UNCLOSED_STRING)) // when partial we tolerate UNCLOSED_STRING - : (error != SUCCESS); // if partial is false, we must have SUCCESS - const bool have_unclosed_string = (error == UNCLOSED_STRING); - if (simdjson_unlikely(should_we_exit)) { return error; } - - if (unescaped_chars_error) { - return UNESCAPED_CHARS; - } - parser.n_structural_indexes = uint32_t(indexer.tail - parser.structural_indexes.get()); - /*** - * The On Demand API requires special padding. - * - * This is related to https://github.com/simdjson/simdjson/issues/906 - * Basically, we want to make sure that if the parsing continues beyond the last (valid) - * structural character, it quickly stops. - * Only three structural characters can be repeated without triggering an error in JSON: [,] and }. - * We repeat the padding character (at 'len'). We don't know what it is, but if the parsing - * continues, then it must be [,] or }. - * Suppose it is ] or }. We backtrack to the first character, what could it be that would - * not trigger an error? It could be ] or } but no, because you can't start a document that way. - * It can't be a comma, a colon or any simple value. So the only way we could continue is - * if the repeated character is [. But if so, the document must start with [. But if the document - * starts with [, it should end with ]. If we enforce that rule, then we would get - * ][[ which is invalid. - * - * This is illustrated with the test array_iterate_unclosed_error() on the following input: - * R"({ "a": [,,)" - **/ - parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len); // used later in partial == stage1_mode::streaming_final - parser.structural_indexes[parser.n_structural_indexes + 1] = uint32_t(len); - parser.structural_indexes[parser.n_structural_indexes + 2] = 0; - parser.next_structural_index = 0; - // a valid JSON file cannot have zero structural indexes - we should have found something - if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { - return EMPTY; - } - if (simdjson_unlikely(parser.structural_indexes[parser.n_structural_indexes - 1] > len)) { - return UNEXPECTED_ERROR; - } - if (partial == stage1_mode::streaming_partial) { - // If we have an unclosed string, then the last structural - // will be the quote and we want to make sure to omit it. - if (have_unclosed_string) { - parser.n_structural_indexes--; - // a valid JSON file cannot have zero structural indexes - we should have found something - if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { return CAPACITY; } - } - // We truncate the input to the end of the last complete document (or zero). - auto new_structural_indexes = find_next_document_index(parser); - if (new_structural_indexes == 0 && parser.n_structural_indexes > 0) { - if (parser.structural_indexes[0] == 0) { - // If the buffer is partial and we started at index 0 but the document is - // incomplete, it's too big to parse. - return CAPACITY; - } - else { - // It is possible that the document could be parsed, we just had a lot - // of white space. - parser.n_structural_indexes = 0; - return EMPTY; - } - } - - parser.n_structural_indexes = new_structural_indexes; - } - else if (partial == stage1_mode::streaming_final) { - if (have_unclosed_string) { parser.n_structural_indexes--; } - // We truncate the input to the end of the last complete document (or zero). - // Because partial == stage1_mode::streaming_final, it means that we may - // silently ignore trailing garbage. Though it sounds bad, we do it - // deliberately because many people who have streams of JSON documents - // will truncate them for processing. E.g., imagine that you are uncompressing - // the data from a size file or receiving it in chunks from the network. You - // may not know where exactly the last document will be. Meanwhile the - // document_stream instances allow people to know the JSON documents they are - // parsing (see the iterator.source() method). - parser.n_structural_indexes = find_next_document_index(parser); - // We store the initial n_structural_indexes so that the client can see - // whether we used truncation. If initial_n_structural_indexes == parser.n_structural_indexes, - // then this will query parser.structural_indexes[parser.n_structural_indexes] which is len, - // otherwise, it will copy some prior index. - parser.structural_indexes[parser.n_structural_indexes + 1] = parser.structural_indexes[parser.n_structural_indexes]; - // This next line is critical, do not change it unless you understand what you are - // doing. - parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len); - if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { - // We tolerate an unclosed string at the very end of the stream. Indeed, users - // often load their data in bulk without being careful and they want us to ignore - // the trailing garbage. - return EMPTY; - } - } - checker.check_eof(); - return checker.errors(); - } - - } // namespace stage1 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/json_structural_indexer.h */ -/* begin file src/generic/stage1/utf8_validator.h */ -namespace simdjson { - namespace westmere { - namespace { - namespace stage1 { - - /** - * Validates that the string is actual UTF-8. - */ - template - bool generic_validate_utf8(const uint8_t* input, size_t length) { - checker c{}; - buf_block_reader<64> reader(input, length); - while (reader.has_full_block()) { - simd::simd8x64 in(reader.full_block()); - c.check_next_input(in); - reader.advance(); - } - uint8_t block[64]{}; - reader.get_remainder(block); - simd::simd8x64 in(block); - c.check_next_input(in); - reader.advance(); - c.check_eof(); - return c.errors() == error_code::SUCCESS; - } - - bool generic_validate_utf8(const char* input, size_t length) { - return generic_validate_utf8(reinterpret_cast(input), length); - } - - } // namespace stage1 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage1/utf8_validator.h */ - // // Stage 2 // -/* begin file src/generic/stage2/stringparsing.h */ -// This file contains the common code every implementation uses -// It is intended to be included multiple times and compiled multiple times - -namespace simdjson { - namespace westmere { - namespace { - /// @private - namespace stringparsing { - - // begin copypasta - // These chars yield themselves: " \ / - // b -> backspace, f -> formfeed, n -> newline, r -> cr, t -> horizontal tab - // u not handled in this table as it's complex - static const uint8_t escape_map[256] = { - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x0. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0x22, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x2f, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x4. - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x5c, 0, 0, 0, // 0x5. - 0, 0, 0x08, 0, 0, 0, 0x0c, 0, 0, 0, 0, 0, 0, 0, 0x0a, 0, // 0x6. - 0, 0, 0x0d, 0, 0x09, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 0x7. - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, - }; - - // handle a unicode codepoint - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint(const uint8_t** src_ptr, - uint8_t** dst_ptr, bool allow_replacement) { - // Use the default Unicode Character 'REPLACEMENT CHARACTER' (U+FFFD) - constexpr uint32_t substitution_code_point = 0xfffd; - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) != ((static_cast ('\\') << 8) | static_cast ('u'))) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - - // We have already checked that the high surrogate is valid and - // (code_point - 0xd800) < 1024. - // - // Check that code_point_2 is in the range 0xdc00..0xdfff - // and that code_point_2 was parsed from valid hex. - uint32_t low_bit = code_point_2 - 0xdc00; - if (low_bit >> 10) { - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - else { - code_point = (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - - } - } - else if (code_point >= 0xdc00 && code_point <= 0xdfff) { - // If we encounter a low surrogate (not preceded by a high surrogate) - // then we have an error. - if (!allow_replacement) { return false; } - code_point = substitution_code_point; - } - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - // handle a unicode codepoint using the wobbly convention - // https://simonsapin.github.io/wtf-8/ - // write appropriate values into dest - // src will advance 6 bytes or 12 bytes - // dest will advance a variable amount (return via pointer) - // return true if the unicode codepoint was valid - // We work in little-endian then swap at write time - simdjson_warn_unused - simdjson_inline bool handle_unicode_codepoint_wobbly(const uint8_t** src_ptr, - uint8_t** dst_ptr) { - // It is not ideal that this function is nearly identical to handle_unicode_codepoint. - // - // jsoncharutils::hex_to_u32_nocheck fills high 16 bits of the return value with 1s if the - // conversion isn't valid; we defer the check for this to inside the - // multilingual plane check - uint32_t code_point = jsoncharutils::hex_to_u32_nocheck(*src_ptr + 2); - *src_ptr += 6; - // If we found a high surrogate, we must - // check for low surrogate for characters - // outside the Basic - // Multilingual Plane. - if (code_point >= 0xd800 && code_point < 0xdc00) { - const uint8_t* src_data = *src_ptr; - /* Compiler optimizations convert this to a single 16-bit load and compare on most platforms */ - if (((src_data[0] << 8) | src_data[1]) == ((static_cast ('\\') << 8) | static_cast ('u'))) { - uint32_t code_point_2 = jsoncharutils::hex_to_u32_nocheck(src_data + 2); - uint32_t low_bit = code_point_2 - 0xdc00; - if ((low_bit >> 10) == 0) { - code_point = - (((code_point - 0xd800) << 10) | low_bit) + 0x10000; - *src_ptr += 6; - } - } - } - - size_t offset = jsoncharutils::codepoint_to_utf8(code_point, *dst_ptr); - *dst_ptr += offset; - return offset > 0; - } - - - /** - * Unescape a valid UTF-8 string from src to dst, stopping at a final unescaped quote. There - * must be an unescaped quote terminating the string. It returns the final output - * position as pointer. In case of error (e.g., the string has bad escaped codes), - * then null_nullptrptr is returned. It is assumed that the output buffer is large - * enough. E.g., if src points at 'joe"', then dst needs to have four free bytes + - * SIMDJSON_PADDING bytes. - */ - simdjson_warn_unused simdjson_inline uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) { - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint(&src, &dst, allow_replacement)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - simdjson_warn_unused simdjson_inline uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) { - // It is not ideal that this function is nearly identical to parse_string. - while (1) { - // Copy the next n bytes, and find the backslash and quote in them. - auto bs_quote = backslash_and_quote::copy_and_find(src, dst); - // If the next thing is the end quote, copy and return - if (bs_quote.has_quote_first()) { - // we encountered quotes first. Move dst to point to quotes and exit - return dst + bs_quote.quote_index(); - } - if (bs_quote.has_backslash()) { - /* find out where the backspace is */ - auto bs_dist = bs_quote.backslash_index(); - uint8_t escape_char = src[bs_dist + 1]; - /* we encountered backslash first. Handle backslash */ - if (escape_char == 'u') { - /* move src/dst up to the start; they will be further adjusted - within the unicode codepoint handling code. */ - src += bs_dist; - dst += bs_dist; - if (!handle_unicode_codepoint_wobbly(&src, &dst)) { - return nullptr; - } - } - else { - /* simple 1:1 conversion. Will eat bs_dist+2 characters in input and - * write bs_dist+1 characters to output - * note this may reach beyond the part of the buffer we've actually - * seen. I think this is ok */ - uint8_t escape_result = escape_map[escape_char]; - if (escape_result == 0u) { - return nullptr; /* bogus escape value is an error */ - } - dst[bs_dist] = escape_result; - src += bs_dist + 2; - dst += bs_dist + 1; - } - } - else { - /* they are the same. Since they can't co-occur, it means we - * encountered neither. */ - src += backslash_and_quote::BYTES_PROCESSED; - dst += backslash_and_quote::BYTES_PROCESSED; - } - } - /* can't be reached */ - return nullptr; - } - - } // namespace stringparsing - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage2/stringparsing.h */ -/* begin file src/generic/stage2/tape_builder.h */ -/* begin file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/logger.h */ -// This is for an internal-only stage 2 specific logger. -// Set LOG_ENABLED = true to log what stage 2 is doing! -namespace simdjson { - namespace westmere { - namespace { - namespace logger { - - static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; - -#if SIMDJSON_VERBOSE_LOGGING - static constexpr const bool LOG_ENABLED = true; -#else - static constexpr const bool LOG_ENABLED = false; -#endif - static constexpr const int LOG_EVENT_LEN = 20; - static constexpr const int LOG_BUFFER_LEN = 30; - static constexpr const int LOG_SMALL_BUFFER_LEN = 10; - static constexpr const int LOG_INDEX_LEN = 5; - - static int log_depth; // Not threadsafe. Log only. - - // Helper to turn unprintable or newline characters into spaces - static simdjson_inline char printable_char(char c) { - if (c >= 0x20) { - return c; - } - else { - return ' '; - } - } - - // Print the header and set up log_start - static simdjson_inline void log_start() { - if (LOG_ENABLED) { - log_depth = 0; - printf("\n"); - printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#"); - printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN + 2, DASHES, LOG_BUFFER_LEN + 2, DASHES, LOG_SMALL_BUFFER_LEN + 2, DASHES, 5 + 2, DASHES); - } - } - - simdjson_unused static simdjson_inline void log_string(const char* message) { - if (LOG_ENABLED) { - printf("%s\n", message); - } - } - - // Logs a single line from the stage 2 DOM parser - template - static simdjson_inline void log_line(S& structurals, const char* title_prefix, const char* title, const char* detail) { - if (LOG_ENABLED) { - printf("| %*s%s%-*s ", log_depth * 2, "", title_prefix, LOG_EVENT_LEN - log_depth * 2 - int(strlen(title_prefix)), title); - auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural - 1; - auto next_index = structurals.next_structural; - auto current = current_index ? &structurals.buf[*current_index] : reinterpret_cast(" "); - auto next = &structurals.buf[*next_index]; - { - // Print the next N characters in the buffer. - printf("| "); - // Otherwise, print the characters starting from the buffer position. - // Print spaces for unprintable or newline characters. - for (int i = 0; i < LOG_BUFFER_LEN; i++) { - printf("%c", printable_char(current[i])); - } - printf(" "); - // Print the next N characters in the buffer. - printf("| "); - // Otherwise, print the characters starting from the buffer position. - // Print spaces for unprintable or newline characters. - for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { - printf("%c", printable_char(next[i])); - } - printf(" "); - } - if (current_index) { - printf("| %*u ", LOG_INDEX_LEN, *current_index); - } - else { - printf("| %-*s ", LOG_INDEX_LEN, ""); - } - // printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index()); - printf("| %-s ", detail); - printf("|\n"); - } - } - - } // namespace logger - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage2/logger.h */ - -namespace simdjson { - namespace westmere { - namespace { - namespace stage2 { - - class json_iterator { - public: - const uint8_t* const buf; - uint32_t* next_structural; - dom_parser_implementation& dom_parser; - uint32_t depth{ 0 }; - - /** - * Walk the JSON document. - * - * The visitor receives callbacks when values are encountered. All callbacks pass the iterator as - * the first parameter; some callbacks have other parameters as well: - * - * - visit_document_start() - at the beginning. - * - visit_document_end() - at the end (if things were successful). - * - * - visit_array_start() - at the start `[` of a non-empty array. - * - visit_array_end() - at the end `]` of a non-empty array. - * - visit_empty_array() - when an empty array is encountered. - * - * - visit_object_end() - at the start `]` of a non-empty object. - * - visit_object_start() - at the end `]` of a non-empty object. - * - visit_empty_object() - when an empty object is encountered. - * - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is - * guaranteed to point at the first quote of the string (`"key"`). - * - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null. - * - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null. - * - * - increment_count(iter) - each time a value is found in an array or object. - */ - template - simdjson_warn_unused simdjson_inline error_code walk_document(V& visitor) noexcept; - - /** - * Create an iterator capable of walking a JSON document. - * - * The document must have already passed through stage 1. - */ - simdjson_inline json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index); - - /** - * Look at the next token. - * - * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). - * - * They may include invalid JSON as well (such as `1.2.3` or `ture`). - */ - simdjson_inline const uint8_t* peek() const noexcept; - /** - * Advance to the next token. - * - * Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)). - * - * They may include invalid JSON as well (such as `1.2.3` or `ture`). - */ - simdjson_inline const uint8_t* advance() noexcept; - /** - * Get the remaining length of the document, from the start of the current token. - */ - simdjson_inline size_t remaining_len() const noexcept; - /** - * Check if we are at the end of the document. - * - * If this is true, there are no more tokens. - */ - simdjson_inline bool at_eof() const noexcept; - /** - * Check if we are at the beginning of the document. - */ - simdjson_inline bool at_beginning() const noexcept; - simdjson_inline uint8_t last_structural() const noexcept; - - /** - * Log that a value has been found. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_value(const char* type) const noexcept; - /** - * Log the start of a multipart value. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_start_value(const char* type) const noexcept; - /** - * Log the end of a multipart value. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_end_value(const char* type) const noexcept; - /** - * Log an error. - * - * Set LOG_ENABLED=true in logger.h to see logging. - */ - simdjson_inline void log_error(const char* error) const noexcept; - - template - simdjson_warn_unused simdjson_inline error_code visit_root_primitive(V& visitor, const uint8_t* value) noexcept; - template - simdjson_warn_unused simdjson_inline error_code visit_primitive(V& visitor, const uint8_t* value) noexcept; - }; - - template - simdjson_warn_unused simdjson_inline error_code json_iterator::walk_document(V& visitor) noexcept { - logger::log_start(); - - // - // Start the document - // - if (at_eof()) { return EMPTY; } - log_start_value("document"); - SIMDJSON_TRY(visitor.visit_document_start(*this)); - - // - // Read first value - // - { - auto value = advance(); - - // Make sure the outer object or array is closed before continuing; otherwise, there are ways we - // could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906 - if (!STREAMING) { - switch (*value) { - case '{': if (last_structural() != '}') { log_value("starting brace unmatched"); return TAPE_ERROR; }; break; - case '[': if (last_structural() != ']') { log_value("starting bracket unmatched"); return TAPE_ERROR; }; break; - } - } - - switch (*value) { - case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; - case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; - default: SIMDJSON_TRY(visitor.visit_root_primitive(*this, value)); break; - } - } - goto document_end; - - // - // Object parser states - // - object_begin: - log_start_value("object"); - depth++; - if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } - dom_parser.is_array[depth] = false; - SIMDJSON_TRY(visitor.visit_object_start(*this)); - - { - auto key = advance(); - if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; } - SIMDJSON_TRY(visitor.increment_count(*this)); - SIMDJSON_TRY(visitor.visit_key(*this, key)); - } - - object_field: - if (simdjson_unlikely(*advance() != ':')) { log_error("Missing colon after key in object"); return TAPE_ERROR; } - { - auto value = advance(); - switch (*value) { - case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; - case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; - default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; - } - } - - object_continue: - switch (*advance()) { - case ',': - SIMDJSON_TRY(visitor.increment_count(*this)); - { - auto key = advance(); - if (simdjson_unlikely(*key != '"')) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; } - SIMDJSON_TRY(visitor.visit_key(*this, key)); - } - goto object_field; - case '}': log_end_value("object"); SIMDJSON_TRY(visitor.visit_object_end(*this)); goto scope_end; - default: log_error("No comma between object fields"); return TAPE_ERROR; - } - - scope_end: - depth--; - if (depth == 0) { goto document_end; } - if (dom_parser.is_array[depth]) { goto array_continue; } - goto object_continue; - - // - // Array parser states - // - array_begin: - log_start_value("array"); - depth++; - if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; } - dom_parser.is_array[depth] = true; - SIMDJSON_TRY(visitor.visit_array_start(*this)); - SIMDJSON_TRY(visitor.increment_count(*this)); - - array_value: - { - auto value = advance(); - switch (*value) { - case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY(visitor.visit_empty_object(*this)); break; } goto object_begin; - case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY(visitor.visit_empty_array(*this)); break; } goto array_begin; - default: SIMDJSON_TRY(visitor.visit_primitive(*this, value)); break; - } - } - - array_continue: - switch (*advance()) { - case ',': SIMDJSON_TRY(visitor.increment_count(*this)); goto array_value; - case ']': log_end_value("array"); SIMDJSON_TRY(visitor.visit_array_end(*this)); goto scope_end; - default: log_error("Missing comma between array values"); return TAPE_ERROR; - } - - document_end: - log_end_value("document"); - SIMDJSON_TRY(visitor.visit_document_end(*this)); - - dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]); - - // If we didn't make it to the end, it's an error - if (!STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes) { - log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!"); - return TAPE_ERROR; - } - - return SUCCESS; - - } // walk_document() - - simdjson_inline json_iterator::json_iterator(dom_parser_implementation& _dom_parser, size_t start_structural_index) - : buf{ _dom_parser.buf }, - next_structural{ &_dom_parser.structural_indexes[start_structural_index] }, - dom_parser{ _dom_parser } { - } - - simdjson_inline const uint8_t* json_iterator::peek() const noexcept { - return &buf[*(next_structural)]; - } - simdjson_inline const uint8_t* json_iterator::advance() noexcept { - return &buf[*(next_structural++)]; - } - simdjson_inline size_t json_iterator::remaining_len() const noexcept { - return dom_parser.len - *(next_structural - 1); - } - - simdjson_inline bool json_iterator::at_eof() const noexcept { - return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes]; - } - simdjson_inline bool json_iterator::at_beginning() const noexcept { - return next_structural == dom_parser.structural_indexes.get(); - } - simdjson_inline uint8_t json_iterator::last_structural() const noexcept { - return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]]; - } - - simdjson_inline void json_iterator::log_value(const char* type) const noexcept { - logger::log_line(*this, "", type, ""); - } - - simdjson_inline void json_iterator::log_start_value(const char* type) const noexcept { - logger::log_line(*this, "+", type, ""); - if (logger::LOG_ENABLED) { logger::log_depth++; } - } - - simdjson_inline void json_iterator::log_end_value(const char* type) const noexcept { - if (logger::LOG_ENABLED) { logger::log_depth--; } - logger::log_line(*this, "-", type, ""); - } - - simdjson_inline void json_iterator::log_error(const char* error) const noexcept { - logger::log_line(*this, "", "ERROR", error); - } - - template - simdjson_warn_unused simdjson_inline error_code json_iterator::visit_root_primitive(V& visitor, const uint8_t* value) noexcept { - switch (*value) { - case '"': return visitor.visit_root_string(*this, value); - case 't': return visitor.visit_root_true_atom(*this, value); - case 'f': return visitor.visit_root_false_atom(*this, value); - case 'n': return visitor.visit_root_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_root_number(*this, value); - default: - log_error("Document starts with a non-value character"); - return TAPE_ERROR; - } - } - template - simdjson_warn_unused simdjson_inline error_code json_iterator::visit_primitive(V& visitor, const uint8_t* value) noexcept { - switch (*value) { - case '"': return visitor.visit_string(*this, value); - case 't': return visitor.visit_true_atom(*this, value); - case 'f': return visitor.visit_false_atom(*this, value); - case 'n': return visitor.visit_null_atom(*this, value); - case '-': - case '0': case '1': case '2': case '3': case '4': - case '5': case '6': case '7': case '8': case '9': - return visitor.visit_number(*this, value); - default: - log_error("Non-value found when value was expected!"); - return TAPE_ERROR; - } - } - - } // namespace stage2 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage2/json_iterator.h */ -/* begin file src/generic/stage2/tape_writer.h */ -namespace simdjson { - namespace westmere { - namespace { - namespace stage2 { - - struct tape_writer { - /** The next place to write to tape */ - uint64_t* next_tape_loc; - - /** Write a signed 64-bit value to tape. */ - simdjson_inline void append_s64(int64_t value) noexcept; - - /** Write an unsigned 64-bit value to tape. */ - simdjson_inline void append_u64(uint64_t value) noexcept; - - /** Write a double value to tape. */ - simdjson_inline void append_double(double value) noexcept; - - /** - * Append a tape entry (an 8-bit type,and 56 bits worth of value). - */ - simdjson_inline void append(uint64_t val, internal::tape_type t) noexcept; - - /** - * Skip the current tape entry without writing. - * - * Used to skip the start of the container, since we'll come back later to fill it in when the - * container ends. - */ - simdjson_inline void skip() noexcept; - - /** - * Skip the number of tape entries necessary to write a large u64 or i64. - */ - simdjson_inline void skip_large_integer() noexcept; - - /** - * Skip the number of tape entries necessary to write a double. - */ - simdjson_inline void skip_double() noexcept; - - /** - * Write a value to a known location on tape. - * - * Used to go back and write out the start of a container after the container ends. - */ - simdjson_inline static void write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept; - - private: - /** - * Append both the tape entry, and a supplementary value following it. Used for types that need - * all 64 bits, such as double and uint64_t. - */ - template - simdjson_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept; - }; // struct number_writer - - simdjson_inline void tape_writer::append_s64(int64_t value) noexcept { - append2(0, value, internal::tape_type::INT64); - } - - simdjson_inline void tape_writer::append_u64(uint64_t value) noexcept { - append(0, internal::tape_type::UINT64); - *next_tape_loc = value; - next_tape_loc++; - } - - /** Write a double value to tape. */ - simdjson_inline void tape_writer::append_double(double value) noexcept { - append2(0, value, internal::tape_type::DOUBLE); - } - - simdjson_inline void tape_writer::skip() noexcept { - next_tape_loc++; - } - - simdjson_inline void tape_writer::skip_large_integer() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::skip_double() noexcept { - next_tape_loc += 2; - } - - simdjson_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept { - *next_tape_loc = val | ((uint64_t(char(t))) << 56); - next_tape_loc++; - } - - template - simdjson_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept { - append(val, t); - static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!"); - memcpy(next_tape_loc, &val2, sizeof(val2)); - next_tape_loc++; - } - - simdjson_inline void tape_writer::write(uint64_t& tape_loc, uint64_t val, internal::tape_type t) noexcept { - tape_loc = val | ((uint64_t(char(t))) << 56); - } - - } // namespace stage2 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage2/tape_writer.h */ - -namespace simdjson { - namespace westmere { - namespace { - namespace stage2 { - - struct tape_builder { - template - simdjson_warn_unused static simdjson_inline error_code parse_document( - dom_parser_implementation& dom_parser, - dom::document& doc) noexcept; - - /** Called when a non-empty document starts. */ - simdjson_warn_unused simdjson_inline error_code visit_document_start(json_iterator& iter) noexcept; - /** Called when a non-empty document ends without error. */ - simdjson_warn_unused simdjson_inline error_code visit_document_end(json_iterator& iter) noexcept; - - /** Called when a non-empty array starts. */ - simdjson_warn_unused simdjson_inline error_code visit_array_start(json_iterator& iter) noexcept; - /** Called when a non-empty array ends. */ - simdjson_warn_unused simdjson_inline error_code visit_array_end(json_iterator& iter) noexcept; - /** Called when an empty array is found. */ - simdjson_warn_unused simdjson_inline error_code visit_empty_array(json_iterator& iter) noexcept; - - /** Called when a non-empty object starts. */ - simdjson_warn_unused simdjson_inline error_code visit_object_start(json_iterator& iter) noexcept; - /** - * Called when a key in a field is encountered. - * - * primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array - * will be called after this with the field value. - */ - simdjson_warn_unused simdjson_inline error_code visit_key(json_iterator& iter, const uint8_t* key) noexcept; - /** Called when a non-empty object ends. */ - simdjson_warn_unused simdjson_inline error_code visit_object_end(json_iterator& iter) noexcept; - /** Called when an empty object is found. */ - simdjson_warn_unused simdjson_inline error_code visit_empty_object(json_iterator& iter) noexcept; - - /** - * Called when a string, number, boolean or null is found. - */ - simdjson_warn_unused simdjson_inline error_code visit_primitive(json_iterator& iter, const uint8_t* value) noexcept; - /** - * Called when a string, number, boolean or null is found at the top level of a document (i.e. - * when there is no array or object and the entire document is a single string, number, boolean or - * null. - * - * This is separate from primitive() because simdjson's normal primitive parsing routines assume - * there is at least one more token after the value, which is only true in an array or object. - */ - simdjson_warn_unused simdjson_inline error_code visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept; - - simdjson_warn_unused simdjson_inline error_code visit_string(json_iterator& iter, const uint8_t* value, bool key = false) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_number(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept; - - simdjson_warn_unused simdjson_inline error_code visit_root_string(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_number(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept; - simdjson_warn_unused simdjson_inline error_code visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept; - - /** Called each time a new field or element in an array or object is found. */ - simdjson_warn_unused simdjson_inline error_code increment_count(json_iterator& iter) noexcept; - - /** Next location to write to tape */ - tape_writer tape; - private: - /** Next write location in the string buf for stage 2 parsing */ - uint8_t* current_string_buf_loc; - - simdjson_inline tape_builder(dom::document& doc) noexcept; - - simdjson_inline uint32_t next_tape_index(json_iterator& iter) const noexcept; - simdjson_inline void start_container(json_iterator& iter) noexcept; - simdjson_warn_unused simdjson_inline error_code end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; - simdjson_warn_unused simdjson_inline error_code empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept; - simdjson_inline uint8_t* on_start_string(json_iterator& iter) noexcept; - simdjson_inline void on_end_string(uint8_t* dst) noexcept; - }; // class tape_builder - - template - simdjson_warn_unused simdjson_inline error_code tape_builder::parse_document( - dom_parser_implementation& dom_parser, - dom::document& doc) noexcept { - dom_parser.doc = &doc; - json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0); - tape_builder builder(doc); - return iter.walk_document(builder); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_primitive(json_iterator& iter, const uint8_t* value) noexcept { - return iter.visit_root_primitive(*this, value); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_primitive(json_iterator& iter, const uint8_t* value) noexcept { - return iter.visit_primitive(*this, value); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_object(json_iterator& iter) noexcept { - return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_empty_array(json_iterator& iter) noexcept { - return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_start(json_iterator& iter) noexcept { - start_container(iter); - return SUCCESS; - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_start(json_iterator& iter) noexcept { - start_container(iter); - return SUCCESS; - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_start(json_iterator& iter) noexcept { - start_container(iter); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_object_end(json_iterator& iter) noexcept { - return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_array_end(json_iterator& iter) noexcept { - return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY); - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_document_end(json_iterator& iter) noexcept { - constexpr uint32_t start_tape_index = 0; - tape.append(start_tape_index, internal::tape_type::ROOT); - tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT); - return SUCCESS; - } - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_key(json_iterator& iter, const uint8_t* key) noexcept { - return visit_string(iter, key, true); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::increment_count(json_iterator& iter) noexcept { - iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1 - return SUCCESS; - } - - simdjson_inline tape_builder::tape_builder(dom::document& doc) noexcept : tape{ doc.tape.get() }, current_string_buf_loc{ doc.string_buf.get() } {} - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_string(json_iterator& iter, const uint8_t* value, bool key) noexcept { - iter.log_value(key ? "key" : "string"); - uint8_t* dst = on_start_string(iter); - dst = stringparsing::parse_string(value + 1, dst, false); // We do not allow replacement when the escape characters are invalid. - if (dst == nullptr) { - iter.log_error("Invalid escape in string"); - return STRING_ERROR; - } - on_end_string(dst); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_string(json_iterator& iter, const uint8_t* value) noexcept { - return visit_string(iter, value); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_number(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("number"); - return numberparsing::parse_number(value, tape); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_number(json_iterator& iter, const uint8_t* value) noexcept { - // - // We need to make a copy to make sure that the string is space terminated. - // This is not about padding the input, which should already padded up - // to len + SIMDJSON_PADDING. However, we have no control at this stage - // on how the padding was done. What if the input string was padded with nulls? - // It is quite common for an input string to have an extra null character (C string). - // We do not want to allow 9\0 (where \0 is the null character) inside a JSON - // document, but the string "9\0" by itself is fine. So we make a copy and - // pad the input with spaces when we know that there is just one input element. - // This copy is relatively expensive, but it will almost never be called in - // practice unless you are in the strange scenario where you have many JSON - // documents made of single atoms. - // - std::unique_ptrcopy(new (std::nothrow) uint8_t[iter.remaining_len() + SIMDJSON_PADDING]); - if (copy.get() == nullptr) { return MEMALLOC; } - std::memcpy(copy.get(), value, iter.remaining_len()); - std::memset(copy.get() + iter.remaining_len(), ' ', SIMDJSON_PADDING); - error_code error = visit_number(iter, copy.get()); - return error; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_true_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("true"); - if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; } - tape.append(0, internal::tape_type::TRUE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_true_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("true"); - if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; } - tape.append(0, internal::tape_type::TRUE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_false_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("false"); - if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; } - tape.append(0, internal::tape_type::FALSE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_false_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("false"); - if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; } - tape.append(0, internal::tape_type::FALSE_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_null_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("null"); - if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; } - tape.append(0, internal::tape_type::NULL_VALUE); - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::visit_root_null_atom(json_iterator& iter, const uint8_t* value) noexcept { - iter.log_value("null"); - if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; } - tape.append(0, internal::tape_type::NULL_VALUE); - return SUCCESS; - } - - // private: - - simdjson_inline uint32_t tape_builder::next_tape_index(json_iterator& iter) const noexcept { - return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get()); - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::empty_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { - auto start_index = next_tape_index(iter); - tape.append(start_index + 2, start); - tape.append(start_index, end); - return SUCCESS; - } - - simdjson_inline void tape_builder::start_container(json_iterator& iter) noexcept { - iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter); - iter.dom_parser.open_containers[iter.depth].count = 0; - tape.skip(); // We don't actually *write* the start element until the end. - } - - simdjson_warn_unused simdjson_inline error_code tape_builder::end_container(json_iterator& iter, internal::tape_type start, internal::tape_type end) noexcept { - // Write the ending tape element, pointing at the start location - const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index; - tape.append(start_tape_index, end); - // Write the start tape element, pointing at the end location (and including count) - // count can overflow if it exceeds 24 bits... so we saturate - // the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff). - const uint32_t count = iter.dom_parser.open_containers[iter.depth].count; - const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count; - tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start); - return SUCCESS; - } - - simdjson_inline uint8_t* tape_builder::on_start_string(json_iterator& iter) noexcept { - // we advance the point, accounting for the fact that we have a NULL termination - tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING); - return current_string_buf_loc + sizeof(uint32_t); - } - - simdjson_inline void tape_builder::on_end_string(uint8_t* dst) noexcept { - uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t))); - // TODO check for overflow in case someone has a crazy string (>=4GB?) - // But only add the overflow check when the document itself exceeds 4GB - // Currently unneeded because we refuse to parse docs larger or equal to 4GB. - memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t)); - // NULL termination is still handy if you expect all your strings to - // be NULL terminated? It comes at a small cost - *dst = 0; - current_string_buf_loc = dst + 1; - } - - } // namespace stage2 - } // unnamed namespace - } // namespace westmere -} // namespace simdjson -/* end file src/generic/stage2/tape_builder.h */ // // Implementation-specific overrides @@ -16645,16 +43599,6 @@ namespace simdjson { namespace simdjson { namespace westmere { - namespace { - namespace stage1 { - - simdjson_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) { - if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; } - return find_escaped_branchless(backslash); - } - - } // namespace stage1 - } // unnamed namespace simdjson_warn_unused error_code implementation::minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept { return westmere::stage1::json_minifier::minify<64>(buf, len, dst, dst_len); @@ -16695,11 +43639,27 @@ namespace simdjson { } // namespace westmere } // namespace simdjson -/* begin file include/simdjson/westmere/end.h */ -SIMDJSON_UNTARGET_WESTMERE -/* end file include/simdjson/westmere/end.h */ -/* end file src/westmere/dom_parser_implementation.cpp */ +/* including simdjson/westmere/end.h: #include */ +/* begin file simdjson/westmere/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_UNTARGET_REGION #endif -SIMDJSON_POP_DISABLE_WARNINGS -/* end file src/simdjson.cpp */ +/* undefining SIMDJSON_IMPLEMENTATION from "westmere" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/westmere/end.h */ + +#endif // SIMDJSON_SRC_WESTMERE_CPP +/* end file westmere.cpp */ +#endif + +/* undefining SIMDJSON_CONDITIONAL_INCLUDE */ +#undef SIMDJSON_CONDITIONAL_INCLUDE + +SIMDJSON_POP_DISABLE_UNUSED_WARNINGS + +/* end file simdjson.cpp */ diff --git a/M6502/HarteTest_6502/simdjson/simdjson.h b/M6502/HarteTest_6502/simdjson/simdjson.h index 729c988..cf5dce4 100644 --- a/M6502/HarteTest_6502/simdjson/simdjson.h +++ b/M6502/HarteTest_6502/simdjson/simdjson.h @@ -1,5 +1,6 @@ -/* auto-generated on 2023-03-13 21:26:32 -0400. Do not edit! */ -/* begin file include/simdjson.h */ +/* auto-generated on 2023-12-07 12:42:28 -0500. Do not edit! */ +/* including simdjson.h: */ +/* begin file simdjson.h */ #ifndef SIMDJSON_H #define SIMDJSON_H @@ -36,43 +37,14 @@ } */ - /* begin file include/simdjson/simdjson_version.h */ - // /include/simdjson/simdjson_version.h automatically generated by release.py, - // do not change by hand -#ifndef SIMDJSON_SIMDJSON_VERSION_H -#define SIMDJSON_SIMDJSON_VERSION_H + /* including simdjson/common_defs.h: #include "simdjson/common_defs.h" */ + /* begin file simdjson/common_defs.h */ +#ifndef SIMDJSON_COMMON_DEFS_H +#define SIMDJSON_COMMON_DEFS_H -/** The version of simdjson being used (major.minor.revision) */ -#define SIMDJSON_VERSION "3.1.6" - -namespace simdjson { - enum { - /** - * The major version (MAJOR.minor.revision) of simdjson being used. - */ - SIMDJSON_VERSION_MAJOR = 3, - /** - * The minor version (major.MINOR.revision) of simdjson being used. - */ - SIMDJSON_VERSION_MINOR = 1, - /** - * The revision (major.minor.REVISION) of simdjson being used. - */ - SIMDJSON_VERSION_REVISION = 6 - }; -} // namespace simdjson - -#endif // SIMDJSON_SIMDJSON_VERSION_H -/* end file include/simdjson/simdjson_version.h */ -/* begin file include/simdjson/dom.h */ -#ifndef SIMDJSON_DOM_H -#define SIMDJSON_DOM_H - -/* begin file include/simdjson/base.h */ -#ifndef SIMDJSON_BASE_H -#define SIMDJSON_BASE_H - -/* begin file include/simdjson/compiler_check.h */ +#include +/* including simdjson/compiler_check.h: #include "simdjson/compiler_check.h" */ +/* begin file simdjson/compiler_check.h */ #ifndef SIMDJSON_COMPILER_CHECK_H #define SIMDJSON_COMPILER_CHECK_H @@ -107,14 +79,18 @@ namespace simdjson { #error simdjson requires a compiler compliant with the C++11 standard #endif -#endif // SIMDJSON_COMPILER_CHECK_H -/* end file include/simdjson/compiler_check.h */ -/* begin file include/simdjson/common_defs.h */ -#ifndef SIMDJSON_COMMON_DEFS_H -#define SIMDJSON_COMMON_DEFS_H +#ifndef SIMDJSON_IF_CONSTEXPR +#if SIMDJSON_CPLUSPLUS17 +#define SIMDJSON_IF_CONSTEXPR if constexpr +#else +#define SIMDJSON_IF_CONSTEXPR if +#endif +#endif -#include -/* begin file include/simdjson/portability.h */ +#endif // SIMDJSON_COMPILER_CHECK_H +/* end file simdjson/compiler_check.h */ +/* including simdjson/portability.h: #include "simdjson/portability.h" */ +/* begin file simdjson/portability.h */ #ifndef SIMDJSON_PORTABILITY_H #define SIMDJSON_PORTABILITY_H @@ -149,24 +125,19 @@ namespace simdjson { #endif // __clang__ #endif // _MSC_VER -#if SIMDJSON_REGULAR_VISUAL_STUDIO -// https://en.wikipedia.org/wiki/C_alternative_tokens -// This header should have no effect, except maybe -// under Visual Studio. -#include -#endif - #if defined(__x86_64__) || defined(_M_AMD64) #define SIMDJSON_IS_X86_64 1 #elif defined(__aarch64__) || defined(_M_ARM64) #define SIMDJSON_IS_ARM64 1 +#elif defined(__riscv) && __riscv_xlen == 64 +#define SIMDJSON_IS_RISCV64 1 #elif defined(__PPC64__) || defined(_M_PPC64) -#define SIMDJSON_IS_PPC64 1 +#if defined(__ALTIVEC__) +#define SIMDJSON_IS_PPC64_VMX 1 +#endif // defined(__ALTIVEC__) #else #define SIMDJSON_IS_32BITS 1 -// We do not support 32-bit platforms, but it can be -// handy to identify them. #if defined(_M_IX86) || defined(__i386__) #define SIMDJSON_IS_X86_32BITS 1 #elif defined(__arm__) || defined(_M_ARM) @@ -182,14 +153,17 @@ namespace simdjson { #if SIMDJSON_IS_32BITS #ifndef SIMDJSON_NO_PORTABILITY_WARNING -#pragma message("The simdjson library is designed \ -for 64-bit processors and it seems that you are not \ -compiling for a known 64-bit platform. All fast kernels \ -will be disabled and performance may be poor. Please \ -use a 64-bit target such as x64, 64-bit ARM or 64-bit PPC.") +// In the future, we should allow programmers +// to get warning. #endif // SIMDJSON_NO_PORTABILITY_WARNING #endif // SIMDJSON_IS_32BITS +#define SIMDJSON_CAT_IMPLEMENTATION_(a,...) a ## __VA_ARGS__ +#define SIMDJSON_CAT(a,...) SIMDJSON_CAT_IMPLEMENTATION_(a, __VA_ARGS__) + +#define SIMDJSON_STRINGIFY_IMPLEMENTATION_(a,...) #a SIMDJSON_STRINGIFY(__VA_ARGS__) +#define SIMDJSON_STRINGIFY(a,...) SIMDJSON_CAT_IMPLEMENTATION_(a, __VA_ARGS__) + // this is almost standard? #undef SIMDJSON_STRINGIFY_IMPLEMENTATION_ #undef SIMDJSON_STRINGIFY @@ -292,8 +266,9 @@ use a 64-bit target such as x64, 64-bit ARM or 64-bit PPC.") #define simdjson_strncasecmp strncasecmp #endif -#ifdef NDEBUG - +#if defined(NDEBUG) || defined(__OPTIMIZE__) || (defined(_MSC_VER) && !defined(_DEBUG)) +// If NDEBUG is set, or __OPTIMIZE__ is set, or we are under MSVC in release mode, +// then do away with asserts and use __assume. #if SIMDJSON_VISUAL_STUDIO #define SIMDJSON_UNREACHABLE() __assume(0) #define SIMDJSON_ASSUME(COND) __assume(COND) @@ -302,18 +277,17 @@ use a 64-bit target such as x64, 64-bit ARM or 64-bit PPC.") #define SIMDJSON_ASSUME(COND) do { if (!(COND)) __builtin_unreachable(); } while (0) #endif -#else // NDEBUG - +#else // defined(NDEBUG) || defined(__OPTIMIZE__) || (defined(_MSC_VER) && !defined(_DEBUG)) +// This should only ever be enabled in debug mode. #define SIMDJSON_UNREACHABLE() assert(0); #define SIMDJSON_ASSUME(COND) assert(COND) #endif #endif // SIMDJSON_PORTABILITY_H -/* end file include/simdjson/portability.h */ +/* end file simdjson/portability.h */ namespace simdjson { - namespace internal { /** * @private @@ -328,7 +302,6 @@ namespace simdjson { */ double from_chars(const char* first) noexcept; double from_chars(const char* first, const char* end) noexcept; - } #ifndef SIMDJSON_EXCEPTIONS @@ -339,26 +312,6 @@ namespace simdjson { #endif #endif - /** The maximum document size supported by simdjson. */ - constexpr size_t SIMDJSON_MAXSIZE_BYTES = 0xFFFFFFFF; - - /** - * The amount of padding needed in a buffer to parse JSON. - * - * The input buf should be readable up to buf + SIMDJSON_PADDING - * this is a stopgap; there should be a better description of the - * main loop and its behavior that abstracts over this - * See https://github.com/simdjson/simdjson/issues/174 - */ - constexpr size_t SIMDJSON_PADDING = 64; - - /** - * By default, simdjson supports this many nested objects and arrays. - * - * This is the default for parser::max_depth(). - */ - constexpr size_t DEFAULT_MAX_DEPTH = 1024; - } // namespace simdjson #if defined(__GNUC__) @@ -413,6 +366,9 @@ namespace simdjson { #define SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING #define SIMDJSON_POP_DISABLE_WARNINGS __pragma(warning( pop )) +#define SIMDJSON_PUSH_DISABLE_UNUSED_WARNINGS +#define SIMDJSON_POP_DISABLE_UNUSED_WARNINGS + #else // SIMDJSON_REGULAR_VISUAL_STUDIO #define simdjson_really_inline inline __attribute__((always_inline)) @@ -458,7 +414,8 @@ namespace simdjson { SIMDJSON_DISABLE_GCC_WARNING(-Wshadow) \ SIMDJSON_DISABLE_GCC_WARNING(-Wunused-parameter) \ SIMDJSON_DISABLE_GCC_WARNING(-Wunused-variable) \ - SIMDJSON_DISABLE_GCC_WARNING(-Wmaybe-uninitialized) + SIMDJSON_DISABLE_GCC_WARNING(-Wmaybe-uninitialized) \ + SIMDJSON_DISABLE_GCC_WARNING(-Wformat-security) #endif // __clang__ #define SIMDJSON_PRAGMA(P) _Pragma(#P) @@ -472,6 +429,10 @@ namespace simdjson { #define SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING SIMDJSON_DISABLE_GCC_WARNING(-Wstrict-overflow) #define SIMDJSON_POP_DISABLE_WARNINGS _Pragma("GCC diagnostic pop") +#define SIMDJSON_PUSH_DISABLE_UNUSED_WARNINGS SIMDJSON_PUSH_DISABLE_WARNINGS \ + SIMDJSON_DISABLE_GCC_WARNING(-Wunused) +#define SIMDJSON_POP_DISABLE_UNUSED_WARNINGS SIMDJSON_POP_DISABLE_WARNINGS + #endif // MSC_VER @@ -574,7 +535,8 @@ namespace simdjson { // #ifndef SIMDJSON_HAS_STRING_VIEW SIMDJSON_PUSH_DISABLE_ALL_WARNINGS -/* begin file include/simdjson/nonstd/string_view.hpp */ +/* including simdjson/nonstd/string_view.hpp: #include "simdjson/nonstd/string_view.hpp" */ +/* begin file simdjson/nonstd/string_view.hpp */ // Copyright 2017-2020 by Martin Moene // // string-view lite, a C++17-like string_view for C++98 and later. @@ -589,7 +551,7 @@ SIMDJSON_PUSH_DISABLE_ALL_WARNINGS #define NONSTD_SV_LITE_H_INCLUDED #define string_view_lite_MAJOR 1 -#define string_view_lite_MINOR 6 +#define string_view_lite_MINOR 7 #define string_view_lite_PATCH 0 #define string_view_lite_VERSION nssv_STRINGIFY(string_view_lite_MAJOR) "." nssv_STRINGIFY(string_view_lite_MINOR) "." nssv_STRINGIFY(string_view_lite_PATCH) @@ -649,7 +611,7 @@ SIMDJSON_PUSH_DISABLE_ALL_WARNINGS // Control presence of exception handling (try and auto discover): #ifndef nssv_CONFIG_NO_EXCEPTIONS -# if _MSC_VER +# if defined(_MSC_VER) # include // for _HAS_EXCEPTIONS # endif # if defined(__cpp_exceptions) || defined(__EXCEPTIONS) || (_HAS_EXCEPTIONS) @@ -659,7 +621,7 @@ SIMDJSON_PUSH_DISABLE_ALL_WARNINGS # endif #endif -// C++ language version detection (C++20 is speculative): +// C++ language version detection (C++23 is speculative): // Note: VC14.0/1900 (VS2015) lacks too much from C++14. #ifndef nssv_CPLUSPLUS @@ -675,7 +637,8 @@ SIMDJSON_PUSH_DISABLE_ALL_WARNINGS #define nssv_CPP11_OR_GREATER_ ( nssv_CPLUSPLUS >= 201103L ) #define nssv_CPP14_OR_GREATER ( nssv_CPLUSPLUS >= 201402L ) #define nssv_CPP17_OR_GREATER ( nssv_CPLUSPLUS >= 201703L ) -#define nssv_CPP20_OR_GREATER ( nssv_CPLUSPLUS >= 202000L ) +#define nssv_CPP20_OR_GREATER ( nssv_CPLUSPLUS >= 202002L ) +#define nssv_CPP23_OR_GREATER ( nssv_CPLUSPLUS >= 202300L ) // use C++17 std::string_view if available and requested: @@ -866,6 +829,8 @@ namespace nonstd { #define nssv_HAVE_CONSTEXPR_11 nssv_CPP11_140 #define nssv_HAVE_EXPLICIT_CONVERSION nssv_CPP11_140 #define nssv_HAVE_INLINE_NAMESPACE nssv_CPP11_140 +#define nssv_HAVE_IS_DEFAULT nssv_CPP11_140 +#define nssv_HAVE_IS_DELETE nssv_CPP11_140 #define nssv_HAVE_NOEXCEPT nssv_CPP11_140 #define nssv_HAVE_NULLPTR nssv_CPP11_100 #define nssv_HAVE_REF_QUALIFIER nssv_CPP11_140 @@ -1048,6 +1013,17 @@ nssv_DISABLE_MSVC_WARNINGS(4455 26481 26472) namespace nonstd { namespace sv_lite { + // + // basic_string_view declaration: + // + + template + < + class CharT, + class Traits = std::char_traits + > + class basic_string_view; + namespace detail { // support constexpr comparison in C++14; @@ -1115,14 +1091,33 @@ namespace nonstd { #endif // OPTIMIZE - } // namespace detail +#if nssv_CPP11_OR_GREATER && ! nssv_CPP17_OR_GREATER +#if defined(__OPTIMIZE__) - template - < - class CharT, - class Traits = std::char_traits - > - class basic_string_view; + // gcc, clang provide __OPTIMIZE__ + // Expect tail call optimization to make search() non-recursive: + + template< class CharT, class Traits = std::char_traits > + constexpr const CharT* search(basic_string_view haystack, basic_string_view needle) + { + return haystack.starts_with(needle) ? haystack.begin() : + haystack.empty() ? haystack.end() : search(haystack.substr(1), needle); + } + +#else // OPTIMIZE + + // non-recursive: + + template< class CharT, class Traits = std::char_traits > + constexpr const CharT* search(basic_string_view haystack, basic_string_view needle) + { + return std::search(haystack.begin(), haystack.end(), needle.begin(), needle.end()); + } + +#endif // OPTIMIZE +#endif // nssv_CPP11_OR_GREATER && ! nssv_CPP17_OR_GREATER + + } // namespace detail // // basic_string_view: @@ -1149,7 +1144,7 @@ namespace nonstd { typedef const_pointer iterator; typedef const_pointer const_iterator; typedef std::reverse_iterator< const_iterator > reverse_iterator; - typedef std::reverse_iterator< const_iterator > const_reverse_iterator; + typedef std::reverse_iterator< const_iterator > const_reverse_iterator; typedef std::size_t size_type; typedef std::ptrdiff_t difference_type; @@ -1186,6 +1181,14 @@ namespace nonstd { #endif {} +#if nssv_HAVE_NULLPTR +# if nssv_HAVE_IS_DELETE + nssv_constexpr basic_string_view(std::nullptr_t) nssv_noexcept = delete; +# else + private: nssv_constexpr basic_string_view(std::nullptr_t) nssv_noexcept; public: +# endif +#endif + // Assignment: #if nssv_CPP11_OR_GREATER @@ -1383,25 +1386,30 @@ namespace nonstd { // find(), 4x: - nssv_constexpr14 size_type find(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) + nssv_constexpr size_type find(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) { return assert(v.size() == 0 || v.data() != nssv_nullptr) , pos >= size() - ? npos - : to_pos(std::search(cbegin() + pos, cend(), v.cbegin(), v.cend(), Traits::eq)); + ? npos : to_pos( +#if nssv_CPP11_OR_GREATER && ! nssv_CPP17_OR_GREATER + detail::search(substr(pos), v) +#else + std::search(cbegin() + pos, cend(), v.cbegin(), v.cend(), Traits::eq) +#endif + ); } - nssv_constexpr14 size_type find(CharT c, size_type pos = 0) const nssv_noexcept // (2) + nssv_constexpr size_type find(CharT c, size_type pos = 0) const nssv_noexcept // (2) { return find(basic_string_view(&c, 1), pos); } - nssv_constexpr14 size_type find(CharT const* s, size_type pos, size_type n) const // (3) + nssv_constexpr size_type find(CharT const* s, size_type pos, size_type n) const // (3) { return find(basic_string_view(s, n), pos); } - nssv_constexpr14 size_type find(CharT const* s, size_type pos = 0) const // (4) + nssv_constexpr size_type find(CharT const* s, size_type pos = 0) const // (4) { return find(basic_string_view(s), pos); } @@ -2044,7 +2052,7 @@ namespace nonstd { { typename Stream::sentry sentry(os); - if (!os) + if (!sentry) return os; const std::streamsize length = static_cast(sv.length()); @@ -2303,7 +2311,7 @@ nssv_RESTORE_WARNINGS() #endif // nssv_HAVE_STD_STRING_VIEW #endif // NONSTD_SV_LITE_H_INCLUDED -/* end file include/simdjson/nonstd/string_view.hpp */ +/* end file simdjson/nonstd/string_view.hpp */ SIMDJSON_POP_DISABLE_WARNINGS namespace std { @@ -2359,7 +2367,6 @@ namespace std { # define simdjson_fallthrough do {} while (0) /* fallthrough */ #endif // simdjson_fallthrough - #if SIMDJSON_DEVELOPMENT_CHECKS #define SIMDJSON_DEVELOPMENT_ASSERT(expr) do { assert ((expr)); } while (0) #else @@ -2370,18 +2377,82 @@ namespace std { #define SIMDJSON_UTF8VALIDATION 1 #endif +#ifdef __has_include +// How do we detect that a compiler supports vbmi2? +// For sure if the following header is found, we are ok? +#if __has_include() +#define SIMDJSON_COMPILER_SUPPORTS_VBMI2 1 +#endif +#endif + +#ifdef _MSC_VER +#if _MSC_VER >= 1920 +// Visual Studio 2019 and up support VBMI2 under x64 even if the header +// avx512vbmi2intrin.h is not found. +#define SIMDJSON_COMPILER_SUPPORTS_VBMI2 1 +#endif +#endif + +// By default, we allow AVX512. +#ifndef SIMDJSON_AVX512_ALLOWED +#define SIMDJSON_AVX512_ALLOWED 1 +#endif + #endif // SIMDJSON_COMMON_DEFS_H -/* end file include/simdjson/common_defs.h */ +/* end file simdjson/common_defs.h */ -SIMDJSON_PUSH_DISABLE_WARNINGS -SIMDJSON_DISABLE_UNDESIRED_WARNINGS +// This provides the public API for simdjson. +// DOM and ondemand are amalgamated separately, in simdjson.h +/* including simdjson/simdjson_version.h: #include "simdjson/simdjson_version.h" */ +/* begin file simdjson/simdjson_version.h */ +// /include/simdjson/simdjson_version.h automatically generated by release.py, +// do not change by hand +#ifndef SIMDJSON_SIMDJSON_VERSION_H +#define SIMDJSON_SIMDJSON_VERSION_H -// Public API -/* begin file include/simdjson/error.h */ +/** The version of simdjson being used (major.minor.revision) */ +#define SIMDJSON_VERSION "3.6.3" + +namespace simdjson { + enum { + /** + * The major version (MAJOR.minor.revision) of simdjson being used. + */ + SIMDJSON_VERSION_MAJOR = 3, + /** + * The minor version (major.MINOR.revision) of simdjson being used. + */ + SIMDJSON_VERSION_MINOR = 6, + /** + * The revision (major.minor.REVISION) of simdjson being used. + */ + SIMDJSON_VERSION_REVISION = 3 + }; +} // namespace simdjson + +#endif // SIMDJSON_SIMDJSON_VERSION_H +/* end file simdjson/simdjson_version.h */ + +/* including simdjson/base.h: #include "simdjson/base.h" */ +/* begin file simdjson/base.h */ +/** + * @file Base declarations for all simdjson headers + * @private + */ +#ifndef SIMDJSON_BASE_H +#define SIMDJSON_BASE_H + + /* skipped duplicate #include "simdjson/common_defs.h" */ + /* skipped duplicate #include "simdjson/compiler_check.h" */ + /* including simdjson/error.h: #include "simdjson/error.h" */ + /* begin file simdjson/error.h */ #ifndef SIMDJSON_ERROR_H #define SIMDJSON_ERROR_H +/* skipped duplicate #include "simdjson/base.h" */ + #include +#include namespace simdjson { @@ -2419,7 +2490,7 @@ namespace simdjson { INVALID_URI_FRAGMENT, ///< Invalid URI fragment UNEXPECTED_ERROR, ///< indicative of a bug in simdjson PARSER_IN_USE, ///< parser is already in use. - OUT_OF_ORDER_ITERATION, ///< tried to iterate an array or object out of order + OUT_OF_ORDER_ITERATION, ///< tried to iterate an array or object out of order (checked when SIMDJSON_DEVELOPMENT_CHECKS=1) INSUFFICIENT_PADDING, ///< The JSON doesn't have enough padding for simdjson to safely parse it. INCOMPLETE_ARRAY_OR_OBJECT, ///< The document ends early. SCALAR_DOCUMENT_AS_VALUE, ///< A scalar document is treated as a value. @@ -2429,15 +2500,22 @@ namespace simdjson { }; /** - * Get the error message for the given error code. - * - * dom::parser parser; - * dom::element doc; - * auto error = parser.parse("foo",3).get(doc); - * if (error) { printf("Error: %s\n", error_message(error)); } - * - * @return The error message. + * It is the convention throughout the code that the macro SIMDJSON_DEVELOPMENT_CHECKS determines whether + * we check for OUT_OF_ORDER_ITERATION. The logic behind it is that these errors only occurs when the code + * that was written while breaking some simdjson::ondemand requirement. They should not occur in released + * code after these issues were fixed. */ + + /** + * Get the error message for the given error code. + * + * dom::parser parser; + * dom::element doc; + * auto error = parser.parse("foo",3).get(doc); + * if (error) { printf("Error: %s\n", error_message(error)); } + * + * @return The error message. + */ inline const char* error_message(error_code error) noexcept; /** @@ -2587,11 +2665,11 @@ namespace simdjson { */ simdjson_inline simdjson_result() noexcept; /** - * @private Create a new error result. + * @private Create a new successful result. */ simdjson_inline simdjson_result(T&& value) noexcept; /** - * @private Create a new successful result. + * @private Create a new error result. */ simdjson_inline simdjson_result(error_code error_code) noexcept; /** @@ -2685,290 +2763,293 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_ERROR_H -/* end file include/simdjson/error.h */ -/* begin file include/simdjson/minify.h */ -#ifndef SIMDJSON_MINIFY_H -#define SIMDJSON_MINIFY_H - -/* begin file include/simdjson/padded_string.h */ -#ifndef SIMDJSON_PADDED_STRING_H -#define SIMDJSON_PADDED_STRING_H - -#include -#include -#include -#include +/* end file simdjson/error.h */ +/* skipped duplicate #include "simdjson/portability.h" */ +/** + * @brief The top level simdjson namespace, containing everything the library provides. + */ namespace simdjson { + SIMDJSON_PUSH_DISABLE_UNUSED_WARNINGS + + /** The maximum document size supported by simdjson. */ + constexpr size_t SIMDJSON_MAXSIZE_BYTES = 0xFFFFFFFF; + + /** + * The amount of padding needed in a buffer to parse JSON. + * + * The input buf should be readable up to buf + SIMDJSON_PADDING + * this is a stopgap; there should be a better description of the + * main loop and its behavior that abstracts over this + * See https://github.com/simdjson/simdjson/issues/174 + */ + constexpr size_t SIMDJSON_PADDING = 64; + + /** + * By default, simdjson supports this many nested objects and arrays. + * + * This is the default for parser::max_depth(). + */ + constexpr size_t DEFAULT_MAX_DEPTH = 1024; + + SIMDJSON_POP_DISABLE_UNUSED_WARNINGS + + class implementation; + struct padded_string; class padded_string_view; + enum class stage1_mode; - /** - * String with extra allocation for ease of use with parser::parse() - * - * This is a move-only class, it cannot be copied. - */ - struct padded_string final { - - /** - * Create a new, empty padded string. - */ - explicit inline padded_string() noexcept; - /** - * Create a new padded string buffer. - * - * @param length the size of the string. - */ - explicit inline padded_string(size_t length) noexcept; - /** - * Create a new padded string by copying the given input. - * - * @param data the buffer to copy - * @param length the number of bytes to copy - */ - explicit inline padded_string(const char* data, size_t length) noexcept; - /** - * Create a new padded string by copying the given input. - * - * @param str_ the string to copy - */ - inline padded_string(const std::string& str_) noexcept; - /** - * Create a new padded string by copying the given input. - * - * @param sv_ the string to copy - */ - inline padded_string(std::string_view sv_) noexcept; - /** - * Move one padded string into another. - * - * The original padded string will be reduced to zero capacity. - * - * @param o the string to move. - */ - inline padded_string(padded_string&& o) noexcept; - /** - * Move one padded string into another. - * - * The original padded string will be reduced to zero capacity. - * - * @param o the string to move. - */ - inline padded_string& operator=(padded_string&& o) noexcept; - inline void swap(padded_string& o) noexcept; - ~padded_string() noexcept; - - /** - * The length of the string. - * - * Does not include padding. - */ - size_t size() const noexcept; - - /** - * The length of the string. - * - * Does not include padding. - */ - size_t length() const noexcept; - - /** - * The string data. - **/ - const char* data() const noexcept; - const uint8_t* u8data() const noexcept { return static_cast(static_cast(data_ptr)); } - - /** - * The string data. - **/ - char* data() noexcept; - - /** - * Create a std::string_view with the same content. - */ - operator std::string_view() const; - - /** - * Create a padded_string_view with the same content. - */ - operator padded_string_view() const noexcept; - - /** - * Load this padded string from a file. - * - * @return IO_ERROR on error. Be mindful that on some 32-bit systems, - * the file size might be limited to 2 GB. - * - * @param path the path to the file. - **/ - inline static simdjson_result load(std::string_view path) noexcept; - - private: - padded_string& operator=(const padded_string& o) = delete; - padded_string(const padded_string& o) = delete; - - size_t viable_size{ 0 }; - char* data_ptr{ nullptr }; - - }; // padded_string - - /** - * Send padded_string instance to an output stream. - * - * @param out The output stream. - * @param s The padded_string instance. - * @throw if there is an error with the underlying output stream. simdjson itself will not throw. - */ - inline std::ostream& operator<<(std::ostream& out, const padded_string& s) { return out << s.data(); } - -#if SIMDJSON_EXCEPTIONS - /** - * Send padded_string instance to an output stream. - * - * @param out The output stream. - * @param s The padded_string instance. - * @throw simdjson_error if the result being printed has an error. If there is an error with the - * underlying output stream, that error will be propagated (simdjson_error will not be - * thrown). - */ - inline std::ostream& operator<<(std::ostream& out, simdjson_result& s) noexcept(false) { return out << s.value(); } -#endif - -} // namespace simdjson - -// This is deliberately outside of simdjson so that people get it without having to use the namespace -inline simdjson::padded_string operator "" _padded(const char* str, size_t len) { - return simdjson::padded_string(str, len); -} - -namespace simdjson { namespace internal { - // The allocate_padded_buffer function is a low-level function to allocate memory - // with padding so we can read past the "length" bytes safely. It is used by - // the padded_string class automatically. It returns nullptr in case - // of error: the caller should check for a null pointer. - // The length parameter is the maximum size in bytes of the string. - // The caller is responsible to free the memory (e.g., delete[] (...)). - inline char* allocate_padded_buffer(size_t length) noexcept; + template + class atomic_ptr; + class dom_parser_implementation; + class escape_json_string; + class tape_ref; + struct value128; + enum class tape_type; } // namespace internal } // namespace simdjson -#endif // SIMDJSON_PADDED_STRING_H -/* end file include/simdjson/padded_string.h */ -#include -#include -#include +#endif // SIMDJSON_BASE_H +/* end file simdjson/base.h */ + +/* skipped duplicate #include "simdjson/error.h" */ +/* including simdjson/error-inl.h: #include "simdjson/error-inl.h" */ +/* begin file simdjson/error-inl.h */ +#ifndef SIMDJSON_ERROR_INL_H +#define SIMDJSON_ERROR_INL_H + +/* skipped duplicate #include "simdjson/error.h" */ + +#include namespace simdjson { + namespace internal { + // We store the error code so we can validate the error message is associated with the right code + struct error_code_info { + error_code code; + const char* message; // do not use a fancy std::string where a simple C string will do (no alloc, no destructor) + }; + // These MUST match the codes in error_code. We check this constraint in basictests. + extern SIMDJSON_DLLIMPORTEXPORT const error_code_info error_codes[]; + } // namespace internal + inline const char* error_message(error_code error) noexcept { + // If you're using error_code, we're trusting you got it from the enum. + return internal::error_codes[int(error)].message; + } - /** - * - * Minify the input string assuming that it represents a JSON string, does not parse or validate. - * This function is much faster than parsing a JSON string and then writing a minified version of it. - * However, it does not validate the input. It will merely return an error in simple cases (e.g., if - * there is a string that was never terminated). - * - * - * @param buf the json document to minify. - * @param len the length of the json document. - * @param dst the buffer to write the minified document to. *MUST* be allocated up to len bytes. - * @param dst_len the number of bytes written. Output only. - * @return the error code, or SUCCESS if there was no error. - */ - simdjson_warn_unused error_code minify(const char* buf, size_t len, char* dst, size_t& dst_len) noexcept; + // deprecated function +#ifndef SIMDJSON_DISABLE_DEPRECATED_API + inline const std::string error_message(int error) noexcept { + if (error < 0 || error >= error_code::NUM_ERROR_CODES) { + return internal::error_codes[UNEXPECTED_ERROR].message; + } + return internal::error_codes[error].message; + } +#endif // SIMDJSON_DISABLE_DEPRECATED_API -} // namespace simdjson + inline std::ostream& operator<<(std::ostream& out, error_code error) noexcept { + return out << error_message(error); + } -#endif // SIMDJSON_MINIFY_H -/* end file include/simdjson/minify.h */ -/* begin file include/simdjson/padded_string_view.h */ -#ifndef SIMDJSON_PADDED_STRING_VIEW_H -#define SIMDJSON_PADDED_STRING_VIEW_H + namespace internal { + // + // internal::simdjson_result_base inline implementation + // -#include -#include -#include -#include + template + simdjson_inline void simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } -namespace simdjson { + template + simdjson_warn_unused simdjson_inline error_code simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } - /** - * User-provided string that promises it has extra padded bytes at the end for use with parser::parse(). - */ - class padded_string_view : public std::string_view { - private: - size_t _capacity; - - public: - /** Create an empty padded_string_view. */ - inline padded_string_view() noexcept = default; - - /** - * Promise the given buffer has at least SIMDJSON_PADDING extra bytes allocated to it. - * - * @param s The string. - * @param len The length of the string (not including padding). - * @param capacity The allocated length of the string, including padding. - */ - explicit inline padded_string_view(const char* s, size_t len, size_t capacity) noexcept; - /** overload explicit inline padded_string_view(const char* s, size_t len) noexcept */ - explicit inline padded_string_view(const uint8_t* s, size_t len, size_t capacity) noexcept; - - /** - * Promise the given string has at least SIMDJSON_PADDING extra bytes allocated to it. - * - * The capacity of the string will be used to determine its padding. - * - * @param s The string. - */ - explicit inline padded_string_view(const std::string& s) noexcept; - - /** - * Promise the given string_view has at least SIMDJSON_PADDING extra bytes allocated to it. - * - * @param s The string. - * @param capacity The allocated length of the string, including padding. - */ - explicit inline padded_string_view(std::string_view s, size_t capacity) noexcept; - - /** The number of allocated bytes. */ - inline size_t capacity() const noexcept; - - /** The amount of padding on the string (capacity() - length()) */ - inline size_t padding() const noexcept; - - }; // padded_string_view + template + simdjson_inline error_code simdjson_result_base::error() const noexcept { + return this->second; + } #if SIMDJSON_EXCEPTIONS - /** - * Send padded_string instance to an output stream. - * - * @param out The output stream. - * @param s The padded_string_view. - * @throw simdjson_error if the result being printed has an error. If there is an error with the - * underlying output stream, that error will be propagated (simdjson_error will not be - * thrown). - */ - inline std::ostream& operator<<(std::ostream& out, simdjson_result& s) noexcept(false) { return out << s.value(); } -#endif + + template + simdjson_inline T& simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T&& simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline simdjson_result_base::simdjson_result_base(T&& value, error_code error) noexcept + : std::pair(std::forward(value), error) {} + template + simdjson_inline simdjson_result_base::simdjson_result_base(error_code error) noexcept + : simdjson_result_base(T{}, error) {} + template + simdjson_inline simdjson_result_base::simdjson_result_base(T&& value) noexcept + : simdjson_result_base(std::forward(value), SUCCESS) {} + template + simdjson_inline simdjson_result_base::simdjson_result_base() noexcept + : simdjson_result_base(T{}, UNINITIALIZED) {} + + } // namespace internal + + /// + /// simdjson_result inline implementation + /// + + template + simdjson_inline void simdjson_result::tie(T& value, error_code& error) && noexcept { + std::forward>(*this).tie(value, error); + } + + template + simdjson_warn_unused simdjson_inline error_code simdjson_result::get(T& value) && noexcept { + return std::forward>(*this).get(value); + } + + template + simdjson_inline error_code simdjson_result::error() const noexcept { + return internal::simdjson_result_base::error(); + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& simdjson_result::value() & noexcept(false) { + return internal::simdjson_result_base::value(); + } + + template + simdjson_inline T&& simdjson_result::value() && noexcept(false) { + return std::forward>(*this).value(); + } + + template + simdjson_inline T&& simdjson_result::take_value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline simdjson_result::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& simdjson_result::value_unsafe() const& noexcept { + return internal::simdjson_result_base::value_unsafe(); + } + + template + simdjson_inline T&& simdjson_result::value_unsafe() && noexcept { + return std::forward>(*this).value_unsafe(); + } + + template + simdjson_inline simdjson_result::simdjson_result(T&& value, error_code error) noexcept + : internal::simdjson_result_base(std::forward(value), error) {} + template + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : internal::simdjson_result_base(error) {} + template + simdjson_inline simdjson_result::simdjson_result(T&& value) noexcept + : internal::simdjson_result_base(std::forward(value)) {} + template + simdjson_inline simdjson_result::simdjson_result() noexcept + : internal::simdjson_result_base() {} } // namespace simdjson -#endif // SIMDJSON_PADDED_STRING_VIEW_H -/* end file include/simdjson/padded_string_view.h */ -/* begin file include/simdjson/implementation.h */ +#endif // SIMDJSON_ERROR_INL_H +/* end file simdjson/error-inl.h */ +/* including simdjson/implementation.h: #include "simdjson/implementation.h" */ +/* begin file simdjson/implementation.h */ #ifndef SIMDJSON_IMPLEMENTATION_H #define SIMDJSON_IMPLEMENTATION_H -/* begin file include/simdjson/internal/dom_parser_implementation.h */ +/* including simdjson/internal/atomic_ptr.h: #include "simdjson/internal/atomic_ptr.h" */ +/* begin file simdjson/internal/atomic_ptr.h */ +#ifndef SIMDJSON_INTERNAL_ATOMIC_PTR_H +#define SIMDJSON_INTERNAL_ATOMIC_PTR_H + +/* skipped duplicate #include "simdjson/base.h" */ +#include + +namespace simdjson { + namespace internal { + + template + class atomic_ptr { + public: + atomic_ptr(T* _ptr) : ptr{ _ptr } {} + + operator const T* () const { return ptr.load(); } + const T& operator*() const { return *ptr; } + const T* operator->() const { return ptr.load(); } + + operator T* () { return ptr.load(); } + T& operator*() { return *ptr; } + T* operator->() { return ptr.load(); } + atomic_ptr& operator=(T* _ptr) { ptr = _ptr; return *this; } + + private: + std::atomic ptr; + }; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_ATOMIC_PTR_H +/* end file simdjson/internal/atomic_ptr.h */ +/* including simdjson/internal/dom_parser_implementation.h: #include "simdjson/internal/dom_parser_implementation.h" */ +/* begin file simdjson/internal/dom_parser_implementation.h */ #ifndef SIMDJSON_INTERNAL_DOM_PARSER_IMPLEMENTATION_H #define SIMDJSON_INTERNAL_DOM_PARSER_IMPLEMENTATION_H +/* skipped duplicate #include "simdjson/base.h" */ +/* skipped duplicate #include "simdjson/error.h" */ #include namespace simdjson { @@ -3216,232 +3297,9 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_INTERNAL_DOM_PARSER_IMPLEMENTATION_H -/* end file include/simdjson/internal/dom_parser_implementation.h */ -/* begin file include/simdjson/internal/isadetection.h */ -/* From -https://github.com/endorno/pytorch/blob/master/torch/lib/TH/generic/simd/simd.h -Highly modified. +/* end file simdjson/internal/dom_parser_implementation.h */ -Copyright (c) 2016- Facebook, Inc (Adam Paszke) -Copyright (c) 2014- Facebook, Inc (Soumith Chintala) -Copyright (c) 2011-2014 Idiap Research Institute (Ronan Collobert) -Copyright (c) 2012-2014 Deepmind Technologies (Koray Kavukcuoglu) -Copyright (c) 2011-2012 NEC Laboratories America (Koray Kavukcuoglu) -Copyright (c) 2011-2013 NYU (Clement Farabet) -Copyright (c) 2006-2010 NEC Laboratories America (Ronan Collobert, Leon Bottou, -Iain Melvin, Jason Weston) Copyright (c) 2006 Idiap Research Institute -(Samy Bengio) Copyright (c) 2001-2004 Idiap Research Institute (Ronan Collobert, -Samy Bengio, Johnny Mariethoz) - -All rights reserved. - -Redistribution and use in source and binary forms, with or without -modification, are permitted provided that the following conditions are met: - -1. Redistributions of source code must retain the above copyright - notice, this list of conditions and the following disclaimer. - -2. Redistributions in binary form must reproduce the above copyright - notice, this list of conditions and the following disclaimer in the - documentation and/or other materials provided with the distribution. - -3. Neither the names of Facebook, Deepmind Technologies, NYU, NEC Laboratories -America and IDIAP Research Institute nor the names of its contributors may be - used to endorse or promote products derived from this software without - specific prior written permission. - -THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" -AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE -IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE -ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE -LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR -CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF -SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS -INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN -CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) -ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE -POSSIBILITY OF SUCH DAMAGE. -*/ - -#ifndef SIMDJSON_INTERNAL_ISADETECTION_H -#define SIMDJSON_INTERNAL_ISADETECTION_H - -#include -#include -#if defined(_MSC_VER) -#include -#elif defined(HAVE_GCC_GET_CPUID) && defined(USE_GCC_GET_CPUID) -#include -#endif - -namespace simdjson { - namespace internal { - - - enum instruction_set { - DEFAULT = 0x0, - NEON = 0x1, - AVX2 = 0x4, - SSE42 = 0x8, - PCLMULQDQ = 0x10, - BMI1 = 0x20, - BMI2 = 0x40, - ALTIVEC = 0x80, - AVX512F = 0x100, - AVX512DQ = 0x200, - AVX512IFMA = 0x400, - AVX512PF = 0x800, - AVX512ER = 0x1000, - AVX512CD = 0x2000, - AVX512BW = 0x4000, - AVX512VL = 0x8000, - AVX512VBMI2 = 0x10000 - }; - -#if defined(__PPC64__) - - static inline uint32_t detect_supported_architectures() { - return instruction_set::ALTIVEC; - } - -#elif defined(__aarch64__) || defined(_M_ARM64) - - static inline uint32_t detect_supported_architectures() { - return instruction_set::NEON; - } - -#elif defined(__x86_64__) || defined(_M_AMD64) // x64 - - - namespace { - // Can be found on Intel ISA Reference for CPUID - constexpr uint32_t cpuid_avx2_bit = 1 << 5; ///< @private Bit 5 of EBX for EAX=0x7 - constexpr uint32_t cpuid_bmi1_bit = 1 << 3; ///< @private bit 3 of EBX for EAX=0x7 - constexpr uint32_t cpuid_bmi2_bit = 1 << 8; ///< @private bit 8 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512f_bit = 1 << 16; ///< @private bit 16 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512dq_bit = 1 << 17; ///< @private bit 17 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512ifma_bit = 1 << 21; ///< @private bit 21 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512pf_bit = 1 << 26; ///< @private bit 26 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512er_bit = 1 << 27; ///< @private bit 27 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512cd_bit = 1 << 28; ///< @private bit 28 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512bw_bit = 1 << 30; ///< @private bit 30 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512vl_bit = 1U << 31; ///< @private bit 31 of EBX for EAX=0x7 - constexpr uint32_t cpuid_avx512vbmi2_bit = 1 << 6; ///< @private bit 6 of ECX for EAX=0x7 - constexpr uint32_t cpuid_sse42_bit = 1 << 20; ///< @private bit 20 of ECX for EAX=0x1 - constexpr uint32_t cpuid_pclmulqdq_bit = 1 << 1; ///< @private bit 1 of ECX for EAX=0x1 - } - - - - static inline void cpuid(uint32_t* eax, uint32_t* ebx, uint32_t* ecx, - uint32_t* edx) { -#if defined(_MSC_VER) - int cpu_info[4]; - __cpuid(cpu_info, *eax); - *eax = cpu_info[0]; - *ebx = cpu_info[1]; - *ecx = cpu_info[2]; - *edx = cpu_info[3]; -#elif defined(HAVE_GCC_GET_CPUID) && defined(USE_GCC_GET_CPUID) - uint32_t level = *eax; - __get_cpuid(level, eax, ebx, ecx, edx); -#else - uint32_t a = *eax, b, c = *ecx, d; - asm volatile("cpuid\n\t" : "+a"(a), "=b"(b), "+c"(c), "=d"(d)); - *eax = a; - *ebx = b; - *ecx = c; - *edx = d; -#endif - } - - static inline uint32_t detect_supported_architectures() { - uint32_t eax, ebx, ecx, edx; - uint32_t host_isa = 0x0; - - // ECX for EAX=0x7 - eax = 0x7; - ecx = 0x0; - cpuid(&eax, &ebx, &ecx, &edx); - if (ebx & cpuid_avx2_bit) { - host_isa |= instruction_set::AVX2; - } - if (ebx & cpuid_bmi1_bit) { - host_isa |= instruction_set::BMI1; - } - - if (ebx & cpuid_bmi2_bit) { - host_isa |= instruction_set::BMI2; - } - - if (ebx & cpuid_avx512f_bit) { - host_isa |= instruction_set::AVX512F; - } - - if (ebx & cpuid_avx512dq_bit) { - host_isa |= instruction_set::AVX512DQ; - } - - if (ebx & cpuid_avx512ifma_bit) { - host_isa |= instruction_set::AVX512IFMA; - } - - if (ebx & cpuid_avx512pf_bit) { - host_isa |= instruction_set::AVX512PF; - } - - if (ebx & cpuid_avx512er_bit) { - host_isa |= instruction_set::AVX512ER; - } - - if (ebx & cpuid_avx512cd_bit) { - host_isa |= instruction_set::AVX512CD; - } - - if (ebx & cpuid_avx512bw_bit) { - host_isa |= instruction_set::AVX512BW; - } - - if (ebx & cpuid_avx512vl_bit) { - host_isa |= instruction_set::AVX512VL; - } - - if (ecx & cpuid_avx512vbmi2_bit) { - host_isa |= instruction_set::AVX512VBMI2; - } - - // EBX for EAX=0x1 - eax = 0x1; - cpuid(&eax, &ebx, &ecx, &edx); - - if (ecx & cpuid_sse42_bit) { - host_isa |= instruction_set::SSE42; - } - - if (ecx & cpuid_pclmulqdq_bit) { - host_isa |= instruction_set::PCLMULQDQ; - } - - return host_isa; - } -#else // fallback - - - static inline uint32_t detect_supported_architectures() { - return instruction_set::DEFAULT; - } - - -#endif // end SIMD extension detection code - - } // namespace internal -} // namespace simdjson - -#endif // SIMDJSON_INTERNAL_ISADETECTION_H -/* end file include/simdjson/internal/isadetection.h */ -#include -#include -#include +#include namespace simdjson { @@ -3473,10 +3331,6 @@ namespace simdjson { return validate_utf8(s.data(), s.size()); } - namespace dom { - class document; - } // namespace dom - /** * An implementation of simdjson for a particular CPU architecture. * @@ -3651,24 +3505,6 @@ namespace simdjson { const implementation* detect_best_supported() const noexcept; }; - template - class atomic_ptr { - public: - atomic_ptr(T* _ptr) : ptr{ _ptr } {} - - operator const T* () const { return ptr.load(); } - const T& operator*() const { return *ptr; } - const T* operator->() const { return ptr.load(); } - - operator T* () { return ptr.load(); } - T& operator*() { return *ptr; } - T* operator->() { return ptr.load(); } - atomic_ptr& operator=(T* _ptr) { ptr = _ptr; return *this; } - - private: - std::atomic ptr; - }; - } // namespace internal /** @@ -3686,204 +3522,363 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_IMPLEMENTATION_H -/* end file include/simdjson/implementation.h */ +/* end file simdjson/implementation.h */ +/* including simdjson/minify.h: #include "simdjson/minify.h" */ +/* begin file simdjson/minify.h */ +#ifndef SIMDJSON_MINIFY_H +#define SIMDJSON_MINIFY_H -// Inline functions -/* begin file include/simdjson/error-inl.h */ -#ifndef SIMDJSON_INLINE_ERROR_H -#define SIMDJSON_INLINE_ERROR_H +/* skipped duplicate #include "simdjson/base.h" */ +/* including simdjson/padded_string.h: #include "simdjson/padded_string.h" */ +/* begin file simdjson/padded_string.h */ +#ifndef SIMDJSON_PADDED_STRING_H +#define SIMDJSON_PADDED_STRING_H -#include -#include -#include +/* skipped duplicate #include "simdjson/base.h" */ +/* skipped duplicate #include "simdjson/error.h" */ -namespace simdjson { - namespace internal { - // We store the error code so we can validate the error message is associated with the right code - struct error_code_info { - error_code code; - const char* message; // do not use a fancy std::string where a simple C string will do (no alloc, no destructor) - }; - // These MUST match the codes in error_code. We check this constraint in basictests. - extern SIMDJSON_DLLIMPORTEXPORT const error_code_info error_codes[]; - } // namespace internal +/* skipped duplicate #include "simdjson/error-inl.h" */ - - inline const char* error_message(error_code error) noexcept { - // If you're using error_code, we're trusting you got it from the enum. - return internal::error_codes[int(error)].message; - } - - // deprecated function -#ifndef SIMDJSON_DISABLE_DEPRECATED_API - inline const std::string error_message(int error) noexcept { - if (error < 0 || error >= error_code::NUM_ERROR_CODES) { - return internal::error_codes[UNEXPECTED_ERROR].message; - } - return internal::error_codes[error].message; - } -#endif // SIMDJSON_DISABLE_DEPRECATED_API - - inline std::ostream& operator<<(std::ostream& out, error_code error) noexcept { - return out << error_message(error); - } - - namespace internal { - - // - // internal::simdjson_result_base inline implementation - // - - template - simdjson_inline void simdjson_result_base::tie(T& value, error_code& error) && noexcept { - error = this->second; - if (!error) { - value = std::forward>(*this).first; - } - } - - template - simdjson_warn_unused simdjson_inline error_code simdjson_result_base::get(T& value) && noexcept { - error_code error; - std::forward>(*this).tie(value, error); - return error; - } - - template - simdjson_inline error_code simdjson_result_base::error() const noexcept { - return this->second; - } - -#if SIMDJSON_EXCEPTIONS - - template - simdjson_inline T& simdjson_result_base::value() & noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return this->first; - } - - template - simdjson_inline T&& simdjson_result_base::value() && noexcept(false) { - return std::forward>(*this).take_value(); - } - - template - simdjson_inline T&& simdjson_result_base::take_value() && noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return std::forward(this->first); - } - - template - simdjson_inline simdjson_result_base::operator T && () && noexcept(false) { - return std::forward>(*this).take_value(); - } - -#endif // SIMDJSON_EXCEPTIONS - - template - simdjson_inline const T& simdjson_result_base::value_unsafe() const& noexcept { - return this->first; - } - - template - simdjson_inline T&& simdjson_result_base::value_unsafe() && noexcept { - return std::forward(this->first); - } - - template - simdjson_inline simdjson_result_base::simdjson_result_base(T&& value, error_code error) noexcept - : std::pair(std::forward(value), error) {} - template - simdjson_inline simdjson_result_base::simdjson_result_base(error_code error) noexcept - : simdjson_result_base(T{}, error) {} - template - simdjson_inline simdjson_result_base::simdjson_result_base(T&& value) noexcept - : simdjson_result_base(std::forward(value), SUCCESS) {} - template - simdjson_inline simdjson_result_base::simdjson_result_base() noexcept - : simdjson_result_base(T{}, UNINITIALIZED) {} - - } // namespace internal - - /// - /// simdjson_result inline implementation - /// - - template - simdjson_inline void simdjson_result::tie(T& value, error_code& error) && noexcept { - std::forward>(*this).tie(value, error); - } - - template - simdjson_warn_unused simdjson_inline error_code simdjson_result::get(T& value) && noexcept { - return std::forward>(*this).get(value); - } - - template - simdjson_inline error_code simdjson_result::error() const noexcept { - return internal::simdjson_result_base::error(); - } - -#if SIMDJSON_EXCEPTIONS - - template - simdjson_inline T& simdjson_result::value() & noexcept(false) { - return internal::simdjson_result_base::value(); - } - - template - simdjson_inline T&& simdjson_result::value() && noexcept(false) { - return std::forward>(*this).value(); - } - - template - simdjson_inline T&& simdjson_result::take_value() && noexcept(false) { - return std::forward>(*this).take_value(); - } - - template - simdjson_inline simdjson_result::operator T && () && noexcept(false) { - return std::forward>(*this).take_value(); - } - -#endif // SIMDJSON_EXCEPTIONS - - template - simdjson_inline const T& simdjson_result::value_unsafe() const& noexcept { - return internal::simdjson_result_base::value_unsafe(); - } - - template - simdjson_inline T&& simdjson_result::value_unsafe() && noexcept { - return std::forward>(*this).value_unsafe(); - } - - template - simdjson_inline simdjson_result::simdjson_result(T&& value, error_code error) noexcept - : internal::simdjson_result_base(std::forward(value), error) {} - template - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : internal::simdjson_result_base(error) {} - template - simdjson_inline simdjson_result::simdjson_result(T&& value) noexcept - : internal::simdjson_result_base(std::forward(value)) {} - template - simdjson_inline simdjson_result::simdjson_result() noexcept - : internal::simdjson_result_base() {} - -} // namespace simdjson - -#endif // SIMDJSON_INLINE_ERROR_H -/* end file include/simdjson/error-inl.h */ -/* begin file include/simdjson/padded_string-inl.h */ -#ifndef SIMDJSON_INLINE_PADDED_STRING_H -#define SIMDJSON_INLINE_PADDED_STRING_H - - -#include #include #include #include +#include + +namespace simdjson { + + class padded_string_view; + + /** + * String with extra allocation for ease of use with parser::parse() + * + * This is a move-only class, it cannot be copied. + */ + struct padded_string final { + + /** + * Create a new, empty padded string. + */ + explicit inline padded_string() noexcept; + /** + * Create a new padded string buffer. + * + * @param length the size of the string. + */ + explicit inline padded_string(size_t length) noexcept; + /** + * Create a new padded string by copying the given input. + * + * @param data the buffer to copy + * @param length the number of bytes to copy + */ + explicit inline padded_string(const char* data, size_t length) noexcept; + /** + * Create a new padded string by copying the given input. + * + * @param str_ the string to copy + */ + inline padded_string(const std::string& str_) noexcept; + /** + * Create a new padded string by copying the given input. + * + * @param sv_ the string to copy + */ + inline padded_string(std::string_view sv_) noexcept; + /** + * Move one padded string into another. + * + * The original padded string will be reduced to zero capacity. + * + * @param o the string to move. + */ + inline padded_string(padded_string&& o) noexcept; + /** + * Move one padded string into another. + * + * The original padded string will be reduced to zero capacity. + * + * @param o the string to move. + */ + inline padded_string& operator=(padded_string&& o) noexcept; + inline void swap(padded_string& o) noexcept; + ~padded_string() noexcept; + + /** + * The length of the string. + * + * Does not include padding. + */ + size_t size() const noexcept; + + /** + * The length of the string. + * + * Does not include padding. + */ + size_t length() const noexcept; + + /** + * The string data. + **/ + const char* data() const noexcept; + const uint8_t* u8data() const noexcept { return static_cast(static_cast(data_ptr)); } + + /** + * The string data. + **/ + char* data() noexcept; + + /** + * Create a std::string_view with the same content. + */ + operator std::string_view() const; + + /** + * Create a padded_string_view with the same content. + */ + operator padded_string_view() const noexcept; + + /** + * Load this padded string from a file. + * + * @return IO_ERROR on error. Be mindful that on some 32-bit systems, + * the file size might be limited to 2 GB. + * + * @param path the path to the file. + **/ + inline static simdjson_result load(std::string_view path) noexcept; + + private: + padded_string& operator=(const padded_string& o) = delete; + padded_string(const padded_string& o) = delete; + + size_t viable_size{ 0 }; + char* data_ptr{ nullptr }; + + }; // padded_string + + /** + * Send padded_string instance to an output stream. + * + * @param out The output stream. + * @param s The padded_string instance. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, const padded_string& s) { return out << s.data(); } + +#if SIMDJSON_EXCEPTIONS + /** + * Send padded_string instance to an output stream. + * + * @param out The output stream. + * @param s The padded_string instance. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& s) noexcept(false) { return out << s.value(); } +#endif + +} // namespace simdjson + +// This is deliberately outside of simdjson so that people get it without having to use the namespace +inline simdjson::padded_string operator "" _padded(const char* str, size_t len); + +namespace simdjson { + namespace internal { + + // The allocate_padded_buffer function is a low-level function to allocate memory + // with padding so we can read past the "length" bytes safely. It is used by + // the padded_string class automatically. It returns nullptr in case + // of error: the caller should check for a null pointer. + // The length parameter is the maximum size in bytes of the string. + // The caller is responsible to free the memory (e.g., delete[] (...)). + inline char* allocate_padded_buffer(size_t length) noexcept; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_PADDED_STRING_H +/* end file simdjson/padded_string.h */ +#include +#include +#include + +namespace simdjson { + + /** + * + * Minify the input string assuming that it represents a JSON string, does not parse or validate. + * This function is much faster than parsing a JSON string and then writing a minified version of it. + * However, it does not validate the input. It will merely return an error in simple cases (e.g., if + * there is a string that was never terminated). + * + * + * @param buf the json document to minify. + * @param len the length of the json document. + * @param dst the buffer to write the minified document to. *MUST* be allocated up to len bytes. + * @param dst_len the number of bytes written. Output only. + * @return the error code, or SUCCESS if there was no error. + */ + simdjson_warn_unused error_code minify(const char* buf, size_t len, char* dst, size_t& dst_len) noexcept; + +} // namespace simdjson + +#endif // SIMDJSON_MINIFY_H +/* end file simdjson/minify.h */ +/* skipped duplicate #include "simdjson/padded_string.h" */ +/* including simdjson/padded_string-inl.h: #include "simdjson/padded_string-inl.h" */ +/* begin file simdjson/padded_string-inl.h */ +#ifndef SIMDJSON_PADDED_STRING_INL_H +#define SIMDJSON_PADDED_STRING_INL_H + +/* skipped duplicate #include "simdjson/padded_string.h" */ +/* including simdjson/padded_string_view.h: #include "simdjson/padded_string_view.h" */ +/* begin file simdjson/padded_string_view.h */ +#ifndef SIMDJSON_PADDED_STRING_VIEW_H +#define SIMDJSON_PADDED_STRING_VIEW_H + +/* skipped duplicate #include "simdjson/portability.h" */ +/* skipped duplicate #include "simdjson/base.h" // for SIMDJSON_PADDING */ +/* skipped duplicate #include "simdjson/error.h" */ + +#include +#include +#include +#include + +namespace simdjson { + + /** + * User-provided string that promises it has extra padded bytes at the end for use with parser::parse(). + */ + class padded_string_view : public std::string_view { + private: + size_t _capacity; + + public: + /** Create an empty padded_string_view. */ + inline padded_string_view() noexcept = default; + + /** + * Promise the given buffer has at least SIMDJSON_PADDING extra bytes allocated to it. + * + * @param s The string. + * @param len The length of the string (not including padding). + * @param capacity The allocated length of the string, including padding. + */ + explicit inline padded_string_view(const char* s, size_t len, size_t capacity) noexcept; + /** overload explicit inline padded_string_view(const char* s, size_t len) noexcept */ + explicit inline padded_string_view(const uint8_t* s, size_t len, size_t capacity) noexcept; + + /** + * Promise the given string has at least SIMDJSON_PADDING extra bytes allocated to it. + * + * The capacity of the string will be used to determine its padding. + * + * @param s The string. + */ + explicit inline padded_string_view(const std::string& s) noexcept; + + /** + * Promise the given string_view has at least SIMDJSON_PADDING extra bytes allocated to it. + * + * @param s The string. + * @param capacity The allocated length of the string, including padding. + */ + explicit inline padded_string_view(std::string_view s, size_t capacity) noexcept; + + /** The number of allocated bytes. */ + inline size_t capacity() const noexcept; + + /** + * Remove the UTF-8 Byte Order Mark (BOM) if it exists. + * + * @return whether a BOM was found and removed + */ + inline bool remove_utf8_bom() noexcept; + + /** The amount of padding on the string (capacity() - length()) */ + inline size_t padding() const noexcept; + + }; // padded_string_view + +#if SIMDJSON_EXCEPTIONS + /** + * Send padded_string instance to an output stream. + * + * @param out The output stream. + * @param s The padded_string_view. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& s) noexcept(false); +#endif + +} // namespace simdjson + +#endif // SIMDJSON_PADDED_STRING_VIEW_H +/* end file simdjson/padded_string_view.h */ + +/* skipped duplicate #include "simdjson/error-inl.h" */ +/* including simdjson/padded_string_view-inl.h: #include "simdjson/padded_string_view-inl.h" */ +/* begin file simdjson/padded_string_view-inl.h */ +#ifndef SIMDJSON_PADDED_STRING_VIEW_INL_H +#define SIMDJSON_PADDED_STRING_VIEW_INL_H + +/* skipped duplicate #include "simdjson/padded_string_view.h" */ +/* skipped duplicate #include "simdjson/error-inl.h" */ + +#include /* memcmp */ + +namespace simdjson { + + inline padded_string_view::padded_string_view(const char* s, size_t len, size_t capacity) noexcept + : std::string_view(s, len), _capacity(capacity) + { + } + + inline padded_string_view::padded_string_view(const uint8_t* s, size_t len, size_t capacity) noexcept + : padded_string_view(reinterpret_cast(s), len, capacity) + { + } + + inline padded_string_view::padded_string_view(const std::string& s) noexcept + : std::string_view(s), _capacity(s.capacity()) + { + } + + inline padded_string_view::padded_string_view(std::string_view s, size_t capacity) noexcept + : std::string_view(s), _capacity(capacity) + { + } + + inline size_t padded_string_view::capacity() const noexcept { return _capacity; } + + inline size_t padded_string_view::padding() const noexcept { return capacity() - length(); } + + inline bool padded_string_view::remove_utf8_bom() noexcept { + if (length() < 3) { return false; } + if (std::memcmp(data(), "\xEF\xBB\xBF", 3) == 0) { + remove_prefix(3); + _capacity -= 3; + return true; + } + return false; + } + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson_result& s) noexcept(false) { return out << s.value(); } +#endif + +} // namespace simdjson + + +#endif // SIMDJSON_PADDED_STRING_VIEW_INL_H +/* end file simdjson/padded_string_view-inl.h */ + +#include namespace simdjson { namespace internal { @@ -3911,9 +3906,8 @@ namespace simdjson { if (padded_buffer == nullptr) { return nullptr; } - // We write zeroes in the padded region to avoid having uninitized - // garbage. If nothing else, garbage getting read might trigger a - // warning in a memory checking. + // We write nulls in the padded region to avoid having uninitialized + // content which may trigger warning for some sanitizers std::memset(padded_buffer + length, 0, totalpaddedlength - length); return padded_buffer; } // allocate_padded_buffer() @@ -4047,107 +4041,97 @@ namespace simdjson { } // namespace simdjson -#endif // SIMDJSON_INLINE_PADDED_STRING_H -/* end file include/simdjson/padded_string-inl.h */ -/* begin file include/simdjson/padded_string_view-inl.h */ -#ifndef SIMDJSON_PADDED_STRING_VIEW_INL_H -#define SIMDJSON_PADDED_STRING_VIEW_INL_H +inline simdjson::padded_string operator "" _padded(const char* str, size_t len) { + return simdjson::padded_string(str, len); +} +#endif // SIMDJSON_PADDED_STRING_INL_H +/* end file simdjson/padded_string-inl.h */ +/* skipped duplicate #include "simdjson/padded_string_view.h" */ +/* skipped duplicate #include "simdjson/padded_string_view-inl.h" */ -#include -#include -#include -#include +/* including simdjson/dom.h: #include "simdjson/dom.h" */ +/* begin file simdjson/dom.h */ +#ifndef SIMDJSON_DOM_H +#define SIMDJSON_DOM_H + +/* including simdjson/dom/base.h: #include "simdjson/dom/base.h" */ +/* begin file simdjson/dom/base.h */ +#ifndef SIMDJSON_DOM_BASE_H +#define SIMDJSON_DOM_BASE_H + +/* skipped duplicate #include "simdjson/base.h" */ namespace simdjson { - inline padded_string_view::padded_string_view(const char* s, size_t len, size_t capacity) noexcept - : std::string_view(s, len), _capacity(capacity) - { - } + /** + * @brief A DOM API on top of the simdjson parser. + */ + namespace dom { - inline padded_string_view::padded_string_view(const uint8_t* s, size_t len, size_t capacity) noexcept - : padded_string_view(reinterpret_cast(s), len, capacity) - { - } + /** The default batch size for parser.parse_many() and parser.load_many() */ + static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; + /** + * Some adversary might try to set the batch size to 0 or 1, which might cause problems. + * We set a minimum of 32B since anything else is highly likely to be an error. In practice, + * most users will want a much larger batch size. + * + * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON + * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. + */ + static constexpr size_t MINIMAL_BATCH_SIZE = 32; - inline padded_string_view::padded_string_view(const std::string& s) noexcept - : std::string_view(s), _capacity(s.capacity()) - { - } + /** + * It is wasteful to allocate memory for tiny documents (e.g., 4 bytes). + */ + static constexpr size_t MINIMAL_DOCUMENT_CAPACITY = 32; - inline padded_string_view::padded_string_view(std::string_view s, size_t capacity) noexcept - : std::string_view(s), _capacity(capacity) - { - } + class array; + class document; + class document_stream; + class element; + class key_value_pair; + class object; + class parser; - inline size_t padded_string_view::capacity() const noexcept { return _capacity; } +#ifdef SIMDJSON_THREADS_ENABLED + struct stage1_worker; +#endif // SIMDJSON_THREADS_ENABLED - inline size_t padded_string_view::padding() const noexcept { return capacity() - length(); } + } // namespace dom + + namespace internal { + + template + class string_builder; + class tape_ref; + + } // namespace internal } // namespace simdjson -#endif // SIMDJSON_PADDED_STRING_VIEW_INL_H -/* end file include/simdjson/padded_string_view-inl.h */ - -SIMDJSON_POP_DISABLE_WARNINGS - -#endif // SIMDJSON_BASE_H -/* end file include/simdjson/base.h */ - -SIMDJSON_PUSH_DISABLE_WARNINGS -SIMDJSON_DISABLE_UNDESIRED_WARNINGS - -/* begin file include/simdjson/dom/array.h */ +#endif // SIMDJSON_DOM_BASE_H +/* end file simdjson/dom/base.h */ +/* including simdjson/dom/array.h: #include "simdjson/dom/array.h" */ +/* begin file simdjson/dom/array.h */ #ifndef SIMDJSON_DOM_ARRAY_H #define SIMDJSON_DOM_ARRAY_H -/* begin file include/simdjson/internal/tape_ref.h */ +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* including simdjson/internal/tape_ref.h: #include "simdjson/internal/tape_ref.h" */ +/* begin file simdjson/internal/tape_ref.h */ #ifndef SIMDJSON_INTERNAL_TAPE_REF_H #define SIMDJSON_INTERNAL_TAPE_REF_H -/* begin file include/simdjson/internal/tape_type.h */ -#ifndef SIMDJSON_INTERNAL_TAPE_TYPE_H -#define SIMDJSON_INTERNAL_TAPE_TYPE_H +/* skipped duplicate #include "simdjson/base.h" */ namespace simdjson { - namespace internal { - - /** - * The possible types in the tape. - */ - enum class tape_type { - ROOT = 'r', - START_ARRAY = '[', - START_OBJECT = '{', - END_ARRAY = ']', - END_OBJECT = '}', - STRING = '"', - INT64 = 'l', - UINT64 = 'u', - DOUBLE = 'd', - TRUE_VALUE = 't', - FALSE_VALUE = 'f', - NULL_VALUE = 'n' - }; // enum class tape_type - - } // namespace internal -} // namespace simdjson - -#endif // SIMDJSON_INTERNAL_TAPE_TYPE_H -/* end file include/simdjson/internal/tape_type.h */ - -namespace simdjson { - namespace dom { class document; - } + } // namespace dom namespace internal { - constexpr const uint64_t JSON_VALUE_MASK = 0x00FFFFFFFFFFFFFF; - constexpr const uint32_t JSON_COUNT_MASK = 0xFFFFFF; - /** * A reference to an element on the tape. Internal only. */ @@ -4185,19 +4169,11 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_INTERNAL_TAPE_REF_H -/* end file include/simdjson/internal/tape_ref.h */ +/* end file simdjson/internal/tape_ref.h */ namespace simdjson { - - namespace internal { - template - class string_builder; - } namespace dom { - class document; - class element; - /** * JSON array. */ @@ -4364,27 +4340,31 @@ namespace std { #endif // defined(__cpp_lib_ranges) #endif // SIMDJSON_DOM_ARRAY_H -/* end file include/simdjson/dom/array.h */ -/* begin file include/simdjson/dom/document_stream.h */ +/* end file simdjson/dom/array.h */ +/* including simdjson/dom/document_stream.h: #include "simdjson/dom/document_stream.h" */ +/* begin file simdjson/dom/document_stream.h */ #ifndef SIMDJSON_DOCUMENT_STREAM_H #define SIMDJSON_DOCUMENT_STREAM_H -/* begin file include/simdjson/dom/parser.h */ +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* including simdjson/dom/parser.h: #include "simdjson/dom/parser.h" */ +/* begin file simdjson/dom/parser.h */ #ifndef SIMDJSON_DOM_PARSER_H #define SIMDJSON_DOM_PARSER_H -/* begin file include/simdjson/dom/document.h */ +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* including simdjson/dom/document.h: #include "simdjson/dom/document.h" */ +/* begin file simdjson/dom/document.h */ #ifndef SIMDJSON_DOM_DOCUMENT_H #define SIMDJSON_DOM_DOCUMENT_H +/* skipped duplicate #include "simdjson/dom/base.h" */ + #include -#include namespace simdjson { namespace dom { - class element; - /** * A parsed JSON document. * @@ -4466,35 +4446,12 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_DOM_DOCUMENT_H -/* end file include/simdjson/dom/document.h */ -#include -#include -#include +/* end file simdjson/dom/document.h */ namespace simdjson { namespace dom { - class document_stream; - class element; - - /** The default batch size for parser.parse_many() and parser.load_many() */ - static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; - /** - * Some adversary might try to set the batch size to 0 or 1, which might cause problems. - * We set a minimum of 32B since anything else is highly likely to be an error. In practice, - * most users will want a much larger batch size. - * - * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON - * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. - */ - static constexpr size_t MINIMAL_BATCH_SIZE = 32; - - /** - * It is wasteful to allocate memory for tiny documents (e.g., 4 bytes). - */ - static constexpr size_t MINIMAL_DOCUMENT_CAPACITY = 32; - /** * A persistent document parser. * @@ -4741,6 +4698,8 @@ namespace simdjson { * And, possibly, no document many have been parsed when the `parser.load_many(path)` function * returned. * + * If there is a UTF-8 BOM, the parser skips it. + * * ### Format * * The file must contain a series of one or more JSON documents, concatenated into a single @@ -4833,6 +4792,8 @@ namespace simdjson { * cout << std::string(doc["title"]) << endl; * } * + * If there is a UTF-8 BOM, the parser skips it. + * * ### Format * * The buffer must contain a series of one or more JSON documents, concatenated into a single @@ -5075,7 +5036,8 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_DOM_PARSER_H -/* end file include/simdjson/dom/parser.h */ +/* end file simdjson/dom/parser.h */ + #ifdef SIMDJSON_THREADS_ENABLED #include #include @@ -5085,7 +5047,6 @@ namespace simdjson { namespace simdjson { namespace dom { - #ifdef SIMDJSON_THREADS_ENABLED /** @private Custom worker class **/ struct stage1_worker { @@ -5297,8 +5258,7 @@ namespace simdjson { * Parse the next document found in the buffer previously given to document_stream. * * The content should be a valid JSON document encoded as UTF-8. If there is a - * UTF-8 BOM, the caller is responsible for omitting it, UTF-8 BOM are - * discouraged. + * UTF-8 BOM, the parser skips it. * * You do NOT need to pre-allocate a parser. This function takes care of * pre-allocating a capacity defined by the batch_size defined when creating the @@ -5394,22 +5354,18 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_DOCUMENT_STREAM_H -/* end file include/simdjson/dom/document_stream.h */ -/* begin file include/simdjson/dom/element.h */ +/* end file simdjson/dom/document_stream.h */ +/* skipped duplicate #include "simdjson/dom/document.h" */ +/* including simdjson/dom/element.h: #include "simdjson/dom/element.h" */ +/* begin file simdjson/dom/element.h */ #ifndef SIMDJSON_DOM_ELEMENT_H #define SIMDJSON_DOM_ELEMENT_H -#include +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/array.h" */ namespace simdjson { - namespace internal { - template - class string_builder; - } namespace dom { - class array; - class document; - class object; /** * The actual concrete type of a JSON element @@ -5615,7 +5571,11 @@ namespace simdjson { inline simdjson_result get() const noexcept { // Unless the simdjson library provides an inline implementation, calling this method should // immediately fail. - static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library."); + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are Boolean (bool), numbers (double, uint64_t, int64_t), " + "strings (std::string_view, const char *), arrays (dom::array) and objects (dom::object). " + "We recommand you use get_double(), get_bool(), get_uint64(), get_int64(), " + "get_object(), get_array() or get_string() instead of the get template."); } /** @@ -5855,6 +5815,22 @@ namespace simdjson { */ inline simdjson_result at_key_case_insensitive(std::string_view key) const noexcept; + /** + * operator< defines a total order for element allowing to use them in + * ordered C++ STL containers + * + * @return TRUE if the key appears before the other one in the tape + */ + inline bool operator<(const element& other) const noexcept; + + /** + * operator== allows to verify if two element values reference the + * same JSON item + * + * @return TRUE if the two values references the same JSON element + */ + inline bool operator==(const element& other) const noexcept; + /** @private for debugging. Prints out the root element. */ inline bool dump_raw_tape(std::ostream& out) const noexcept; @@ -5932,27 +5908,22 @@ namespace simdjson { #endif // SIMDJSON_EXCEPTIONS }; - } // namespace simdjson #endif // SIMDJSON_DOM_DOCUMENT_H -/* end file include/simdjson/dom/element.h */ -/* begin file include/simdjson/dom/object.h */ +/* end file simdjson/dom/element.h */ +/* including simdjson/dom/object.h: #include "simdjson/dom/object.h" */ +/* begin file simdjson/dom/object.h */ #ifndef SIMDJSON_DOM_OBJECT_H #define SIMDJSON_DOM_OBJECT_H +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/element.h" */ +/* skipped duplicate #include "simdjson/internal/tape_ref.h" */ namespace simdjson { - namespace internal { - template - class string_builder; - } namespace dom { - class document; - class element; - class key_value_pair; - /** * JSON object. */ @@ -6209,11 +6180,17 @@ namespace std { #endif // defined(__cpp_lib_ranges) #endif // SIMDJSON_DOM_OBJECT_H -/* end file include/simdjson/dom/object.h */ -/* begin file include/simdjson/dom/serialization.h */ +/* end file simdjson/dom/object.h */ +/* skipped duplicate #include "simdjson/dom/parser.h" */ +/* including simdjson/dom/serialization.h: #include "simdjson/dom/serialization.h" */ +/* begin file simdjson/dom/serialization.h */ #ifndef SIMDJSON_SERIALIZATION_H #define SIMDJSON_SERIALIZATION_H +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/element.h" */ +/* skipped duplicate #include "simdjson/dom/object.h" */ + #include namespace simdjson { @@ -6225,7 +6202,90 @@ namespace simdjson { */ namespace internal { - class mini_formatter; + template + class base_formatter { + public: + /** Add a comma **/ + simdjson_inline void comma(); + /** Start an array, prints [ **/ + simdjson_inline void start_array(); + /** End an array, prints ] **/ + simdjson_inline void end_array(); + /** Start an array, prints { **/ + simdjson_inline void start_object(); + /** Start an array, prints } **/ + simdjson_inline void end_object(); + /** Prints a true **/ + simdjson_inline void true_atom(); + /** Prints a false **/ + simdjson_inline void false_atom(); + /** Prints a null **/ + simdjson_inline void null_atom(); + /** Prints a number **/ + simdjson_inline void number(int64_t x); + /** Prints a number **/ + simdjson_inline void number(uint64_t x); + /** Prints a number **/ + simdjson_inline void number(double x); + /** Prints a key (string + colon) **/ + simdjson_inline void key(std::string_view unescaped); + /** Prints a string. The string is escaped as needed. **/ + simdjson_inline void string(std::string_view unescaped); + /** Clears out the content. **/ + simdjson_inline void clear(); + /** + * Get access to the buffer, it is owned by the instance, but + * the user can make a copy. + **/ + simdjson_inline std::string_view str() const; + + /** Prints one character **/ + simdjson_inline void one_char(char c); + + simdjson_inline void call_print_newline() { + this->print_newline(); + } + + simdjson_inline void call_print_indents(size_t depth) { + this->print_indents(depth); + } + + simdjson_inline void call_print_space() { + this->print_space(); + } + + protected: + // implementation details (subject to change) + /** Backing buffer **/ + std::vector buffer{}; // not ideal! + }; + + + /** + * @private This is the class that we expect to use with the string_builder + * template. It tries to produce a compact version of the JSON element + * as quickly as possible. + */ + class mini_formatter : public base_formatter { + public: + simdjson_inline void print_newline(); + + simdjson_inline void print_indents(size_t depth); + + simdjson_inline void print_space(); + }; + + class pretty_formatter : public base_formatter { + public: + simdjson_inline void print_newline(); + + simdjson_inline void print_indents(size_t depth); + + simdjson_inline void print_space(); + + protected: + int indent_step = 4; + }; /** * @private The string_builder template allows us to construct @@ -6261,56 +6321,6 @@ namespace simdjson { formatter format{}; }; - /** - * @private This is the class that we expect to use with the string_builder - * template. It tries to produce a compact version of the JSON element - * as quickly as possible. - */ - class mini_formatter { - public: - mini_formatter() = default; - /** Add a comma **/ - simdjson_inline void comma(); - /** Start an array, prints [ **/ - simdjson_inline void start_array(); - /** End an array, prints ] **/ - simdjson_inline void end_array(); - /** Start an array, prints { **/ - simdjson_inline void start_object(); - /** Start an array, prints } **/ - simdjson_inline void end_object(); - /** Prints a true **/ - simdjson_inline void true_atom(); - /** Prints a false **/ - simdjson_inline void false_atom(); - /** Prints a null **/ - simdjson_inline void null_atom(); - /** Prints a number **/ - simdjson_inline void number(int64_t x); - /** Prints a number **/ - simdjson_inline void number(uint64_t x); - /** Prints a number **/ - simdjson_inline void number(double x); - /** Prints a key (string + colon) **/ - simdjson_inline void key(std::string_view unescaped); - /** Prints a string. The string is escaped as needed. **/ - simdjson_inline void string(std::string_view unescaped); - /** Clears out the content. **/ - simdjson_inline void clear(); - /** - * Get access to the buffer, it is owned by the instance, but - * the user can make a copy. - **/ - simdjson_inline std::string_view str() const; - - private: - // implementation details (subject to change) - /** Prints one character **/ - simdjson_inline void one_char(char c); - /** Backing buffer **/ - std::vector buffer{}; // not ideal! - }; - } // internal namespace dom { @@ -6322,16 +6332,9 @@ namespace simdjson { * @param value The element. * @throw if there is an error with the underlying output stream. simdjson itself will not throw. */ - inline std::ostream& operator<<(std::ostream& out, simdjson::dom::element value) { - simdjson::internal::string_builder<> sb; - sb.append(value); - return (out << sb.str()); - } + inline std::ostream& operator<<(std::ostream& out, simdjson::dom::element value); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { - if (x.error()) { throw simdjson::simdjson_error(x.error()); } - return (out << x.value()); - } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); #endif /** * Print JSON to an output stream. @@ -6340,16 +6343,9 @@ namespace simdjson { * @param value The array. * @throw if there is an error with the underlying output stream. simdjson itself will not throw. */ - inline std::ostream& operator<<(std::ostream& out, simdjson::dom::array value) { - simdjson::internal::string_builder<> sb; - sb.append(value); - return (out << sb.str()); - } + inline std::ostream& operator<<(std::ostream& out, simdjson::dom::array value); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { - if (x.error()) { throw simdjson::simdjson_error(x.error()); } - return (out << x.value()); - } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); #endif /** * Print JSON to an output stream. @@ -6358,16 +6354,9 @@ namespace simdjson { * @param value The object. * @throw if there is an error with the underlying output stream. simdjson itself will not throw. */ - inline std::ostream& operator<<(std::ostream& out, simdjson::dom::object value) { - simdjson::internal::string_builder<> sb; - sb.append(value); - return (out << sb.str()); - } + inline std::ostream& operator<<(std::ostream& out, simdjson::dom::object value); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { - if (x.error()) { throw simdjson::simdjson_error(x.error()); } - return (out << x.value()); - } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); #endif } // namespace dom @@ -6418,581 +6407,208 @@ namespace simdjson { } #endif + /** + * Prettifies a JSON element or document, printing the valid JSON with indentation. + * + * dom::parser parser; + * element doc = parser.parse(" [ 1 , 2 , 3 ] "_padded); + * + * // Prints: + * // { + * // [ + * // 1, + * // 2, + * // 3 + * // ] + * // } + * cout << prettify(doc) << endl; + * + */ + template + std::string prettify(T x) { + simdjson::internal::string_builder sb; + sb.append(x); + std::string_view answer = sb.str(); + return std::string(answer.data(), answer.size()); + } + +#if SIMDJSON_EXCEPTIONS + template + std::string prettify(simdjson_result x) { + if (x.error()) { throw simdjson_error(x.error()); } + return to_string(x.value()); + } +#endif } // namespace simdjson #endif -/* end file include/simdjson/dom/serialization.h */ +/* end file simdjson/dom/serialization.h */ // Deprecated API -/* begin file include/simdjson/dom/jsonparser.h */ +/* including simdjson/dom/jsonparser.h: #include "simdjson/dom/jsonparser.h" */ +/* begin file simdjson/dom/jsonparser.h */ // TODO Remove this -- deprecated API and files #ifndef SIMDJSON_DOM_JSONPARSER_H #define SIMDJSON_DOM_JSONPARSER_H -/* begin file include/simdjson/dom/parsedjson.h */ -// TODO Remove this -- deprecated API and files +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/parser.h" */ +/* skipped duplicate #include "simdjson/dom/element.h" */ -#ifndef SIMDJSON_DOM_PARSEDJSON_H -#define SIMDJSON_DOM_PARSEDJSON_H +/* including simdjson/dom/parser-inl.h: #include "simdjson/dom/parser-inl.h" */ +/* begin file simdjson/dom/parser-inl.h */ +#ifndef SIMDJSON_PARSER_INL_H +#define SIMDJSON_PARSER_INL_H +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/document_stream.h" */ +/* skipped duplicate #include "simdjson/implementation.h" */ +/* skipped duplicate #include "simdjson/internal/dom_parser_implementation.h" */ -namespace simdjson { +/* skipped duplicate #include "simdjson/error-inl.h" */ +/* skipped duplicate #include "simdjson/padded_string-inl.h" */ +/* including simdjson/dom/document_stream-inl.h: #include "simdjson/dom/document_stream-inl.h" */ +/* begin file simdjson/dom/document_stream-inl.h */ +#ifndef SIMDJSON_DOCUMENT_STREAM_INL_H +#define SIMDJSON_DOCUMENT_STREAM_INL_H - /** - * @deprecated Use `dom::parser` instead. - */ - using ParsedJson [[deprecated("Use dom::parser instead")]] = dom::parser; +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/document_stream.h" */ +/* including simdjson/dom/element-inl.h: #include "simdjson/dom/element-inl.h" */ +/* begin file simdjson/dom/element-inl.h */ +#ifndef SIMDJSON_ELEMENT_INL_H +#define SIMDJSON_ELEMENT_INL_H -} // namespace simdjson - -#endif // SIMDJSON_DOM_PARSEDJSON_H -/* end file include/simdjson/dom/parsedjson.h */ -/* begin file include/simdjson/jsonioutil.h */ -#ifndef SIMDJSON_JSONIOUTIL_H -#define SIMDJSON_JSONIOUTIL_H - - -namespace simdjson { - -#if SIMDJSON_EXCEPTIONS -#ifndef SIMDJSON_DISABLE_DEPRECATED_API - [[deprecated("Use padded_string::load() instead")]] - inline padded_string get_corpus(const char* path) { - return padded_string::load(path); - } -#endif // SIMDJSON_DISABLE_DEPRECATED_API -#endif // SIMDJSON_EXCEPTIONS - -} // namespace simdjson - -#endif // SIMDJSON_JSONIOUTIL_H -/* end file include/simdjson/jsonioutil.h */ - -namespace simdjson { - - // - // C API (json_parse and build_parsed_json) declarations - // - -#ifndef SIMDJSON_DISABLE_DEPRECATED_API - [[deprecated("Use parser.parse() instead")]] - inline int json_parse(const uint8_t* buf, size_t len, dom::parser& parser, bool realloc_if_needed = true) noexcept { - error_code code = parser.parse(buf, len, realloc_if_needed).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return code; - } - [[deprecated("Use parser.parse() instead")]] - inline int json_parse(const char* buf, size_t len, dom::parser& parser, bool realloc_if_needed = true) noexcept { - error_code code = parser.parse(buf, len, realloc_if_needed).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return code; - } - [[deprecated("Use parser.parse() instead")]] - inline int json_parse(const std::string& s, dom::parser& parser, bool realloc_if_needed = true) noexcept { - error_code code = parser.parse(s.data(), s.length(), realloc_if_needed).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return code; - } - [[deprecated("Use parser.parse() instead")]] - inline int json_parse(const padded_string& s, dom::parser& parser) noexcept { - error_code code = parser.parse(s).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return code; - } - - [[deprecated("Use parser.parse() instead")]] - simdjson_warn_unused inline dom::parser build_parsed_json(const uint8_t* buf, size_t len, bool realloc_if_needed = true) noexcept { - dom::parser parser; - error_code code = parser.parse(buf, len, realloc_if_needed).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return parser; - } - [[deprecated("Use parser.parse() instead")]] - simdjson_warn_unused inline dom::parser build_parsed_json(const char* buf, size_t len, bool realloc_if_needed = true) noexcept { - dom::parser parser; - error_code code = parser.parse(buf, len, realloc_if_needed).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return parser; - } - [[deprecated("Use parser.parse() instead")]] - simdjson_warn_unused inline dom::parser build_parsed_json(const std::string& s, bool realloc_if_needed = true) noexcept { - dom::parser parser; - error_code code = parser.parse(s.data(), s.length(), realloc_if_needed).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return parser; - } - [[deprecated("Use parser.parse() instead")]] - simdjson_warn_unused inline dom::parser build_parsed_json(const padded_string& s) noexcept { - dom::parser parser; - error_code code = parser.parse(s).error(); - // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid - // bits in the parser instead of heeding the result code. The normal parser unsets those in - // anticipation of making the error code ephemeral. - // Here we put the code back into the parser, until we've removed this method. - parser.valid = code == SUCCESS; - parser.error = code; - return parser; - } -#endif // SIMDJSON_DISABLE_DEPRECATED_API - - /** @private We do not want to allow implicit conversion from C string to std::string. */ - int json_parse(const char* buf, dom::parser& parser) noexcept = delete; - /** @private We do not want to allow implicit conversion from C string to std::string. */ - dom::parser build_parsed_json(const char* buf) noexcept = delete; - -} // namespace simdjson - -#endif // SIMDJSON_DOM_JSONPARSER_H -/* end file include/simdjson/dom/jsonparser.h */ -/* begin file include/simdjson/dom/parsedjson_iterator.h */ -// TODO Remove this -- deprecated API and files - -#ifndef SIMDJSON_DOM_PARSEDJSON_ITERATOR_H -#define SIMDJSON_DOM_PARSEDJSON_ITERATOR_H - -#include -#include -#include -#include -#include -#include - -/* begin file include/simdjson/internal/jsonformatutils.h */ -#ifndef SIMDJSON_INTERNAL_JSONFORMATUTILS_H -#define SIMDJSON_INTERNAL_JSONFORMATUTILS_H - -#include -#include -#include +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/element.h" */ +/* skipped duplicate #include "simdjson/dom/document.h" */ +/* skipped duplicate #include "simdjson/dom/object.h" */ +/* including simdjson/internal/tape_type.h: #include "simdjson/internal/tape_type.h" */ +/* begin file simdjson/internal/tape_type.h */ +#ifndef SIMDJSON_INTERNAL_TAPE_TYPE_H +#define SIMDJSON_INTERNAL_TAPE_TYPE_H namespace simdjson { namespace internal { - class escape_json_string; - - inline std::ostream& operator<<(std::ostream& out, const escape_json_string& str); - - class escape_json_string { - public: - escape_json_string(std::string_view _str) noexcept : str{ _str } {} - operator std::string() const noexcept { std::stringstream s; s << *this; return s.str(); } - private: - std::string_view str; - friend std::ostream& operator<<(std::ostream& out, const escape_json_string& unescaped); - }; - - inline std::ostream& operator<<(std::ostream& out, const escape_json_string& unescaped) { - for (size_t i = 0; i < unescaped.str.length(); i++) { - switch (unescaped.str[i]) { - case '\b': - out << "\\b"; - break; - case '\f': - out << "\\f"; - break; - case '\n': - out << "\\n"; - break; - case '\r': - out << "\\r"; - break; - case '\"': - out << "\\\""; - break; - case '\t': - out << "\\t"; - break; - case '\\': - out << "\\\\"; - break; - default: - if (static_cast(unescaped.str[i]) <= 0x1F) { - // TODO can this be done once at the beginning, or will it mess up << char? - std::ios::fmtflags f(out.flags()); - out << "\\u" << std::hex << std::setw(4) << std::setfill('0') << int(unescaped.str[i]); - out.flags(f); - } - else { - out << unescaped.str[i]; - } - } - } - return out; - } + /** + * The possible types in the tape. + */ + enum class tape_type { + ROOT = 'r', + START_ARRAY = '[', + START_OBJECT = '{', + END_ARRAY = ']', + END_OBJECT = '}', + STRING = '"', + INT64 = 'l', + UINT64 = 'u', + DOUBLE = 'd', + TRUE_VALUE = 't', + FALSE_VALUE = 'f', + NULL_VALUE = 'n' + }; // enum class tape_type } // namespace internal } // namespace simdjson -#endif // SIMDJSON_INTERNAL_JSONFORMATUTILS_H -/* end file include/simdjson/internal/jsonformatutils.h */ +#endif // SIMDJSON_INTERNAL_TAPE_TYPE_H +/* end file simdjson/internal/tape_type.h */ -#ifndef SIMDJSON_DISABLE_DEPRECATED_API +/* including simdjson/dom/object-inl.h: #include "simdjson/dom/object-inl.h" */ +/* begin file simdjson/dom/object-inl.h */ +#ifndef SIMDJSON_OBJECT_INL_H +#define SIMDJSON_OBJECT_INL_H -namespace simdjson { - /** @private **/ - class [[deprecated("Use the new DOM navigation API instead (see doc/basics.md)")]] dom::parser::Iterator { - public: - inline Iterator(const dom::parser& parser) noexcept(false); - inline Iterator(const Iterator& o) noexcept; - inline ~Iterator() noexcept; +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/object.h" */ +/* skipped duplicate #include "simdjson/dom/document.h" */ - inline Iterator& operator=(const Iterator&) = delete; +/* skipped duplicate #include "simdjson/dom/element-inl.h" */ +/* skipped duplicate #include "simdjson/error-inl.h" */ - inline bool is_ok() const; - - // useful for debugging purposes - inline size_t get_tape_location() const; - - // useful for debugging purposes - inline size_t get_tape_length() const; - - // returns the current depth (start at 1 with 0 reserved for the fictitious - // root node) - inline size_t get_depth() const; - - // A scope is a series of nodes at the same depth, typically it is either an - // object ({) or an array ([). The root node has type 'r'. - inline uint8_t get_scope_type() const; - - // move forward in document order - inline bool move_forward(); - - // retrieve the character code of what we're looking at: - // [{"slutfn are the possibilities - inline uint8_t get_type() const { - return current_type; // short functions should be inlined! - } - - // get the int64_t value at this node; valid only if get_type is "l" - inline int64_t get_integer() const { - if (location + 1 >= tape_length) { - return 0; // default value in case of error - } - return static_cast(doc.tape[location + 1]); - } - - // get the value as uint64; valid only if if get_type is "u" - inline uint64_t get_unsigned_integer() const { - if (location + 1 >= tape_length) { - return 0; // default value in case of error - } - return doc.tape[location + 1]; - } - - // get the string value at this node (NULL ended); valid only if get_type is " - // note that tabs, and line endings are escaped in the returned value (see - // print_with_escapes) return value is valid UTF-8, it may contain NULL chars - // within the string: get_string_length determines the true string length. - inline const char* get_string() const { - return reinterpret_cast( - doc.string_buf.get() + (current_val & internal::JSON_VALUE_MASK) + sizeof(uint32_t)); - } - - // return the length of the string in bytes - inline uint32_t get_string_length() const { - uint32_t answer; - std::memcpy(&answer, - reinterpret_cast(doc.string_buf.get() + - (current_val & internal::JSON_VALUE_MASK)), - sizeof(uint32_t)); - return answer; - } - - // get the double value at this node; valid only if - // get_type() is "d" - inline double get_double() const { - if (location + 1 >= tape_length) { - return std::numeric_limits::quiet_NaN(); // default value in - // case of error - } - double answer; - std::memcpy(&answer, &doc.tape[location + 1], sizeof(answer)); - return answer; - } - - inline bool is_object_or_array() const { return is_object() || is_array(); } - - inline bool is_object() const { return get_type() == '{'; } - - inline bool is_array() const { return get_type() == '['; } - - inline bool is_string() const { return get_type() == '"'; } - - // Returns true if the current type of the node is an signed integer. - // You can get its value with `get_integer()`. - inline bool is_integer() const { return get_type() == 'l'; } - - // Returns true if the current type of the node is an unsigned integer. - // You can get its value with `get_unsigned_integer()`. - // - // NOTE: - // Only a large value, which is out of range of a 64-bit signed integer, is - // represented internally as an unsigned node. On the other hand, a typical - // positive integer, such as 1, 42, or 1000000, is as a signed node. - // Be aware this function returns false for a signed node. - inline bool is_unsigned_integer() const { return get_type() == 'u'; } - // Returns true if the current type of the node is a double floating-point number. - inline bool is_double() const { return get_type() == 'd'; } - // Returns true if the current type of the node is a number (integer or floating-point). - inline bool is_number() const { - return is_integer() || is_unsigned_integer() || is_double(); - } - // Returns true if the current type of the node is a bool with true value. - inline bool is_true() const { return get_type() == 't'; } - // Returns true if the current type of the node is a bool with false value. - inline bool is_false() const { return get_type() == 'f'; } - // Returns true if the current type of the node is null. - inline bool is_null() const { return get_type() == 'n'; } - // Returns true if the type byte represents an object of an array - static bool is_object_or_array(uint8_t type) { - return ((type == '[') || (type == '{')); - } - - // when at {, go one level deep, looking for a given key - // if successful, we are left pointing at the value, - // if not, we are still pointing at the object ({) - // (in case of repeated keys, this only finds the first one). - // We seek the key using C's strcmp so if your JSON strings contain - // NULL chars, this would trigger a false positive: if you expect that - // to be the case, take extra precautions. - // Furthermore, we do the comparison character-by-character - // without taking into account Unicode equivalence. - inline bool move_to_key(const char* key); - - // as above, but case insensitive lookup (strcmpi instead of strcmp) - inline bool move_to_key_insensitive(const char* key); - - // when at {, go one level deep, looking for a given key - // if successful, we are left pointing at the value, - // if not, we are still pointing at the object ({) - // (in case of repeated keys, this only finds the first one). - // The string we search for can contain NULL values. - // Furthermore, we do the comparison character-by-character - // without taking into account Unicode equivalence. - inline bool move_to_key(const char* key, uint32_t length); - - // when at a key location within an object, this moves to the accompanying - // value (located next to it). This is equivalent but much faster than - // calling "next()". - inline void move_to_value(); - - // when at [, go one level deep, and advance to the given index. - // if successful, we are left pointing at the value, - // if not, we are still pointing at the array ([) - inline bool move_to_index(uint32_t index); - - // Moves the iterator to the value corresponding to the json pointer. - // Always search from the root of the document. - // if successful, we are left pointing at the value, - // if not, we are still pointing the same value we were pointing before the - // call. The json pointer follows the rfc6901 standard's syntax: - // https://tools.ietf.org/html/rfc6901 However, the standard says "If a - // referenced member name is not unique in an object, the member that is - // referenced is undefined, and evaluation fails". Here we just return the - // first corresponding value. The length parameter is the length of the - // jsonpointer string ('pointer'). - inline bool move_to(const char* pointer, uint32_t length); - - // Moves the iterator to the value corresponding to the json pointer. - // Always search from the root of the document. - // if successful, we are left pointing at the value, - // if not, we are still pointing the same value we were pointing before the - // call. The json pointer implementation follows the rfc6901 standard's - // syntax: https://tools.ietf.org/html/rfc6901 However, the standard says - // "If a referenced member name is not unique in an object, the member that - // is referenced is undefined, and evaluation fails". Here we just return - // the first corresponding value. - inline bool move_to(const std::string& pointer) { - return move_to(pointer.c_str(), uint32_t(pointer.length())); - } - - private: - // Almost the same as move_to(), except it searches from the current - // position. The pointer's syntax is identical, though that case is not - // handled by the rfc6901 standard. The '/' is still required at the - // beginning. However, contrary to move_to(), the URI Fragment Identifier - // Representation is not supported here. Also, in case of failure, we are - // left pointing at the closest value it could reach. For these reasons it - // is private. It exists because it is used by move_to(). - inline bool relative_move_to(const char* pointer, uint32_t length); - - public: - // throughout return true if we can do the navigation, false - // otherwise - - // Within a given scope (series of nodes at the same depth within either an - // array or an object), we move forward. - // Thus, given [true, null, {"a":1}, [1,2]], we would visit true, null, { - // and [. At the object ({) or at the array ([), you can issue a "down" to - // visit their content. valid if we're not at the end of a scope (returns - // true). - inline bool next(); - - // Within a given scope (series of nodes at the same depth within either an - // array or an object), we move backward. - // Thus, given [true, null, {"a":1}, [1,2]], we would visit ], }, null, true - // when starting at the end of the scope. At the object ({) or at the array - // ([), you can issue a "down" to visit their content. - // Performance warning: This function is implemented by starting again - // from the beginning of the scope and scanning forward. You should expect - // it to be relatively slow. - inline bool prev(); - - // Moves back to either the containing array or object (type { or [) from - // within a contained scope. - // Valid unless we are at the first level of the document - inline bool up(); - - // Valid if we're at a [ or { and it starts a non-empty scope; moves us to - // start of that deeper scope if it not empty. Thus, given [true, null, - // {"a":1}, [1,2]], if we are at the { node, we would move to the "a" node. - inline bool down(); - - // move us to the start of our current scope, - // a scope is a series of nodes at the same level - inline void to_start_scope(); - - inline void rewind() { - while (up()) - ; - } - - - - // print the node we are currently pointing at - inline bool print(std::ostream& os, bool escape_strings = true) const; - - private: - const document& doc; - size_t max_depth{}; - size_t depth{}; - size_t location{}; // our current location on a tape - size_t tape_length{}; - uint8_t current_type{}; - uint64_t current_val{}; - typedef struct { - size_t start_of_scope; - uint8_t scope_type; - } scopeindex_t; - - scopeindex_t* depth_index{}; - }; - -} // namespace simdjson -#endif // SIMDJSON_DISABLE_DEPRECATED_API - -#endif // SIMDJSON_DOM_PARSEDJSON_ITERATOR_H -/* end file include/simdjson/dom/parsedjson_iterator.h */ - -// Inline functions -/* begin file include/simdjson/dom/array-inl.h */ -#ifndef SIMDJSON_INLINE_ARRAY_H -#define SIMDJSON_INLINE_ARRAY_H - -// Inline implementations go in here. - -#include +#include namespace simdjson { // - // simdjson_result inline implementation + // simdjson_result inline implementation // - simdjson_inline simdjson_result::simdjson_result() noexcept - : internal::simdjson_result_base() {} - simdjson_inline simdjson_result::simdjson_result(dom::array value) noexcept - : internal::simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : internal::simdjson_result_base(error) {} + simdjson_inline simdjson_result::simdjson_result() noexcept + : internal::simdjson_result_base() {} + simdjson_inline simdjson_result::simdjson_result(dom::object value) noexcept + : internal::simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : internal::simdjson_result_base(error) {} + + inline simdjson_result simdjson_result::operator[](std::string_view key) const noexcept { + if (error()) { return error(); } + return first[key]; + } + inline simdjson_result simdjson_result::operator[](const char* key) const noexcept { + if (error()) { return error(); } + return first[key]; + } + inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) const noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + inline simdjson_result simdjson_result::at_key(std::string_view key) const noexcept { + if (error()) { return error(); } + return first.at_key(key); + } + inline simdjson_result simdjson_result::at_key_case_insensitive(std::string_view key) const noexcept { + if (error()) { return error(); } + return first.at_key_case_insensitive(key); + } #if SIMDJSON_EXCEPTIONS - inline dom::array::iterator simdjson_result::begin() const noexcept(false) { + inline dom::object::iterator simdjson_result::begin() const noexcept(false) { if (error()) { throw simdjson_error(error()); } return first.begin(); } - inline dom::array::iterator simdjson_result::end() const noexcept(false) { + inline dom::object::iterator simdjson_result::end() const noexcept(false) { if (error()) { throw simdjson_error(error()); } return first.end(); } - inline size_t simdjson_result::size() const noexcept(false) { + inline size_t simdjson_result::size() const noexcept(false) { if (error()) { throw simdjson_error(error()); } return first.size(); } #endif // SIMDJSON_EXCEPTIONS - inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) const noexcept { - if (error()) { return error(); } - return first.at_pointer(json_pointer); - } - inline simdjson_result simdjson_result::at(size_t index) const noexcept { - if (error()) { return error(); } - return first.at(index); - } - namespace dom { // - // array inline implementation + // object inline implementation // - simdjson_inline array::array() noexcept : tape{} {} - simdjson_inline array::array(const internal::tape_ref& _tape) noexcept : tape{ _tape } {} - inline array::iterator array::begin() const noexcept { + simdjson_inline object::object() noexcept : tape{} {} + simdjson_inline object::object(const internal::tape_ref& _tape) noexcept : tape{ _tape } { } + inline object::iterator object::begin() const noexcept { SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 return internal::tape_ref(tape.doc, tape.json_index + 1); } - inline array::iterator array::end() const noexcept { + inline object::iterator object::end() const noexcept { SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 return internal::tape_ref(tape.doc, tape.after_element() - 1); } - inline size_t array::size() const noexcept { + inline size_t object::size() const noexcept { SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 return tape.scope_count(); } - inline size_t array::number_of_slots() const noexcept { - SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 - return tape.matching_brace_index() - tape.json_index; + + inline simdjson_result object::operator[](std::string_view key) const noexcept { + return at_key(key); } - inline simdjson_result array::at_pointer(std::string_view json_pointer) const noexcept { + inline simdjson_result object::operator[](const char* key) const noexcept { + return at_key(key); + } + inline simdjson_result object::at_pointer(std::string_view json_pointer) const noexcept { SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 if (json_pointer.empty()) { // an empty string means that we return the current node return element(this->tape); // copy the current node @@ -7001,95 +6617,175 @@ namespace simdjson { return INVALID_JSON_POINTER; } json_pointer = json_pointer.substr(1); - // - means "the append position" or "the element after the end of the array" - // We don't support this, because we're returning a real element, not a position. - if (json_pointer == "-") { return INDEX_OUT_OF_BOUNDS; } + size_t slash = json_pointer.find('/'); + std::string_view key = json_pointer.substr(0, slash); + // Grab the child with the given key + simdjson_result child; - // Read the array index - size_t array_index = 0; - size_t i; - for (i = 0; i < json_pointer.length() && json_pointer[i] != '/'; i++) { - uint8_t digit = uint8_t(json_pointer[i] - '0'); - // Check for non-digit in array index. If it's there, we're trying to get a field in an object - if (digit > 9) { return INCORRECT_TYPE; } - array_index = array_index * 10 + digit; + // If there is an escape character in the key, unescape it and then get the child. + size_t escape = key.find('~'); + if (escape != std::string_view::npos) { + // Unescape the key + std::string unescaped(key); + do { + switch (unescaped[escape + 1]) { + case '0': + unescaped.replace(escape, 2, "~"); + break; + case '1': + unescaped.replace(escape, 2, "/"); + break; + default: + return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); + } + escape = unescaped.find('~', escape + 1); + } while (escape != std::string::npos); + child = at_key(unescaped); + } + else { + child = at_key(key); } - - // 0 followed by other digits is invalid - if (i > 1 && json_pointer[0] == '0') { return INVALID_JSON_POINTER; } // "JSON pointer array index has other characters after 0" - - // Empty string is invalid; so is a "/" with no digits before it - if (i == 0) { return INVALID_JSON_POINTER; } // "Empty string in JSON pointer array index" - - // Get the child - auto child = array(tape).at(array_index); - // If there is an error, it ends here if (child.error()) { - return child; + return child; // we do not continue if there was an error } - // If there is a /, we're not done yet, call recursively. - if (i < json_pointer.length()) { - child = child.at_pointer(json_pointer.substr(i)); + // If there is a /, we have to recurse and look up more of the path + if (slash != std::string_view::npos) { + child = child.at_pointer(json_pointer.substr(slash)); } return child; } - inline simdjson_result array::at(size_t index) const noexcept { - SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 - size_t i = 0; - for (auto element : *this) { - if (i == index) { return element; } - i++; + inline simdjson_result object::at_key(std::string_view key) const noexcept { + iterator end_field = end(); + for (iterator field = begin(); field != end_field; ++field) { + if (field.key_equals(key)) { + return field.value(); + } } - return INDEX_OUT_OF_BOUNDS; + return NO_SUCH_FIELD; + } + // In case you wonder why we need this, please see + // https://github.com/simdjson/simdjson/issues/323 + // People do seek keys in a case-insensitive manner. + inline simdjson_result object::at_key_case_insensitive(std::string_view key) const noexcept { + iterator end_field = end(); + for (iterator field = begin(); field != end_field; ++field) { + if (field.key_equals_case_insensitive(key)) { + return field.value(); + } + } + return NO_SUCH_FIELD; } // - // array::iterator inline implementation + // object::iterator inline implementation // - simdjson_inline array::iterator::iterator(const internal::tape_ref& _tape) noexcept : tape{ _tape } { } - inline element array::iterator::operator*() const noexcept { - return element(tape); + simdjson_inline object::iterator::iterator(const internal::tape_ref& _tape) noexcept : tape{ _tape } { } + inline const key_value_pair object::iterator::operator*() const noexcept { + return key_value_pair(key(), value()); } - inline array::iterator& array::iterator::operator++() noexcept { + inline bool object::iterator::operator!=(const object::iterator& other) const noexcept { + return tape.json_index != other.tape.json_index; + } + inline bool object::iterator::operator==(const object::iterator& other) const noexcept { + return tape.json_index == other.tape.json_index; + } + inline bool object::iterator::operator<(const object::iterator& other) const noexcept { + return tape.json_index < other.tape.json_index; + } + inline bool object::iterator::operator<=(const object::iterator& other) const noexcept { + return tape.json_index <= other.tape.json_index; + } + inline bool object::iterator::operator>=(const object::iterator& other) const noexcept { + return tape.json_index >= other.tape.json_index; + } + inline bool object::iterator::operator>(const object::iterator& other) const noexcept { + return tape.json_index > other.tape.json_index; + } + inline object::iterator& object::iterator::operator++() noexcept { + tape.json_index++; tape.json_index = tape.after_element(); return *this; } - inline array::iterator array::iterator::operator++(int) noexcept { - array::iterator out = *this; - ++* this; + inline object::iterator object::iterator::operator++(int) noexcept { + object::iterator out = *this; + ++*this; return out; } - inline bool array::iterator::operator!=(const array::iterator& other) const noexcept { - return tape.json_index != other.tape.json_index; + inline std::string_view object::iterator::key() const noexcept { + return tape.get_string_view(); } - inline bool array::iterator::operator==(const array::iterator& other) const noexcept { - return tape.json_index == other.tape.json_index; + inline uint32_t object::iterator::key_length() const noexcept { + return tape.get_string_length(); } - inline bool array::iterator::operator<(const array::iterator& other) const noexcept { - return tape.json_index < other.tape.json_index; + inline const char* object::iterator::key_c_str() const noexcept { + return reinterpret_cast(&tape.doc->string_buf[size_t(tape.tape_value()) + sizeof(uint32_t)]); } - inline bool array::iterator::operator<=(const array::iterator& other) const noexcept { - return tape.json_index <= other.tape.json_index; + inline element object::iterator::value() const noexcept { + return element(internal::tape_ref(tape.doc, tape.json_index + 1)); } - inline bool array::iterator::operator>=(const array::iterator& other) const noexcept { - return tape.json_index >= other.tape.json_index; + + /** + * Design notes: + * Instead of constructing a string_view and then comparing it with a + * user-provided strings, it is probably more performant to have dedicated + * functions taking as a parameter the string we want to compare against + * and return true when they are equal. That avoids the creation of a temporary + * std::string_view. Though it is possible for the compiler to avoid entirely + * any overhead due to string_view, relying too much on compiler magic is + * problematic: compiler magic sometimes fail, and then what do you do? + * Also, enticing users to rely on high-performance function is probably better + * on the long run. + */ + + inline bool object::iterator::key_equals(std::string_view o) const noexcept { + // We use the fact that the key length can be computed quickly + // without access to the string buffer. + const uint32_t len = key_length(); + if (o.size() == len) { + // We avoid construction of a temporary string_view instance. + return (memcmp(o.data(), key_c_str(), len) == 0); + } + return false; } - inline bool array::iterator::operator>(const array::iterator& other) const noexcept { - return tape.json_index > other.tape.json_index; + + inline bool object::iterator::key_equals_case_insensitive(std::string_view o) const noexcept { + // We use the fact that the key length can be computed quickly + // without access to the string buffer. + const uint32_t len = key_length(); + if (o.size() == len) { + // See For case-insensitive string comparisons, avoid char-by-char functions + // https://lemire.me/blog/2020/04/30/for-case-insensitive-string-comparisons-avoid-char-by-char-functions/ + // Note that it might be worth rolling our own strncasecmp function, with vectorization. + return (simdjson_strncasecmp(o.data(), key_c_str(), len) == 0); + } + return false; } + // + // key_value_pair inline implementation + // + inline key_value_pair::key_value_pair(std::string_view _key, element _value) noexcept : + key(_key), value(_value) {} } // namespace dom - } // namespace simdjson -/* begin file include/simdjson/dom/element-inl.h */ -#ifndef SIMDJSON_INLINE_ELEMENT_H -#define SIMDJSON_INLINE_ELEMENT_H +#if defined(__cpp_lib_ranges) +static_assert(std::ranges::view); +static_assert(std::ranges::sized_range); +#if SIMDJSON_EXCEPTIONS +static_assert(std::ranges::view>); +static_assert(std::ranges::sized_range>); +#endif // SIMDJSON_EXCEPTIONS +#endif // defined(__cpp_lib_ranges) -#include -#include +#endif // SIMDJSON_OBJECT_INL_H +/* end file simdjson/dom/object-inl.h */ +/* skipped duplicate #include "simdjson/error-inl.h" */ + +#include +#include namespace simdjson { @@ -7490,6 +7186,12 @@ namespace simdjson { inline simdjson_result element::at_key_case_insensitive(std::string_view key) const noexcept { return get().at_key_case_insensitive(key); } + inline bool element::operator<(const element& other) const noexcept { + return tape.json_index < other.tape.json_index; + } + inline bool element::operator==(const element& other) const noexcept { + return tape.json_index == other.tape.json_index; + } inline bool element::dump_raw_tape(std::ostream& out) const noexcept { SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 @@ -7524,31 +7226,17 @@ namespace simdjson { } // namespace simdjson -#endif // SIMDJSON_INLINE_ELEMENT_H -/* end file include/simdjson/dom/element-inl.h */ +#endif // SIMDJSON_ELEMENT_INL_H +/* end file simdjson/dom/element-inl.h */ +/* skipped duplicate #include "simdjson/dom/parser-inl.h" */ +/* skipped duplicate #include "simdjson/error-inl.h" */ +/* skipped duplicate #include "simdjson/internal/dom_parser_implementation.h" */ -#if defined(__cpp_lib_ranges) -static_assert(std::ranges::view); -static_assert(std::ranges::sized_range); -#if SIMDJSON_EXCEPTIONS -static_assert(std::ranges::view>); -static_assert(std::ranges::sized_range>); -#endif // SIMDJSON_EXCEPTIONS -#endif // defined(__cpp_lib_ranges) - -#endif // SIMDJSON_INLINE_ARRAY_H -/* end file include/simdjson/dom/array-inl.h */ -/* begin file include/simdjson/dom/document_stream-inl.h */ -#ifndef SIMDJSON_INLINE_DOCUMENT_STREAM_H -#define SIMDJSON_INLINE_DOCUMENT_STREAM_H - -#include -#include -#include namespace simdjson { namespace dom { #ifdef SIMDJSON_THREADS_ENABLED + inline void stage1_worker::finish() { // After calling "run" someone would call finish() to wait // for the end of the processing. @@ -7880,15 +7568,1004 @@ namespace simdjson { #endif // SIMDJSON_EXCEPTIONS } // namespace simdjson -#endif // SIMDJSON_INLINE_DOCUMENT_STREAM_H -/* end file include/simdjson/dom/document_stream-inl.h */ -/* begin file include/simdjson/dom/document-inl.h */ -#ifndef SIMDJSON_INLINE_DOCUMENT_H -#define SIMDJSON_INLINE_DOCUMENT_H +#endif // SIMDJSON_DOCUMENT_STREAM_INL_H +/* end file simdjson/dom/document_stream-inl.h */ +/* skipped duplicate #include "simdjson/dom/element-inl.h" */ + +#include +#include /* memcmp */ + +namespace simdjson { + namespace dom { + + // + // parser inline implementation + // + simdjson_inline parser::parser(size_t max_capacity) noexcept + : _max_capacity{ max_capacity }, + loaded_bytes(nullptr) { + } + simdjson_inline parser::parser(parser&& other) noexcept = default; + simdjson_inline parser& parser::operator=(parser&& other) noexcept = default; + + inline bool parser::is_valid() const noexcept { return valid; } + inline int parser::get_error_code() const noexcept { return error; } + inline std::string parser::get_error_message() const noexcept { return error_message(error); } + + inline bool parser::dump_raw_tape(std::ostream& os) const noexcept { + return valid ? doc.dump_raw_tape(os) : false; + } + + inline simdjson_result parser::read_file(const std::string& path) noexcept { + // Open the file + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe + std::FILE* fp = std::fopen(path.c_str(), "rb"); + SIMDJSON_POP_DISABLE_WARNINGS + + if (fp == nullptr) { + return IO_ERROR; + } + + // Get the file size + int ret; +#if SIMDJSON_VISUAL_STUDIO && !SIMDJSON_IS_32BITS + ret = _fseeki64(fp, 0, SEEK_END); +#else + ret = std::fseek(fp, 0, SEEK_END); +#endif // _WIN64 + if (ret < 0) { + std::fclose(fp); + return IO_ERROR; + } +#if SIMDJSON_VISUAL_STUDIO && !SIMDJSON_IS_32BITS + __int64 len = _ftelli64(fp); + if (len == -1L) { + std::fclose(fp); + return IO_ERROR; + } +#else + long len = std::ftell(fp); + if ((len < 0) || (len == LONG_MAX)) { + std::fclose(fp); + return IO_ERROR; + } +#endif + + // Make sure we have enough capacity to load the file + if (_loaded_bytes_capacity < size_t(len)) { + loaded_bytes.reset(internal::allocate_padded_buffer(len)); + if (!loaded_bytes) { + std::fclose(fp); + return MEMALLOC; + } + _loaded_bytes_capacity = len; + } + + // Read the string + std::rewind(fp); + size_t bytes_read = std::fread(loaded_bytes.get(), 1, len, fp); + if (std::fclose(fp) != 0 || bytes_read != size_t(len)) { + return IO_ERROR; + } + + return bytes_read; + } + + inline simdjson_result parser::load(const std::string& path) & noexcept { + size_t len; + auto _error = read_file(path).get(len); + if (_error) { return _error; } + return parse(loaded_bytes.get(), len, false); + } + + inline simdjson_result parser::load_many(const std::string& path, size_t batch_size) noexcept { + size_t len; + auto _error = read_file(path).get(len); + if (_error) { return _error; } + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + return document_stream(*this, reinterpret_cast(loaded_bytes.get()), len, batch_size); + } + + inline simdjson_result parser::parse_into_document(document& provided_doc, const uint8_t* buf, size_t len, bool realloc_if_needed) & noexcept { + // Important: we need to ensure that document has enough capacity. + // Important: It is possible that provided_doc is actually the internal 'doc' within the parser!!! + error_code _error = ensure_capacity(provided_doc, len); + if (_error) { return _error; } + if (realloc_if_needed) { + // Make sure we have enough capacity to copy len bytes + if (!loaded_bytes || _loaded_bytes_capacity < len) { + loaded_bytes.reset(internal::allocate_padded_buffer(len)); + if (!loaded_bytes) { + return MEMALLOC; + } + _loaded_bytes_capacity = len; + } + std::memcpy(static_cast(loaded_bytes.get()), buf, len); + buf = reinterpret_cast(loaded_bytes.get()); + } + + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + _error = implementation->parse(buf, len, provided_doc); + + if (_error) { return _error; } + + return provided_doc.root(); + } + + simdjson_inline simdjson_result parser::parse_into_document(document& provided_doc, const char* buf, size_t len, bool realloc_if_needed) & noexcept { + return parse_into_document(provided_doc, reinterpret_cast(buf), len, realloc_if_needed); + } + simdjson_inline simdjson_result parser::parse_into_document(document& provided_doc, const std::string& s) & noexcept { + return parse_into_document(provided_doc, s.data(), s.length(), s.capacity() - s.length() < SIMDJSON_PADDING); + } + simdjson_inline simdjson_result parser::parse_into_document(document& provided_doc, const padded_string& s) & noexcept { + return parse_into_document(provided_doc, s.data(), s.length(), false); + } + + + inline simdjson_result parser::parse(const uint8_t* buf, size_t len, bool realloc_if_needed) & noexcept { + return parse_into_document(doc, buf, len, realloc_if_needed); + } + + simdjson_inline simdjson_result parser::parse(const char* buf, size_t len, bool realloc_if_needed) & noexcept { + return parse(reinterpret_cast(buf), len, realloc_if_needed); + } + simdjson_inline simdjson_result parser::parse(const std::string& s) & noexcept { + return parse(s.data(), s.length(), s.capacity() - s.length() < SIMDJSON_PADDING); + } + simdjson_inline simdjson_result parser::parse(const padded_string& s) & noexcept { + return parse(s.data(), s.length(), false); + } + simdjson_inline simdjson_result parser::parse(const padded_string_view& v) & noexcept { + return parse(v.data(), v.length(), false); + } + + inline simdjson_result parser::parse_many(const uint8_t* buf, size_t len, size_t batch_size) noexcept { + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + return document_stream(*this, buf, len, batch_size); + } + inline simdjson_result parser::parse_many(const char* buf, size_t len, size_t batch_size) noexcept { + return parse_many(reinterpret_cast(buf), len, batch_size); + } + inline simdjson_result parser::parse_many(const std::string& s, size_t batch_size) noexcept { + return parse_many(s.data(), s.length(), batch_size); + } + inline simdjson_result parser::parse_many(const padded_string& s, size_t batch_size) noexcept { + return parse_many(s.data(), s.length(), batch_size); + } + + simdjson_inline size_t parser::capacity() const noexcept { + return implementation ? implementation->capacity() : 0; + } + simdjson_inline size_t parser::max_capacity() const noexcept { + return _max_capacity; + } + simdjson_inline size_t parser::max_depth() const noexcept { + return implementation ? implementation->max_depth() : DEFAULT_MAX_DEPTH; + } + + simdjson_warn_unused + inline error_code parser::allocate(size_t capacity, size_t max_depth) noexcept { + // + // Reallocate implementation if needed + // + error_code err; + if (implementation) { + err = implementation->allocate(capacity, max_depth); + } + else { + err = simdjson::get_active_implementation()->create_dom_parser_implementation(capacity, max_depth, implementation); + } + if (err) { return err; } + return SUCCESS; + } + +#ifndef SIMDJSON_DISABLE_DEPRECATED_API + simdjson_warn_unused + inline bool parser::allocate_capacity(size_t capacity, size_t max_depth) noexcept { + return !allocate(capacity, max_depth); + } +#endif // SIMDJSON_DISABLE_DEPRECATED_API + + inline error_code parser::ensure_capacity(size_t desired_capacity) noexcept { + return ensure_capacity(doc, desired_capacity); + } + + + inline error_code parser::ensure_capacity(document& target_document, size_t desired_capacity) noexcept { + // 1. It is wasteful to allocate a document and a parser for documents spanning less than MINIMAL_DOCUMENT_CAPACITY bytes. + // 2. If we allow desired_capacity = 0 then it is possible to exit this function with implementation == nullptr. + if (desired_capacity < MINIMAL_DOCUMENT_CAPACITY) { desired_capacity = MINIMAL_DOCUMENT_CAPACITY; } + // If we don't have enough capacity, (try to) automatically bump it. + // If the document needs allocation, do it too. + // Both in one if statement to minimize unlikely branching. + // + // Note: we must make sure that this function is called if capacity() == 0. We do so because we + // ensure that desired_capacity > 0. + if (simdjson_unlikely(capacity() < desired_capacity || target_document.capacity() < desired_capacity)) { + if (desired_capacity > max_capacity()) { + return error = CAPACITY; + } + error_code err1 = target_document.capacity() < desired_capacity ? target_document.allocate(desired_capacity) : SUCCESS; + error_code err2 = capacity() < desired_capacity ? allocate(desired_capacity, max_depth()) : SUCCESS; + if (err1 != SUCCESS) { return error = err1; } + if (err2 != SUCCESS) { return error = err2; } + } + return SUCCESS; + } + + simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { + if (max_capacity > MINIMAL_DOCUMENT_CAPACITY) { + _max_capacity = max_capacity; + } + else { + _max_capacity = MINIMAL_DOCUMENT_CAPACITY; + } + } + + } // namespace dom +} // namespace simdjson + +#endif // SIMDJSON_PARSER_INL_H +/* end file simdjson/dom/parser-inl.h */ + +namespace simdjson { + + // + // C API (json_parse and build_parsed_json) declarations + // + +#ifndef SIMDJSON_DISABLE_DEPRECATED_API + [[deprecated("Use parser.parse() instead")]] + inline int json_parse(const uint8_t* buf, size_t len, dom::parser& parser, bool realloc_if_needed = true) noexcept { + error_code code = parser.parse(buf, len, realloc_if_needed).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return code; + } + [[deprecated("Use parser.parse() instead")]] + inline int json_parse(const char* buf, size_t len, dom::parser& parser, bool realloc_if_needed = true) noexcept { + error_code code = parser.parse(buf, len, realloc_if_needed).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return code; + } + [[deprecated("Use parser.parse() instead")]] + inline int json_parse(const std::string& s, dom::parser& parser, bool realloc_if_needed = true) noexcept { + error_code code = parser.parse(s.data(), s.length(), realloc_if_needed).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return code; + } + [[deprecated("Use parser.parse() instead")]] + inline int json_parse(const padded_string& s, dom::parser& parser) noexcept { + error_code code = parser.parse(s).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return code; + } + + [[deprecated("Use parser.parse() instead")]] + simdjson_warn_unused inline dom::parser build_parsed_json(const uint8_t* buf, size_t len, bool realloc_if_needed = true) noexcept { + dom::parser parser; + error_code code = parser.parse(buf, len, realloc_if_needed).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return parser; + } + [[deprecated("Use parser.parse() instead")]] + simdjson_warn_unused inline dom::parser build_parsed_json(const char* buf, size_t len, bool realloc_if_needed = true) noexcept { + dom::parser parser; + error_code code = parser.parse(buf, len, realloc_if_needed).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return parser; + } + [[deprecated("Use parser.parse() instead")]] + simdjson_warn_unused inline dom::parser build_parsed_json(const std::string& s, bool realloc_if_needed = true) noexcept { + dom::parser parser; + error_code code = parser.parse(s.data(), s.length(), realloc_if_needed).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return parser; + } + [[deprecated("Use parser.parse() instead")]] + simdjson_warn_unused inline dom::parser build_parsed_json(const padded_string& s) noexcept { + dom::parser parser; + error_code code = parser.parse(s).error(); + // The deprecated json_parse API is a signal that the user plans to *use* the error code / valid + // bits in the parser instead of heeding the result code. The normal parser unsets those in + // anticipation of making the error code ephemeral. + // Here we put the code back into the parser, until we've removed this method. + parser.valid = code == SUCCESS; + parser.error = code; + return parser; + } +#endif // SIMDJSON_DISABLE_DEPRECATED_API + + /** @private We do not want to allow implicit conversion from C string to std::string. */ + int json_parse(const char* buf, dom::parser& parser) noexcept = delete; + /** @private We do not want to allow implicit conversion from C string to std::string. */ + dom::parser build_parsed_json(const char* buf) noexcept = delete; + +} // namespace simdjson + +#endif // SIMDJSON_DOM_JSONPARSER_H +/* end file simdjson/dom/jsonparser.h */ +/* including simdjson/dom/parsedjson.h: #include "simdjson/dom/parsedjson.h" */ +/* begin file simdjson/dom/parsedjson.h */ +// TODO Remove this -- deprecated API and files + +#ifndef SIMDJSON_DOM_PARSEDJSON_H +#define SIMDJSON_DOM_PARSEDJSON_H + +/* skipped duplicate #include "simdjson/dom/base.h" */ + +namespace simdjson { + + /** + * @deprecated Use `dom::parser` instead. + */ + using ParsedJson [[deprecated("Use dom::parser instead")]] = dom::parser; + +} // namespace simdjson + +#endif // SIMDJSON_DOM_PARSEDJSON_H +/* end file simdjson/dom/parsedjson.h */ +/* including simdjson/dom/parsedjson_iterator.h: #include "simdjson/dom/parsedjson_iterator.h" */ +/* begin file simdjson/dom/parsedjson_iterator.h */ +// TODO Remove this -- deprecated API and files + +#ifndef SIMDJSON_DOM_PARSEDJSON_ITERATOR_H +#define SIMDJSON_DOM_PARSEDJSON_ITERATOR_H + +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/parser.h" */ + +#ifndef SIMDJSON_DISABLE_DEPRECATED_API + +namespace simdjson { + /** @private **/ + class [[deprecated("Use the new DOM navigation API instead (see doc/basics.md)")]] dom::parser::Iterator { + public: + inline Iterator(const dom::parser& parser) noexcept(false); + inline Iterator(const Iterator& o) noexcept; + inline ~Iterator() noexcept; + + inline Iterator& operator=(const Iterator&) = delete; + + inline bool is_ok() const; + + // useful for debugging purposes + inline size_t get_tape_location() const; + + // useful for debugging purposes + inline size_t get_tape_length() const; + + // returns the current depth (start at 1 with 0 reserved for the fictitious + // root node) + inline size_t get_depth() const; + + // A scope is a series of nodes at the same depth, typically it is either an + // object ({) or an array ([). The root node has type 'r'. + inline uint8_t get_scope_type() const; + + // move forward in document order + inline bool move_forward(); + + // retrieve the character code of what we're looking at: + // [{"slutfn are the possibilities + inline uint8_t get_type() const { + return current_type; // short functions should be inlined! + } + + // get the int64_t value at this node; valid only if get_type is "l" + inline int64_t get_integer() const; + + // get the value as uint64; valid only if if get_type is "u" + inline uint64_t get_unsigned_integer() const; + + // get the string value at this node (NULL ended); valid only if get_type is " + // note that tabs, and line endings are escaped in the returned value (see + // print_with_escapes) return value is valid UTF-8, it may contain NULL chars + // within the string: get_string_length determines the true string length. + inline const char* get_string() const; + + // return the length of the string in bytes + inline uint32_t get_string_length() const; + + // get the double value at this node; valid only if + // get_type() is "d" + inline double get_double() const; + + inline bool is_object_or_array() const { return is_object() || is_array(); } + + inline bool is_object() const { return get_type() == '{'; } + + inline bool is_array() const { return get_type() == '['; } + + inline bool is_string() const { return get_type() == '"'; } + + // Returns true if the current type of the node is an signed integer. + // You can get its value with `get_integer()`. + inline bool is_integer() const { return get_type() == 'l'; } + + // Returns true if the current type of the node is an unsigned integer. + // You can get its value with `get_unsigned_integer()`. + // + // NOTE: + // Only a large value, which is out of range of a 64-bit signed integer, is + // represented internally as an unsigned node. On the other hand, a typical + // positive integer, such as 1, 42, or 1000000, is as a signed node. + // Be aware this function returns false for a signed node. + inline bool is_unsigned_integer() const { return get_type() == 'u'; } + // Returns true if the current type of the node is a double floating-point number. + inline bool is_double() const { return get_type() == 'd'; } + // Returns true if the current type of the node is a number (integer or floating-point). + inline bool is_number() const { + return is_integer() || is_unsigned_integer() || is_double(); + } + // Returns true if the current type of the node is a bool with true value. + inline bool is_true() const { return get_type() == 't'; } + // Returns true if the current type of the node is a bool with false value. + inline bool is_false() const { return get_type() == 'f'; } + // Returns true if the current type of the node is null. + inline bool is_null() const { return get_type() == 'n'; } + // Returns true if the type byte represents an object of an array + static bool is_object_or_array(uint8_t type) { + return ((type == '[') || (type == '{')); + } + + // when at {, go one level deep, looking for a given key + // if successful, we are left pointing at the value, + // if not, we are still pointing at the object ({) + // (in case of repeated keys, this only finds the first one). + // We seek the key using C's strcmp so if your JSON strings contain + // NULL chars, this would trigger a false positive: if you expect that + // to be the case, take extra precautions. + // Furthermore, we do the comparison character-by-character + // without taking into account Unicode equivalence. + inline bool move_to_key(const char* key); + + // as above, but case insensitive lookup (strcmpi instead of strcmp) + inline bool move_to_key_insensitive(const char* key); + + // when at {, go one level deep, looking for a given key + // if successful, we are left pointing at the value, + // if not, we are still pointing at the object ({) + // (in case of repeated keys, this only finds the first one). + // The string we search for can contain NULL values. + // Furthermore, we do the comparison character-by-character + // without taking into account Unicode equivalence. + inline bool move_to_key(const char* key, uint32_t length); + + // when at a key location within an object, this moves to the accompanying + // value (located next to it). This is equivalent but much faster than + // calling "next()". + inline void move_to_value(); + + // when at [, go one level deep, and advance to the given index. + // if successful, we are left pointing at the value, + // if not, we are still pointing at the array ([) + inline bool move_to_index(uint32_t index); + + // Moves the iterator to the value corresponding to the json pointer. + // Always search from the root of the document. + // if successful, we are left pointing at the value, + // if not, we are still pointing the same value we were pointing before the + // call. The json pointer follows the rfc6901 standard's syntax: + // https://tools.ietf.org/html/rfc6901 However, the standard says "If a + // referenced member name is not unique in an object, the member that is + // referenced is undefined, and evaluation fails". Here we just return the + // first corresponding value. The length parameter is the length of the + // jsonpointer string ('pointer'). + inline bool move_to(const char* pointer, uint32_t length); + + // Moves the iterator to the value corresponding to the json pointer. + // Always search from the root of the document. + // if successful, we are left pointing at the value, + // if not, we are still pointing the same value we were pointing before the + // call. The json pointer implementation follows the rfc6901 standard's + // syntax: https://tools.ietf.org/html/rfc6901 However, the standard says + // "If a referenced member name is not unique in an object, the member that + // is referenced is undefined, and evaluation fails". Here we just return + // the first corresponding value. + inline bool move_to(const std::string& pointer); + + private: + // Almost the same as move_to(), except it searches from the current + // position. The pointer's syntax is identical, though that case is not + // handled by the rfc6901 standard. The '/' is still required at the + // beginning. However, contrary to move_to(), the URI Fragment Identifier + // Representation is not supported here. Also, in case of failure, we are + // left pointing at the closest value it could reach. For these reasons it + // is private. It exists because it is used by move_to(). + inline bool relative_move_to(const char* pointer, uint32_t length); + + public: + // throughout return true if we can do the navigation, false + // otherwise + + // Within a given scope (series of nodes at the same depth within either an + // array or an object), we move forward. + // Thus, given [true, null, {"a":1}, [1,2]], we would visit true, null, { + // and [. At the object ({) or at the array ([), you can issue a "down" to + // visit their content. valid if we're not at the end of a scope (returns + // true). + inline bool next(); + + // Within a given scope (series of nodes at the same depth within either an + // array or an object), we move backward. + // Thus, given [true, null, {"a":1}, [1,2]], we would visit ], }, null, true + // when starting at the end of the scope. At the object ({) or at the array + // ([), you can issue a "down" to visit their content. + // Performance warning: This function is implemented by starting again + // from the beginning of the scope and scanning forward. You should expect + // it to be relatively slow. + inline bool prev(); + + // Moves back to either the containing array or object (type { or [) from + // within a contained scope. + // Valid unless we are at the first level of the document + inline bool up(); + + // Valid if we're at a [ or { and it starts a non-empty scope; moves us to + // start of that deeper scope if it not empty. Thus, given [true, null, + // {"a":1}, [1,2]], if we are at the { node, we would move to the "a" node. + inline bool down(); + + // move us to the start of our current scope, + // a scope is a series of nodes at the same level + inline void to_start_scope(); + + inline void rewind(); + + + + // print the node we are currently pointing at + inline bool print(std::ostream& os, bool escape_strings = true) const; + + private: + const document& doc; + size_t max_depth{}; + size_t depth{}; + size_t location{}; // our current location on a tape + size_t tape_length{}; + uint8_t current_type{}; + uint64_t current_val{}; + typedef struct { + size_t start_of_scope; + uint8_t scope_type; + } scopeindex_t; + + scopeindex_t* depth_index{}; + }; + +} // namespace simdjson +#endif // SIMDJSON_DISABLE_DEPRECATED_API + +#endif // SIMDJSON_DOM_PARSEDJSON_ITERATOR_H +/* end file simdjson/dom/parsedjson_iterator.h */ + +// Inline functions +/* including simdjson/dom/array-inl.h: #include "simdjson/dom/array-inl.h" */ +/* begin file simdjson/dom/array-inl.h */ +#ifndef SIMDJSON_ARRAY_INL_H +#define SIMDJSON_ARRAY_INL_H + +#include + +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/array.h" */ +/* skipped duplicate #include "simdjson/dom/element.h" */ +/* skipped duplicate #include "simdjson/error-inl.h" */ +/* including simdjson/internal/tape_ref-inl.h: #include "simdjson/internal/tape_ref-inl.h" */ +/* begin file simdjson/internal/tape_ref-inl.h */ +#ifndef SIMDJSON_TAPE_REF_INL_H +#define SIMDJSON_TAPE_REF_INL_H + +/* skipped duplicate #include "simdjson/dom/document.h" */ +/* skipped duplicate #include "simdjson/internal/tape_ref.h" */ +/* skipped duplicate #include "simdjson/internal/tape_type.h" */ + +#include + +namespace simdjson { + namespace internal { + + constexpr const uint64_t JSON_VALUE_MASK = 0x00FFFFFFFFFFFFFF; + constexpr const uint32_t JSON_COUNT_MASK = 0xFFFFFF; + + // + // tape_ref inline implementation + // + simdjson_inline tape_ref::tape_ref() noexcept : doc{ nullptr }, json_index{ 0 } {} + simdjson_inline tape_ref::tape_ref(const dom::document* _doc, size_t _json_index) noexcept : doc{ _doc }, json_index{ _json_index } {} + + + simdjson_inline bool tape_ref::is_document_root() const noexcept { + return json_index == 1; // should we ever change the structure of the tape, this should get updated. + } + simdjson_inline bool tape_ref::usable() const noexcept { + return doc != nullptr; // when the document pointer is null, this tape_ref is uninitialized (should not be accessed). + } + // Some value types have a specific on-tape word value. It can be faster + // to check the type by doing a word-to-word comparison instead of extracting the + // most significant 8 bits. + + simdjson_inline bool tape_ref::is_double() const noexcept { + constexpr uint64_t tape_double = uint64_t(tape_type::DOUBLE) << 56; + return doc->tape[json_index] == tape_double; + } + simdjson_inline bool tape_ref::is_int64() const noexcept { + constexpr uint64_t tape_int64 = uint64_t(tape_type::INT64) << 56; + return doc->tape[json_index] == tape_int64; + } + simdjson_inline bool tape_ref::is_uint64() const noexcept { + constexpr uint64_t tape_uint64 = uint64_t(tape_type::UINT64) << 56; + return doc->tape[json_index] == tape_uint64; + } + simdjson_inline bool tape_ref::is_false() const noexcept { + constexpr uint64_t tape_false = uint64_t(tape_type::FALSE_VALUE) << 56; + return doc->tape[json_index] == tape_false; + } + simdjson_inline bool tape_ref::is_true() const noexcept { + constexpr uint64_t tape_true = uint64_t(tape_type::TRUE_VALUE) << 56; + return doc->tape[json_index] == tape_true; + } + simdjson_inline bool tape_ref::is_null_on_tape() const noexcept { + constexpr uint64_t tape_null = uint64_t(tape_type::NULL_VALUE) << 56; + return doc->tape[json_index] == tape_null; + } + + inline size_t tape_ref::after_element() const noexcept { + switch (tape_ref_type()) { + case tape_type::START_ARRAY: + case tape_type::START_OBJECT: + return matching_brace_index(); + case tape_type::UINT64: + case tape_type::INT64: + case tape_type::DOUBLE: + return json_index + 2; + default: + return json_index + 1; + } + } + simdjson_inline tape_type tape_ref::tape_ref_type() const noexcept { + return static_cast(doc->tape[json_index] >> 56); + } + simdjson_inline uint64_t internal::tape_ref::tape_value() const noexcept { + return doc->tape[json_index] & internal::JSON_VALUE_MASK; + } + simdjson_inline uint32_t internal::tape_ref::matching_brace_index() const noexcept { + return uint32_t(doc->tape[json_index]); + } + simdjson_inline uint32_t internal::tape_ref::scope_count() const noexcept { + return uint32_t((doc->tape[json_index] >> 32) & internal::JSON_COUNT_MASK); + } + + template + simdjson_inline T tape_ref::next_tape_value() const noexcept { + static_assert(sizeof(T) == sizeof(uint64_t), "next_tape_value() template parameter must be 64-bit"); + // Though the following is tempting... + // return *reinterpret_cast(&doc->tape[json_index + 1]); + // It is not generally safe. It is safer, and often faster to rely + // on memcpy. Yes, it is uglier, but it is also encapsulated. + T x; + std::memcpy(&x, &doc->tape[json_index + 1], sizeof(uint64_t)); + return x; + } + + simdjson_inline uint32_t internal::tape_ref::get_string_length() const noexcept { + size_t string_buf_index = size_t(tape_value()); + uint32_t len; + std::memcpy(&len, &doc->string_buf[string_buf_index], sizeof(len)); + return len; + } + + simdjson_inline const char* internal::tape_ref::get_c_str() const noexcept { + size_t string_buf_index = size_t(tape_value()); + return reinterpret_cast(&doc->string_buf[string_buf_index + sizeof(uint32_t)]); + } + + inline std::string_view internal::tape_ref::get_string_view() const noexcept { + return std::string_view( + get_c_str(), + get_string_length() + ); + } + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_TAPE_REF_INL_H +/* end file simdjson/internal/tape_ref-inl.h */ + +#include + +namespace simdjson { + + // + // simdjson_result inline implementation + // + simdjson_inline simdjson_result::simdjson_result() noexcept + : internal::simdjson_result_base() {} + simdjson_inline simdjson_result::simdjson_result(dom::array value) noexcept + : internal::simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : internal::simdjson_result_base(error) {} + +#if SIMDJSON_EXCEPTIONS + + inline dom::array::iterator simdjson_result::begin() const noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first.begin(); + } + inline dom::array::iterator simdjson_result::end() const noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first.end(); + } + inline size_t simdjson_result::size() const noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first.size(); + } + +#endif // SIMDJSON_EXCEPTIONS + + inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) const noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + inline simdjson_result simdjson_result::at(size_t index) const noexcept { + if (error()) { return error(); } + return first.at(index); + } + + namespace dom { + + // + // array inline implementation + // + simdjson_inline array::array() noexcept : tape{} {} + simdjson_inline array::array(const internal::tape_ref& _tape) noexcept : tape{ _tape } {} + inline array::iterator array::begin() const noexcept { + SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 + return internal::tape_ref(tape.doc, tape.json_index + 1); + } + inline array::iterator array::end() const noexcept { + SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 + return internal::tape_ref(tape.doc, tape.after_element() - 1); + } + inline size_t array::size() const noexcept { + SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 + return tape.scope_count(); + } + inline size_t array::number_of_slots() const noexcept { + SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 + return tape.matching_brace_index() - tape.json_index; + } + inline simdjson_result array::at_pointer(std::string_view json_pointer) const noexcept { + SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 + if (json_pointer.empty()) { // an empty string means that we return the current node + return element(this->tape); // copy the current node + } + else if (json_pointer[0] != '/') { // otherwise there is an error + return INVALID_JSON_POINTER; + } + json_pointer = json_pointer.substr(1); + // - means "the append position" or "the element after the end of the array" + // We don't support this, because we're returning a real element, not a position. + if (json_pointer == "-") { return INDEX_OUT_OF_BOUNDS; } + + // Read the array index + size_t array_index = 0; + size_t i; + for (i = 0; i < json_pointer.length() && json_pointer[i] != '/'; i++) { + uint8_t digit = uint8_t(json_pointer[i] - '0'); + // Check for non-digit in array index. If it's there, we're trying to get a field in an object + if (digit > 9) { return INCORRECT_TYPE; } + array_index = array_index * 10 + digit; + } + + // 0 followed by other digits is invalid + if (i > 1 && json_pointer[0] == '0') { return INVALID_JSON_POINTER; } // "JSON pointer array index has other characters after 0" + + // Empty string is invalid; so is a "/" with no digits before it + if (i == 0) { return INVALID_JSON_POINTER; } // "Empty string in JSON pointer array index" + + // Get the child + auto child = array(tape).at(array_index); + // If there is an error, it ends here + if (child.error()) { + return child; + } + // If there is a /, we're not done yet, call recursively. + if (i < json_pointer.length()) { + child = child.at_pointer(json_pointer.substr(i)); + } + return child; + } + + inline simdjson_result array::at(size_t index) const noexcept { + SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 + size_t i = 0; + for (auto element : *this) { + if (i == index) { return element; } + i++; + } + return INDEX_OUT_OF_BOUNDS; + } + + // + // array::iterator inline implementation + // + simdjson_inline array::iterator::iterator(const internal::tape_ref& _tape) noexcept : tape{ _tape } { } + inline element array::iterator::operator*() const noexcept { + return element(tape); + } + inline array::iterator& array::iterator::operator++() noexcept { + tape.json_index = tape.after_element(); + return *this; + } + inline array::iterator array::iterator::operator++(int) noexcept { + array::iterator out = *this; + ++*this; + return out; + } + inline bool array::iterator::operator!=(const array::iterator& other) const noexcept { + return tape.json_index != other.tape.json_index; + } + inline bool array::iterator::operator==(const array::iterator& other) const noexcept { + return tape.json_index == other.tape.json_index; + } + inline bool array::iterator::operator<(const array::iterator& other) const noexcept { + return tape.json_index < other.tape.json_index; + } + inline bool array::iterator::operator<=(const array::iterator& other) const noexcept { + return tape.json_index <= other.tape.json_index; + } + inline bool array::iterator::operator>=(const array::iterator& other) const noexcept { + return tape.json_index >= other.tape.json_index; + } + inline bool array::iterator::operator>(const array::iterator& other) const noexcept { + return tape.json_index > other.tape.json_index; + } + + } // namespace dom + + +} // namespace simdjson + +/* skipped duplicate #include "simdjson/dom/element-inl.h" */ + +#if defined(__cpp_lib_ranges) +static_assert(std::ranges::view); +static_assert(std::ranges::sized_range); +#if SIMDJSON_EXCEPTIONS +static_assert(std::ranges::view>); +static_assert(std::ranges::sized_range>); +#endif // SIMDJSON_EXCEPTIONS +#endif // defined(__cpp_lib_ranges) + +#endif // SIMDJSON_ARRAY_INL_H +/* end file simdjson/dom/array-inl.h */ +/* skipped duplicate #include "simdjson/dom/document_stream-inl.h" */ +/* including simdjson/dom/document-inl.h: #include "simdjson/dom/document-inl.h" */ +/* begin file simdjson/dom/document-inl.h */ +#ifndef SIMDJSON_DOCUMENT_INL_H +#define SIMDJSON_DOCUMENT_INL_H // Inline implementations go in here. +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/document.h" */ +/* skipped duplicate #include "simdjson/dom/element-inl.h" */ +/* skipped duplicate #include "simdjson/internal/tape_ref-inl.h" */ +/* including simdjson/internal/jsonformatutils.h: #include "simdjson/internal/jsonformatutils.h" */ +/* begin file simdjson/internal/jsonformatutils.h */ +#ifndef SIMDJSON_INTERNAL_JSONFORMATUTILS_H +#define SIMDJSON_INTERNAL_JSONFORMATUTILS_H + +/* skipped duplicate #include "simdjson/base.h" */ +#include #include +#include + +namespace simdjson { + namespace internal { + + inline std::ostream& operator<<(std::ostream& out, const escape_json_string& str); + + class escape_json_string { + public: + escape_json_string(std::string_view _str) noexcept : str{ _str } {} + operator std::string() const noexcept { std::stringstream s; s << *this; return s.str(); } + private: + std::string_view str; + friend std::ostream& operator<<(std::ostream& out, const escape_json_string& unescaped); + }; + + inline std::ostream& operator<<(std::ostream& out, const escape_json_string& unescaped) { + for (size_t i = 0; i < unescaped.str.length(); i++) { + switch (unescaped.str[i]) { + case '\b': + out << "\\b"; + break; + case '\f': + out << "\\f"; + break; + case '\n': + out << "\\n"; + break; + case '\r': + out << "\\r"; + break; + case '\"': + out << "\\\""; + break; + case '\t': + out << "\\t"; + break; + case '\\': + out << "\\\\"; + break; + default: + if (static_cast(unescaped.str[i]) <= 0x1F) { + // TODO can this be done once at the beginning, or will it mess up << char? + std::ios::fmtflags f(out.flags()); + out << "\\u" << std::hex << std::setw(4) << std::setfill('0') << int(unescaped.str[i]); + out.flags(f); + } + else { + out << unescaped.str[i]; + } + } + } + return out; + } + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_JSONFORMATUTILS_H +/* end file simdjson/internal/jsonformatutils.h */ + #include namespace simdjson { @@ -8037,270 +8714,26 @@ namespace simdjson { } // namespace dom } // namespace simdjson -#endif // SIMDJSON_INLINE_DOCUMENT_H -/* end file include/simdjson/dom/document-inl.h */ -/* begin file include/simdjson/dom/object-inl.h */ -#ifndef SIMDJSON_INLINE_OBJECT_H -#define SIMDJSON_INLINE_OBJECT_H - -#include -#include - -namespace simdjson { - - // - // simdjson_result inline implementation - // - simdjson_inline simdjson_result::simdjson_result() noexcept - : internal::simdjson_result_base() {} - simdjson_inline simdjson_result::simdjson_result(dom::object value) noexcept - : internal::simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : internal::simdjson_result_base(error) {} - - inline simdjson_result simdjson_result::operator[](std::string_view key) const noexcept { - if (error()) { return error(); } - return first[key]; - } - inline simdjson_result simdjson_result::operator[](const char* key) const noexcept { - if (error()) { return error(); } - return first[key]; - } - inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) const noexcept { - if (error()) { return error(); } - return first.at_pointer(json_pointer); - } - inline simdjson_result simdjson_result::at_key(std::string_view key) const noexcept { - if (error()) { return error(); } - return first.at_key(key); - } - inline simdjson_result simdjson_result::at_key_case_insensitive(std::string_view key) const noexcept { - if (error()) { return error(); } - return first.at_key_case_insensitive(key); - } - -#if SIMDJSON_EXCEPTIONS - - inline dom::object::iterator simdjson_result::begin() const noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first.begin(); - } - inline dom::object::iterator simdjson_result::end() const noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first.end(); - } - inline size_t simdjson_result::size() const noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first.size(); - } - -#endif // SIMDJSON_EXCEPTIONS - - namespace dom { - - // - // object inline implementation - // - simdjson_inline object::object() noexcept : tape{} {} - simdjson_inline object::object(const internal::tape_ref& _tape) noexcept : tape{ _tape } { } - inline object::iterator object::begin() const noexcept { - SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 - return internal::tape_ref(tape.doc, tape.json_index + 1); - } - inline object::iterator object::end() const noexcept { - SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 - return internal::tape_ref(tape.doc, tape.after_element() - 1); - } - inline size_t object::size() const noexcept { - SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 - return tape.scope_count(); - } - - inline simdjson_result object::operator[](std::string_view key) const noexcept { - return at_key(key); - } - inline simdjson_result object::operator[](const char* key) const noexcept { - return at_key(key); - } - inline simdjson_result object::at_pointer(std::string_view json_pointer) const noexcept { - SIMDJSON_DEVELOPMENT_ASSERT(tape.usable()); // https://github.com/simdjson/simdjson/issues/1914 - if (json_pointer.empty()) { // an empty string means that we return the current node - return element(this->tape); // copy the current node - } - else if (json_pointer[0] != '/') { // otherwise there is an error - return INVALID_JSON_POINTER; - } - json_pointer = json_pointer.substr(1); - size_t slash = json_pointer.find('/'); - std::string_view key = json_pointer.substr(0, slash); - // Grab the child with the given key - simdjson_result child; - - // If there is an escape character in the key, unescape it and then get the child. - size_t escape = key.find('~'); - if (escape != std::string_view::npos) { - // Unescape the key - std::string unescaped(key); - do { - switch (unescaped[escape + 1]) { - case '0': - unescaped.replace(escape, 2, "~"); - break; - case '1': - unescaped.replace(escape, 2, "/"); - break; - default: - return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); - } - escape = unescaped.find('~', escape + 1); - } while (escape != std::string::npos); - child = at_key(unescaped); - } - else { - child = at_key(key); - } - if (child.error()) { - return child; // we do not continue if there was an error - } - // If there is a /, we have to recurse and look up more of the path - if (slash != std::string_view::npos) { - child = child.at_pointer(json_pointer.substr(slash)); - } - return child; - } - - inline simdjson_result object::at_key(std::string_view key) const noexcept { - iterator end_field = end(); - for (iterator field = begin(); field != end_field; ++field) { - if (field.key_equals(key)) { - return field.value(); - } - } - return NO_SUCH_FIELD; - } - // In case you wonder why we need this, please see - // https://github.com/simdjson/simdjson/issues/323 - // People do seek keys in a case-insensitive manner. - inline simdjson_result object::at_key_case_insensitive(std::string_view key) const noexcept { - iterator end_field = end(); - for (iterator field = begin(); field != end_field; ++field) { - if (field.key_equals_case_insensitive(key)) { - return field.value(); - } - } - return NO_SUCH_FIELD; - } - - // - // object::iterator inline implementation - // - simdjson_inline object::iterator::iterator(const internal::tape_ref& _tape) noexcept : tape{ _tape } { } - inline const key_value_pair object::iterator::operator*() const noexcept { - return key_value_pair(key(), value()); - } - inline bool object::iterator::operator!=(const object::iterator& other) const noexcept { - return tape.json_index != other.tape.json_index; - } - inline bool object::iterator::operator==(const object::iterator& other) const noexcept { - return tape.json_index == other.tape.json_index; - } - inline bool object::iterator::operator<(const object::iterator& other) const noexcept { - return tape.json_index < other.tape.json_index; - } - inline bool object::iterator::operator<=(const object::iterator& other) const noexcept { - return tape.json_index <= other.tape.json_index; - } - inline bool object::iterator::operator>=(const object::iterator& other) const noexcept { - return tape.json_index >= other.tape.json_index; - } - inline bool object::iterator::operator>(const object::iterator& other) const noexcept { - return tape.json_index > other.tape.json_index; - } - inline object::iterator& object::iterator::operator++() noexcept { - tape.json_index++; - tape.json_index = tape.after_element(); - return *this; - } - inline object::iterator object::iterator::operator++(int) noexcept { - object::iterator out = *this; - ++* this; - return out; - } - inline std::string_view object::iterator::key() const noexcept { - return tape.get_string_view(); - } - inline uint32_t object::iterator::key_length() const noexcept { - return tape.get_string_length(); - } - inline const char* object::iterator::key_c_str() const noexcept { - return reinterpret_cast(&tape.doc->string_buf[size_t(tape.tape_value()) + sizeof(uint32_t)]); - } - inline element object::iterator::value() const noexcept { - return element(internal::tape_ref(tape.doc, tape.json_index + 1)); - } - - /** - * Design notes: - * Instead of constructing a string_view and then comparing it with a - * user-provided strings, it is probably more performant to have dedicated - * functions taking as a parameter the string we want to compare against - * and return true when they are equal. That avoids the creation of a temporary - * std::string_view. Though it is possible for the compiler to avoid entirely - * any overhead due to string_view, relying too much on compiler magic is - * problematic: compiler magic sometimes fail, and then what do you do? - * Also, enticing users to rely on high-performance function is probably better - * on the long run. - */ - - inline bool object::iterator::key_equals(std::string_view o) const noexcept { - // We use the fact that the key length can be computed quickly - // without access to the string buffer. - const uint32_t len = key_length(); - if (o.size() == len) { - // We avoid construction of a temporary string_view instance. - return (memcmp(o.data(), key_c_str(), len) == 0); - } - return false; - } - - inline bool object::iterator::key_equals_case_insensitive(std::string_view o) const noexcept { - // We use the fact that the key length can be computed quickly - // without access to the string buffer. - const uint32_t len = key_length(); - if (o.size() == len) { - // See For case-insensitive string comparisons, avoid char-by-char functions - // https://lemire.me/blog/2020/04/30/for-case-insensitive-string-comparisons-avoid-char-by-char-functions/ - // Note that it might be worth rolling our own strncasecmp function, with vectorization. - return (simdjson_strncasecmp(o.data(), key_c_str(), len) == 0); - } - return false; - } - // - // key_value_pair inline implementation - // - inline key_value_pair::key_value_pair(std::string_view _key, element _value) noexcept : - key(_key), value(_value) {} - - } // namespace dom - -} // namespace simdjson - -#if defined(__cpp_lib_ranges) -static_assert(std::ranges::view); -static_assert(std::ranges::sized_range); -#if SIMDJSON_EXCEPTIONS -static_assert(std::ranges::view>); -static_assert(std::ranges::sized_range>); -#endif // SIMDJSON_EXCEPTIONS -#endif // defined(__cpp_lib_ranges) - -#endif // SIMDJSON_INLINE_OBJECT_H -/* end file include/simdjson/dom/object-inl.h */ -/* begin file include/simdjson/dom/parsedjson_iterator-inl.h */ -#ifndef SIMDJSON_INLINE_PARSEDJSON_ITERATOR_H -#define SIMDJSON_INLINE_PARSEDJSON_ITERATOR_H +#endif // SIMDJSON_DOCUMENT_INL_H +/* end file simdjson/dom/document-inl.h */ +/* skipped duplicate #include "simdjson/dom/element-inl.h" */ +/* skipped duplicate #include "simdjson/dom/object-inl.h" */ +/* including simdjson/dom/parsedjson_iterator-inl.h: #include "simdjson/dom/parsedjson_iterator-inl.h" */ +/* begin file simdjson/dom/parsedjson_iterator-inl.h */ +#ifndef SIMDJSON_PARSEDJSON_ITERATOR_INL_H +#define SIMDJSON_PARSEDJSON_ITERATOR_INL_H + +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/parsedjson_iterator.h" */ +/* skipped duplicate #include "simdjson/internal/jsonformatutils.h" */ + +/* skipped duplicate #include "simdjson/dom/parser-inl.h" */ +/* skipped duplicate #include "simdjson/internal/tape_ref-inl.h" */ #include +#include +#include +#include #ifndef SIMDJSON_DISABLE_DEPRECATED_API @@ -8497,6 +8930,12 @@ namespace simdjson { current_type = uint8_t(current_val >> 56); } + inline void dom::parser::Iterator::rewind() { + while (up()) + ; + } + + bool dom::parser::Iterator::next() { size_t npos; if ((current_type == '[') || (current_type == '{')) { @@ -8669,6 +9108,48 @@ namespace simdjson { return found; } + inline bool dom::parser::Iterator::move_to(const std::string& pointer) { + return move_to(pointer.c_str(), uint32_t(pointer.length())); + } + + inline int64_t dom::parser::Iterator::get_integer() const { + if (location + 1 >= tape_length) { + return 0; // default value in case of error + } + return static_cast(doc.tape[location + 1]); + } + + inline uint64_t dom::parser::Iterator::get_unsigned_integer() const { + if (location + 1 >= tape_length) { + return 0; // default value in case of error + } + return doc.tape[location + 1]; + } + + inline const char* dom::parser::Iterator::get_string() const { + return reinterpret_cast( + doc.string_buf.get() + (current_val & internal::JSON_VALUE_MASK) + sizeof(uint32_t)); + } + + inline uint32_t dom::parser::Iterator::get_string_length() const { + uint32_t answer; + std::memcpy(&answer, + reinterpret_cast(doc.string_buf.get() + + (current_val & internal::JSON_VALUE_MASK)), + sizeof(uint32_t)); + return answer; + } + + inline double dom::parser::Iterator::get_double() const { + if (location + 1 >= tape_length) { + return std::numeric_limits::quiet_NaN(); // default value in + // case of error + } + double answer; + std::memcpy(&answer, &doc.tape[location + 1], sizeof(answer)); + return answer; + } + bool dom::parser::Iterator::relative_move_to(const char* pointer, uint32_t length) { if (length == 0) { @@ -8793,367 +9274,26 @@ namespace simdjson { #endif // SIMDJSON_DISABLE_DEPRECATED_API -#endif // SIMDJSON_INLINE_PARSEDJSON_ITERATOR_H -/* end file include/simdjson/dom/parsedjson_iterator-inl.h */ -/* begin file include/simdjson/dom/parser-inl.h */ -#ifndef SIMDJSON_INLINE_PARSER_H -#define SIMDJSON_INLINE_PARSER_H - -#include -#include - -namespace simdjson { - namespace dom { - - // - // parser inline implementation - // - simdjson_inline parser::parser(size_t max_capacity) noexcept - : _max_capacity{ max_capacity }, - loaded_bytes(nullptr) { - } - simdjson_inline parser::parser(parser&& other) noexcept = default; - simdjson_inline parser& parser::operator=(parser&& other) noexcept = default; - - inline bool parser::is_valid() const noexcept { return valid; } - inline int parser::get_error_code() const noexcept { return error; } - inline std::string parser::get_error_message() const noexcept { return error_message(error); } - - inline bool parser::dump_raw_tape(std::ostream& os) const noexcept { - return valid ? doc.dump_raw_tape(os) : false; - } - - inline simdjson_result parser::read_file(const std::string& path) noexcept { - // Open the file - SIMDJSON_PUSH_DISABLE_WARNINGS - SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe - std::FILE* fp = std::fopen(path.c_str(), "rb"); - SIMDJSON_POP_DISABLE_WARNINGS - - if (fp == nullptr) { - return IO_ERROR; - } - - // Get the file size - int ret; -#if SIMDJSON_VISUAL_STUDIO && !SIMDJSON_IS_32BITS - ret = _fseeki64(fp, 0, SEEK_END); -#else - ret = std::fseek(fp, 0, SEEK_END); -#endif // _WIN64 - if (ret < 0) { - std::fclose(fp); - return IO_ERROR; - } -#if SIMDJSON_VISUAL_STUDIO && !SIMDJSON_IS_32BITS - __int64 len = _ftelli64(fp); - if (len == -1L) { - std::fclose(fp); - return IO_ERROR; - } -#else - long len = std::ftell(fp); - if ((len < 0) || (len == LONG_MAX)) { - std::fclose(fp); - return IO_ERROR; - } -#endif - - // Make sure we have enough capacity to load the file - if (_loaded_bytes_capacity < size_t(len)) { - loaded_bytes.reset(internal::allocate_padded_buffer(len)); - if (!loaded_bytes) { - std::fclose(fp); - return MEMALLOC; - } - _loaded_bytes_capacity = len; - } - - // Read the string - std::rewind(fp); - size_t bytes_read = std::fread(loaded_bytes.get(), 1, len, fp); - if (std::fclose(fp) != 0 || bytes_read != size_t(len)) { - return IO_ERROR; - } - - return bytes_read; - } - - inline simdjson_result parser::load(const std::string& path) & noexcept { - size_t len; - auto _error = read_file(path).get(len); - if (_error) { return _error; } - return parse(loaded_bytes.get(), len, false); - } - - inline simdjson_result parser::load_many(const std::string& path, size_t batch_size) noexcept { - size_t len; - auto _error = read_file(path).get(len); - if (_error) { return _error; } - if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } - return document_stream(*this, reinterpret_cast(loaded_bytes.get()), len, batch_size); - } - - inline simdjson_result parser::parse_into_document(document& provided_doc, const uint8_t* buf, size_t len, bool realloc_if_needed) & noexcept { - // Important: we need to ensure that document has enough capacity. - // Important: It is possible that provided_doc is actually the internal 'doc' within the parser!!! - error_code _error = ensure_capacity(provided_doc, len); - if (_error) { return _error; } - if (realloc_if_needed) { - // Make sure we have enough capacity to copy len bytes - if (!loaded_bytes || _loaded_bytes_capacity < len) { - loaded_bytes.reset(internal::allocate_padded_buffer(len)); - if (!loaded_bytes) { - return MEMALLOC; - } - _loaded_bytes_capacity = len; - } - std::memcpy(static_cast(loaded_bytes.get()), buf, len); - } - _error = implementation->parse(realloc_if_needed ? reinterpret_cast(loaded_bytes.get()) : buf, len, provided_doc); - - if (_error) { return _error; } - - return provided_doc.root(); - } - - simdjson_inline simdjson_result parser::parse_into_document(document& provided_doc, const char* buf, size_t len, bool realloc_if_needed) & noexcept { - return parse_into_document(provided_doc, reinterpret_cast(buf), len, realloc_if_needed); - } - simdjson_inline simdjson_result parser::parse_into_document(document& provided_doc, const std::string& s) & noexcept { - return parse_into_document(provided_doc, s.data(), s.length(), s.capacity() - s.length() < SIMDJSON_PADDING); - } - simdjson_inline simdjson_result parser::parse_into_document(document& provided_doc, const padded_string& s) & noexcept { - return parse_into_document(provided_doc, s.data(), s.length(), false); - } - - - inline simdjson_result parser::parse(const uint8_t* buf, size_t len, bool realloc_if_needed) & noexcept { - return parse_into_document(doc, buf, len, realloc_if_needed); - } - - simdjson_inline simdjson_result parser::parse(const char* buf, size_t len, bool realloc_if_needed) & noexcept { - return parse(reinterpret_cast(buf), len, realloc_if_needed); - } - simdjson_inline simdjson_result parser::parse(const std::string& s) & noexcept { - return parse(s.data(), s.length(), s.capacity() - s.length() < SIMDJSON_PADDING); - } - simdjson_inline simdjson_result parser::parse(const padded_string& s) & noexcept { - return parse(s.data(), s.length(), false); - } - simdjson_inline simdjson_result parser::parse(const padded_string_view& v) & noexcept { - return parse(v.data(), v.length(), false); - } - - inline simdjson_result parser::parse_many(const uint8_t* buf, size_t len, size_t batch_size) noexcept { - if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } - return document_stream(*this, buf, len, batch_size); - } - inline simdjson_result parser::parse_many(const char* buf, size_t len, size_t batch_size) noexcept { - return parse_many(reinterpret_cast(buf), len, batch_size); - } - inline simdjson_result parser::parse_many(const std::string& s, size_t batch_size) noexcept { - return parse_many(s.data(), s.length(), batch_size); - } - inline simdjson_result parser::parse_many(const padded_string& s, size_t batch_size) noexcept { - return parse_many(s.data(), s.length(), batch_size); - } - - simdjson_inline size_t parser::capacity() const noexcept { - return implementation ? implementation->capacity() : 0; - } - simdjson_inline size_t parser::max_capacity() const noexcept { - return _max_capacity; - } - simdjson_inline size_t parser::max_depth() const noexcept { - return implementation ? implementation->max_depth() : DEFAULT_MAX_DEPTH; - } - - simdjson_warn_unused - inline error_code parser::allocate(size_t capacity, size_t max_depth) noexcept { - // - // Reallocate implementation if needed - // - error_code err; - if (implementation) { - err = implementation->allocate(capacity, max_depth); - } - else { - err = simdjson::get_active_implementation()->create_dom_parser_implementation(capacity, max_depth, implementation); - } - if (err) { return err; } - return SUCCESS; - } - -#ifndef SIMDJSON_DISABLE_DEPRECATED_API - simdjson_warn_unused - inline bool parser::allocate_capacity(size_t capacity, size_t max_depth) noexcept { - return !allocate(capacity, max_depth); - } -#endif // SIMDJSON_DISABLE_DEPRECATED_API - - inline error_code parser::ensure_capacity(size_t desired_capacity) noexcept { - return ensure_capacity(doc, desired_capacity); - } - - - inline error_code parser::ensure_capacity(document& target_document, size_t desired_capacity) noexcept { - // 1. It is wasteful to allocate a document and a parser for documents spanning less than MINIMAL_DOCUMENT_CAPACITY bytes. - // 2. If we allow desired_capacity = 0 then it is possible to exit this function with implementation == nullptr. - if (desired_capacity < MINIMAL_DOCUMENT_CAPACITY) { desired_capacity = MINIMAL_DOCUMENT_CAPACITY; } - // If we don't have enough capacity, (try to) automatically bump it. - // If the document needs allocation, do it too. - // Both in one if statement to minimize unlikely branching. - // - // Note: we must make sure that this function is called if capacity() == 0. We do so because we - // ensure that desired_capacity > 0. - if (simdjson_unlikely(capacity() < desired_capacity || target_document.capacity() < desired_capacity)) { - if (desired_capacity > max_capacity()) { - return error = CAPACITY; - } - error_code err1 = target_document.capacity() < desired_capacity ? target_document.allocate(desired_capacity) : SUCCESS; - error_code err2 = capacity() < desired_capacity ? allocate(desired_capacity, max_depth()) : SUCCESS; - if (err1 != SUCCESS) { return error = err1; } - if (err2 != SUCCESS) { return error = err2; } - } - return SUCCESS; - } - - simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { - if (max_capacity > MINIMAL_DOCUMENT_CAPACITY) { - _max_capacity = max_capacity; - } - else { - _max_capacity = MINIMAL_DOCUMENT_CAPACITY; - } - } - - } // namespace dom -} // namespace simdjson - -#endif // SIMDJSON_INLINE_PARSER_H -/* end file include/simdjson/dom/parser-inl.h */ -/* begin file include/simdjson/internal/tape_ref-inl.h */ -#ifndef SIMDJSON_INLINE_TAPE_REF_H -#define SIMDJSON_INLINE_TAPE_REF_H - -#include - -namespace simdjson { - namespace internal { - - // - // tape_ref inline implementation - // - simdjson_inline tape_ref::tape_ref() noexcept : doc{ nullptr }, json_index{ 0 } {} - simdjson_inline tape_ref::tape_ref(const dom::document* _doc, size_t _json_index) noexcept : doc{ _doc }, json_index{ _json_index } {} - - - simdjson_inline bool tape_ref::is_document_root() const noexcept { - return json_index == 1; // should we ever change the structure of the tape, this should get updated. - } - simdjson_inline bool tape_ref::usable() const noexcept { - return doc != nullptr; // when the document pointer is null, this tape_ref is uninitialized (should not be accessed). - } - // Some value types have a specific on-tape word value. It can be faster - // to check the type by doing a word-to-word comparison instead of extracting the - // most significant 8 bits. - - simdjson_inline bool tape_ref::is_double() const noexcept { - constexpr uint64_t tape_double = uint64_t(tape_type::DOUBLE) << 56; - return doc->tape[json_index] == tape_double; - } - simdjson_inline bool tape_ref::is_int64() const noexcept { - constexpr uint64_t tape_int64 = uint64_t(tape_type::INT64) << 56; - return doc->tape[json_index] == tape_int64; - } - simdjson_inline bool tape_ref::is_uint64() const noexcept { - constexpr uint64_t tape_uint64 = uint64_t(tape_type::UINT64) << 56; - return doc->tape[json_index] == tape_uint64; - } - simdjson_inline bool tape_ref::is_false() const noexcept { - constexpr uint64_t tape_false = uint64_t(tape_type::FALSE_VALUE) << 56; - return doc->tape[json_index] == tape_false; - } - simdjson_inline bool tape_ref::is_true() const noexcept { - constexpr uint64_t tape_true = uint64_t(tape_type::TRUE_VALUE) << 56; - return doc->tape[json_index] == tape_true; - } - simdjson_inline bool tape_ref::is_null_on_tape() const noexcept { - constexpr uint64_t tape_null = uint64_t(tape_type::NULL_VALUE) << 56; - return doc->tape[json_index] == tape_null; - } - - inline size_t tape_ref::after_element() const noexcept { - switch (tape_ref_type()) { - case tape_type::START_ARRAY: - case tape_type::START_OBJECT: - return matching_brace_index(); - case tape_type::UINT64: - case tape_type::INT64: - case tape_type::DOUBLE: - return json_index + 2; - default: - return json_index + 1; - } - } - simdjson_inline tape_type tape_ref::tape_ref_type() const noexcept { - return static_cast(doc->tape[json_index] >> 56); - } - simdjson_inline uint64_t internal::tape_ref::tape_value() const noexcept { - return doc->tape[json_index] & internal::JSON_VALUE_MASK; - } - simdjson_inline uint32_t internal::tape_ref::matching_brace_index() const noexcept { - return uint32_t(doc->tape[json_index]); - } - simdjson_inline uint32_t internal::tape_ref::scope_count() const noexcept { - return uint32_t((doc->tape[json_index] >> 32) & internal::JSON_COUNT_MASK); - } - - template - simdjson_inline T tape_ref::next_tape_value() const noexcept { - static_assert(sizeof(T) == sizeof(uint64_t), "next_tape_value() template parameter must be 64-bit"); - // Though the following is tempting... - // return *reinterpret_cast(&doc->tape[json_index + 1]); - // It is not generally safe. It is safer, and often faster to rely - // on memcpy. Yes, it is uglier, but it is also encapsulated. - T x; - std::memcpy(&x, &doc->tape[json_index + 1], sizeof(uint64_t)); - return x; - } - - simdjson_inline uint32_t internal::tape_ref::get_string_length() const noexcept { - size_t string_buf_index = size_t(tape_value()); - uint32_t len; - std::memcpy(&len, &doc->string_buf[string_buf_index], sizeof(len)); - return len; - } - - simdjson_inline const char* internal::tape_ref::get_c_str() const noexcept { - size_t string_buf_index = size_t(tape_value()); - return reinterpret_cast(&doc->string_buf[string_buf_index + sizeof(uint32_t)]); - } - - inline std::string_view internal::tape_ref::get_string_view() const noexcept { - return std::string_view( - get_c_str(), - get_string_length() - ); - } - - } // namespace internal -} // namespace simdjson - -#endif // SIMDJSON_INLINE_TAPE_REF_H -/* end file include/simdjson/internal/tape_ref-inl.h */ -/* begin file include/simdjson/dom/serialization-inl.h */ +#endif // SIMDJSON_PARSEDJSON_ITERATOR_INL_H +/* end file simdjson/dom/parsedjson_iterator-inl.h */ +/* skipped duplicate #include "simdjson/dom/parser-inl.h" */ +/* skipped duplicate #include "simdjson/internal/tape_ref-inl.h" */ +/* including simdjson/dom/serialization-inl.h: #include "simdjson/dom/serialization-inl.h" */ +/* begin file simdjson/dom/serialization-inl.h */ #ifndef SIMDJSON_SERIALIZATION_INL_H #define SIMDJSON_SERIALIZATION_INL_H +/* skipped duplicate #include "simdjson/dom/base.h" */ +/* skipped duplicate #include "simdjson/dom/serialization.h" */ +/* skipped duplicate #include "simdjson/dom/parser.h" */ +/* skipped duplicate #include "simdjson/internal/tape_type.h" */ -#include -#include +/* skipped duplicate #include "simdjson/dom/array-inl.h" */ +/* skipped duplicate #include "simdjson/dom/object-inl.h" */ +/* skipped duplicate #include "simdjson/internal/tape_ref-inl.h" */ + +#include namespace simdjson { namespace dom { @@ -9165,12 +9305,46 @@ namespace simdjson { os << answer; return true; } - } + + inline std::ostream& operator<<(std::ostream& out, simdjson::dom::element value) { + simdjson::internal::string_builder<> sb; + sb.append(value); + return (out << sb.str()); + } +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#endif + inline std::ostream& operator<<(std::ostream& out, simdjson::dom::array value) { + simdjson::internal::string_builder<> sb; + sb.append(value); + return (out << sb.str()); + } +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#endif + inline std::ostream& operator<<(std::ostream& out, simdjson::dom::object value) { + simdjson::internal::string_builder<> sb; + sb.append(value); + return (out << sb.str()); + } +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#endif + + } // namespace dom + /*** * Number utility functions **/ - - namespace { /**@private * Escape sequence like \b or \u0001 @@ -9189,7 +9363,7 @@ namespace simdjson { * adds the to_chars functions which would do as well, but * we want to support C++11. */ - char* fast_itoa(char* output, int64_t value) noexcept { + static char* fast_itoa(char* output, int64_t value) noexcept { // This is a standard implementation of itoa. char buffer[20]; uint64_t value_positive; @@ -9232,7 +9406,7 @@ namespace simdjson { * adds the to_chars functions which would do as well, but * we want to support C++11. */ - char* fast_itoa(char* output, uint64_t value) noexcept { + static char* fast_itoa(char* output, uint64_t value) noexcept { // This is a standard implementation of itoa. char buffer[20]; const char* const end_buffer = buffer + 20; @@ -9249,6 +9423,8 @@ namespace simdjson { std::memcpy(output, write_pointer, len); return output + len; } + + } // anonymous namespace namespace internal { @@ -9256,19 +9432,22 @@ namespace simdjson { * Minifier/formatter code. **/ - simdjson_inline void mini_formatter::number(uint64_t x) { + template + simdjson_inline void base_formatter::number(uint64_t x) { char number_buffer[24]; char* newp = fast_itoa(number_buffer, x); buffer.insert(buffer.end(), number_buffer, newp); } - simdjson_inline void mini_formatter::number(int64_t x) { + template + simdjson_inline void base_formatter::number(int64_t x) { char number_buffer[24]; char* newp = fast_itoa(number_buffer, x); buffer.insert(buffer.end(), number_buffer, newp); } - simdjson_inline void mini_formatter::number(double x) { + template + simdjson_inline void base_formatter::number(double x) { char number_buffer[24]; // Currently, passing the nullptr to the second argument is // safe because our implementation does not check the second @@ -9277,31 +9456,51 @@ namespace simdjson { buffer.insert(buffer.end(), number_buffer, newp); } - simdjson_inline void mini_formatter::start_array() { one_char('['); } - simdjson_inline void mini_formatter::end_array() { one_char(']'); } - simdjson_inline void mini_formatter::start_object() { one_char('{'); } - simdjson_inline void mini_formatter::end_object() { one_char('}'); } - simdjson_inline void mini_formatter::comma() { one_char(','); } + template + simdjson_inline void base_formatter::start_array() { one_char('['); } - simdjson_inline void mini_formatter::true_atom() { + template + simdjson_inline void base_formatter::end_array() { one_char(']'); } + + template + simdjson_inline void base_formatter::start_object() { one_char('{'); } + + template + simdjson_inline void base_formatter::end_object() { one_char('}'); } + + template + simdjson_inline void base_formatter::comma() { one_char(','); } + + template + simdjson_inline void base_formatter::true_atom() { const char* s = "true"; buffer.insert(buffer.end(), s, s + 4); } - simdjson_inline void mini_formatter::false_atom() { + + template + simdjson_inline void base_formatter::false_atom() { const char* s = "false"; buffer.insert(buffer.end(), s, s + 5); } - simdjson_inline void mini_formatter::null_atom() { + + template + simdjson_inline void base_formatter::null_atom() { const char* s = "null"; buffer.insert(buffer.end(), s, s + 4); } - simdjson_inline void mini_formatter::one_char(char c) { buffer.push_back(c); } - simdjson_inline void mini_formatter::key(std::string_view unescaped) { + + template + simdjson_inline void base_formatter::one_char(char c) { buffer.push_back(c); } + + template + simdjson_inline void base_formatter::key(std::string_view unescaped) { string(unescaped); one_char(':'); } - simdjson_inline void mini_formatter::string(std::string_view unescaped) { + + template + simdjson_inline void base_formatter::string(std::string_view unescaped) { one_char('\"'); size_t i = 0; // Fast path for the case where we have no control character, no ", and no backslash. @@ -9383,14 +9582,46 @@ namespace simdjson { one_char('\"'); } - inline void mini_formatter::clear() { + + template + inline void base_formatter::clear() { buffer.clear(); } - simdjson_inline std::string_view mini_formatter::str() const { + template + simdjson_inline std::string_view base_formatter::str() const { return std::string_view(buffer.data(), buffer.size()); } + simdjson_inline void mini_formatter::print_newline() { + return; + } + + simdjson_inline void mini_formatter::print_indents(size_t depth) { + (void)depth; + return; + } + + simdjson_inline void mini_formatter::print_space() { + return; + } + + simdjson_inline void pretty_formatter::print_newline() { + one_char('\n'); + } + + simdjson_inline void pretty_formatter::print_indents(size_t depth) { + if (this->indent_step <= 0) { + return; + } + for (size_t i = 0; i < this->indent_step * depth; i++) { + one_char(' '); + } + } + + simdjson_inline void pretty_formatter::print_space() { + one_char(' '); + } /*** * String building code. @@ -9410,11 +9641,16 @@ namespace simdjson { // print commas after each value if (after_value) { format.comma(); + format.print_newline(); } + + format.print_indents(depth); + // If we are in an object, print the next key and :, and skip to the next // value. if (is_object[depth]) { format.key(iter.get_string_view()); + format.print_space(); iter.json_index++; } switch (iter.tape_ref_type()) { @@ -9443,6 +9679,7 @@ namespace simdjson { is_object[depth] = false; after_value = false; + format.print_newline(); continue; } @@ -9470,6 +9707,7 @@ namespace simdjson { is_object[depth] = true; after_value = false; + format.print_newline(); continue; } @@ -9514,18 +9752,22 @@ namespace simdjson { // Handle multiple ends in a row while (depth != 0 && (iter.tape_ref_type() == tape_type::END_ARRAY || iter.tape_ref_type() == tape_type::END_OBJECT)) { + format.print_newline(); + depth--; + format.print_indents(depth); if (iter.tape_ref_type() == tape_type::END_ARRAY) { format.end_array(); } else { format.end_object(); } - depth--; iter.json_index++; } // Stop when we're at depth 0 } while (depth != 0); + + format.print_newline(); } template @@ -9579,43 +9821,290 @@ namespace simdjson { } // namespace simdjson #endif -/* end file include/simdjson/dom/serialization-inl.h */ - -SIMDJSON_POP_DISABLE_WARNINGS +/* end file simdjson/dom/serialization-inl.h */ #endif // SIMDJSON_DOM_H -/* end file include/simdjson/dom.h */ -/* begin file include/simdjson/builtin.h */ +/* end file simdjson/dom.h */ +/* including simdjson/ondemand.h: #include "simdjson/ondemand.h" */ +/* begin file simdjson/ondemand.h */ +#ifndef SIMDJSON_ONDEMAND_H +#define SIMDJSON_ONDEMAND_H + +/* including simdjson/builtin/ondemand.h: #include "simdjson/builtin/ondemand.h" */ +/* begin file simdjson/builtin/ondemand.h */ +#ifndef SIMDJSON_BUILTIN_ONDEMAND_H +#define SIMDJSON_BUILTIN_ONDEMAND_H + +/* including simdjson/builtin.h: #include "simdjson/builtin.h" */ +/* begin file simdjson/builtin.h */ #ifndef SIMDJSON_BUILTIN_H #define SIMDJSON_BUILTIN_H -/* begin file include/simdjson/implementations.h */ -#ifndef SIMDJSON_IMPLEMENTATIONS_H -#define SIMDJSON_IMPLEMENTATIONS_H +/* including simdjson/builtin/base.h: #include "simdjson/builtin/base.h" */ +/* begin file simdjson/builtin/base.h */ +#ifndef SIMDJSON_BUILTIN_BASE_H +#define SIMDJSON_BUILTIN_BASE_H -/* begin file include/simdjson/implementation-base.h */ -#ifndef SIMDJSON_IMPLEMENTATION_BASE_H -#define SIMDJSON_IMPLEMENTATION_BASE_H +/* skipped duplicate #include "simdjson/base.h" */ +/* including simdjson/implementation_detection.h: #include "simdjson/implementation_detection.h" */ +/* begin file simdjson/implementation_detection.h */ +#ifndef SIMDJSON_IMPLEMENTATION_DETECTION_H +#define SIMDJSON_IMPLEMENTATION_DETECTION_H -/** - * @file - * - * Includes common stuff needed for implementations. - */ +/* skipped duplicate #include "simdjson/base.h" */ +// 0 is reserved, because undefined SIMDJSON_IMPLEMENTATION equals 0 in preprocessor macros. +#define SIMDJSON_IMPLEMENTATION_ID_arm64 1 +#define SIMDJSON_IMPLEMENTATION_ID_fallback 2 +#define SIMDJSON_IMPLEMENTATION_ID_haswell 3 +#define SIMDJSON_IMPLEMENTATION_ID_icelake 4 +#define SIMDJSON_IMPLEMENTATION_ID_ppc64 5 +#define SIMDJSON_IMPLEMENTATION_ID_westmere 6 - // Implementation-internal files (must be included before the implementations themselves, to keep - // amalgamation working--otherwise, the first time a file is included, it might be put inside the - // #ifdef SIMDJSON_IMPLEMENTATION_ARM64/FALLBACK/etc., which means the other implementations can't - // compile unless that implementation is turned on). - /* begin file include/simdjson/internal/jsoncharutils_tables.h */ +#define SIMDJSON_IMPLEMENTATION_ID_FOR(IMPL) SIMDJSON_CAT(SIMDJSON_IMPLEMENTATION_ID_, IMPL) +#define SIMDJSON_IMPLEMENTATION_ID SIMDJSON_IMPLEMENTATION_ID_FOR(SIMDJSON_IMPLEMENTATION) + +#define SIMDJSON_IMPLEMENTATION_IS(IMPL) SIMDJSON_IMPLEMENTATION_ID == SIMDJSON_IMPLEMENTATION_ID_FOR(IMPL) + +// +// First, figure out which implementations can be run. Doing it here makes it so we don't have to worry about the order +// in which we include them. +// + +#ifndef SIMDJSON_IMPLEMENTATION_ARM64 +#define SIMDJSON_IMPLEMENTATION_ARM64 (SIMDJSON_IS_ARM64) +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_ARM64 SIMDJSON_IMPLEMENTATION_ARM64 && SIMDJSON_IS_ARM64 + +// Default Icelake to on if this is x86-64. Even if we're not compiled for it, it could be selected +// at runtime. +#ifndef SIMDJSON_IMPLEMENTATION_ICELAKE +#define SIMDJSON_IMPLEMENTATION_ICELAKE ((SIMDJSON_IS_X86_64) && (SIMDJSON_AVX512_ALLOWED) && (SIMDJSON_COMPILER_SUPPORTS_VBMI2)) +#endif + +#ifdef _MSC_VER +// To see why (__BMI__) && (__PCLMUL__) && (__LZCNT__) are not part of this next line, see +// https://github.com/simdjson/simdjson/issues/1247 +#define SIMDJSON_CAN_ALWAYS_RUN_ICELAKE ((SIMDJSON_IMPLEMENTATION_ICELAKE) && (__AVX2__) && (__AVX512F__) && (__AVX512DQ__) && (__AVX512CD__) && (__AVX512BW__) && (__AVX512VL__) && (__AVX512VBMI2__)) +#else +#define SIMDJSON_CAN_ALWAYS_RUN_ICELAKE ((SIMDJSON_IMPLEMENTATION_ICELAKE) && (__AVX2__) && (__BMI__) && (__PCLMUL__) && (__LZCNT__) && (__AVX512F__) && (__AVX512DQ__) && (__AVX512CD__) && (__AVX512BW__) && (__AVX512VL__) && (__AVX512VBMI2__)) +#endif + +// Default Haswell to on if this is x86-64. Even if we're not compiled for it, it could be selected +// at runtime. +#ifndef SIMDJSON_IMPLEMENTATION_HASWELL +#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +// if icelake is always available, never enable haswell. +#define SIMDJSON_IMPLEMENTATION_HASWELL 0 +#else +#define SIMDJSON_IMPLEMENTATION_HASWELL SIMDJSON_IS_X86_64 +#endif +#endif +#ifdef _MSC_VER +// To see why (__BMI__) && (__PCLMUL__) && (__LZCNT__) are not part of this next line, see +// https://github.com/simdjson/simdjson/issues/1247 +#define SIMDJSON_CAN_ALWAYS_RUN_HASWELL ((SIMDJSON_IMPLEMENTATION_HASWELL) && (SIMDJSON_IS_X86_64) && (__AVX2__)) +#else +#define SIMDJSON_CAN_ALWAYS_RUN_HASWELL ((SIMDJSON_IMPLEMENTATION_HASWELL) && (SIMDJSON_IS_X86_64) && (__AVX2__) && (__BMI__) && (__PCLMUL__) && (__LZCNT__)) +#endif + +// Default Westmere to on if this is x86-64. +#ifndef SIMDJSON_IMPLEMENTATION_WESTMERE +#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE || SIMDJSON_CAN_ALWAYS_RUN_HASWELL +// if icelake or haswell are always available, never enable westmere. +#define SIMDJSON_IMPLEMENTATION_WESTMERE 0 +#else +#define SIMDJSON_IMPLEMENTATION_WESTMERE SIMDJSON_IS_X86_64 +#endif +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_WESTMERE (SIMDJSON_IMPLEMENTATION_WESTMERE && SIMDJSON_IS_X86_64 && __SSE4_2__ && __PCLMUL__) + +#ifndef SIMDJSON_IMPLEMENTATION_PPC64 +#define SIMDJSON_IMPLEMENTATION_PPC64 (SIMDJSON_IS_PPC64 && SIMDJSON_IS_PPC64_VMX) +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_PPC64 SIMDJSON_IMPLEMENTATION_PPC64 && SIMDJSON_IS_PPC64 && SIMDJSON_IS_PPC64_VMX + +// Default Fallback to on unless a builtin implementation has already been selected. +#ifndef SIMDJSON_IMPLEMENTATION_FALLBACK +#if SIMDJSON_CAN_ALWAYS_RUN_ARM64 || SIMDJSON_CAN_ALWAYS_RUN_ICELAKE || SIMDJSON_CAN_ALWAYS_RUN_HASWELL || SIMDJSON_CAN_ALWAYS_RUN_WESTMERE || SIMDJSON_CAN_ALWAYS_RUN_PPC64 +// if anything at all except fallback can always run, then disable fallback. +#define SIMDJSON_IMPLEMENTATION_FALLBACK 0 +#else +#define SIMDJSON_IMPLEMENTATION_FALLBACK 1 +#endif +#endif +#define SIMDJSON_CAN_ALWAYS_RUN_FALLBACK SIMDJSON_IMPLEMENTATION_FALLBACK + +// Determine the best builtin implementation +#ifndef SIMDJSON_BUILTIN_IMPLEMENTATION + +#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +#define SIMDJSON_BUILTIN_IMPLEMENTATION icelake +#elif SIMDJSON_CAN_ALWAYS_RUN_HASWELL +#define SIMDJSON_BUILTIN_IMPLEMENTATION haswell +#elif SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +#define SIMDJSON_BUILTIN_IMPLEMENTATION westmere +#elif SIMDJSON_CAN_ALWAYS_RUN_ARM64 +#define SIMDJSON_BUILTIN_IMPLEMENTATION arm64 +#elif SIMDJSON_CAN_ALWAYS_RUN_PPC64 +#define SIMDJSON_BUILTIN_IMPLEMENTATION ppc64 +#elif SIMDJSON_CAN_ALWAYS_RUN_FALLBACK +#define SIMDJSON_BUILTIN_IMPLEMENTATION fallback +#else +#error "All possible implementations (including fallback) have been disabled! simdjson will not run." +#endif + +#endif // SIMDJSON_BUILTIN_IMPLEMENTATION + +#define SIMDJSON_BUILTIN_IMPLEMENTATION_ID SIMDJSON_IMPLEMENTATION_ID_FOR(SIMDJSON_BUILTIN_IMPLEMENTATION) +#define SIMDJSON_BUILTIN_IMPLEMENTATION_IS(IMPL) SIMDJSON_BUILTIN_IMPLEMENTATION_ID == SIMDJSON_IMPLEMENTATION_ID_FOR(IMPL) + +#endif // SIMDJSON_IMPLEMENTATION_DETECTION_H +/* end file simdjson/implementation_detection.h */ + +namespace simdjson { +#if SIMDJSON_BUILTIN_IMPLEMENTATION_IS(arm64) + namespace arm64 {} +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(fallback) + namespace fallback {} +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(haswell) + namespace haswell {} +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(icelake) + namespace icelake {} +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(ppc64) + namespace ppc64 {} +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(westmere) + namespace westmere {} +#else +#error Unknown SIMDJSON_BUILTIN_IMPLEMENTATION +#endif + + /** + * Represents the best statically linked simdjson implementation that can be used by the compiling + * program. + * + * Detects what options the program is compiled against, and picks the minimum implementation that + * will work on any computer that can run the program. For example, if you compile with g++ + * -march=westmere, it will pick the westmere implementation. The haswell implementation will + * still be available, and can be selected at runtime, but the builtin implementation (and any + * code that uses it) will use westmere. + */ + namespace builtin = SIMDJSON_BUILTIN_IMPLEMENTATION; +} // namespace simdjson + +#endif // SIMDJSON_BUILTIN_BASE_H +/* end file simdjson/builtin/base.h */ +/* including simdjson/builtin/implementation.h: #include "simdjson/builtin/implementation.h" */ +/* begin file simdjson/builtin/implementation.h */ +#ifndef SIMDJSON_BUILTIN_IMPLEMENTATION_H +#define SIMDJSON_BUILTIN_IMPLEMENTATION_H + +/* skipped duplicate #include "simdjson/builtin/base.h" */ + +/* including simdjson/generic/dependencies.h: #include "simdjson/generic/dependencies.h" */ +/* begin file simdjson/generic/dependencies.h */ +#ifdef SIMDJSON_CONDITIONAL_INCLUDE +#error simdjson/generic/dependencies.h must be included before defining SIMDJSON_CONDITIONAL_INCLUDE! +#endif + +#ifndef SIMDJSON_GENERIC_DEPENDENCIES_H +#define SIMDJSON_GENERIC_DEPENDENCIES_H + +// Internal headers needed for generics. +// All includes referencing simdjson headers *not* under simdjson/generic must be here! +// Otherwise, amalgamation will fail. +/* skipped duplicate #include "simdjson/base.h" */ +/* skipped duplicate #include "simdjson/implementation.h" */ +/* skipped duplicate #include "simdjson/implementation_detection.h" */ +/* including simdjson/internal/instruction_set.h: #include "simdjson/internal/instruction_set.h" */ +/* begin file simdjson/internal/instruction_set.h */ +/* From +https://github.com/endorno/pytorch/blob/master/torch/lib/TH/generic/simd/simd.h +Highly modified. + +Copyright (c) 2016- Facebook, Inc (Adam Paszke) +Copyright (c) 2014- Facebook, Inc (Soumith Chintala) +Copyright (c) 2011-2014 Idiap Research Institute (Ronan Collobert) +Copyright (c) 2012-2014 Deepmind Technologies (Koray Kavukcuoglu) +Copyright (c) 2011-2012 NEC Laboratories America (Koray Kavukcuoglu) +Copyright (c) 2011-2013 NYU (Clement Farabet) +Copyright (c) 2006-2010 NEC Laboratories America (Ronan Collobert, Leon Bottou, +Iain Melvin, Jason Weston) Copyright (c) 2006 Idiap Research Institute +(Samy Bengio) Copyright (c) 2001-2004 Idiap Research Institute (Ronan Collobert, +Samy Bengio, Johnny Mariethoz) + +All rights reserved. + +Redistribution and use in source and binary forms, with or without +modification, are permitted provided that the following conditions are met: + +1. Redistributions of source code must retain the above copyright + notice, this list of conditions and the following disclaimer. + +2. Redistributions in binary form must reproduce the above copyright + notice, this list of conditions and the following disclaimer in the + documentation and/or other materials provided with the distribution. + +3. Neither the names of Facebook, Deepmind Technologies, NYU, NEC Laboratories +America and IDIAP Research Institute nor the names of its contributors may be + used to endorse or promote products derived from this software without + specific prior written permission. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" +AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE +IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE +ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE +LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR +CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF +SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS +INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN +CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) +ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE +POSSIBILITY OF SUCH DAMAGE. +*/ + +#ifndef SIMDJSON_INTERNAL_INSTRUCTION_SET_H +#define SIMDJSON_INTERNAL_INSTRUCTION_SET_H + +namespace simdjson { + namespace internal { + + enum instruction_set { + DEFAULT = 0x0, + NEON = 0x1, + AVX2 = 0x4, + SSE42 = 0x8, + PCLMULQDQ = 0x10, + BMI1 = 0x20, + BMI2 = 0x40, + ALTIVEC = 0x80, + AVX512F = 0x100, + AVX512DQ = 0x200, + AVX512IFMA = 0x400, + AVX512PF = 0x800, + AVX512ER = 0x1000, + AVX512CD = 0x2000, + AVX512BW = 0x4000, + AVX512VL = 0x8000, + AVX512VBMI2 = 0x10000 + }; + + } // namespace internal +} // namespace simdjson + +#endif // SIMDJSON_INTERNAL_INSTRUCTION_SET_H +/* end file simdjson/internal/instruction_set.h */ +/* skipped duplicate #include "simdjson/internal/dom_parser_implementation.h" */ +/* including simdjson/internal/jsoncharutils_tables.h: #include "simdjson/internal/jsoncharutils_tables.h" */ +/* begin file simdjson/internal/jsoncharutils_tables.h */ #ifndef SIMDJSON_INTERNAL_JSONCHARUTILS_TABLES_H #define SIMDJSON_INTERNAL_JSONCHARUTILS_TABLES_H +/* skipped duplicate #include "simdjson/base.h" */ #ifdef JSON_TEST_STRINGS - void found_string(const uint8_t* buf, const uint8_t* parsed_begin, - const uint8_t* parsed_end); +void found_string(const uint8_t* buf, const uint8_t* parsed_begin, + const uint8_t* parsed_end); void found_bad_string(const uint8_t* buf); #endif @@ -9634,11 +10123,13 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_INTERNAL_JSONCHARUTILS_TABLES_H -/* end file include/simdjson/internal/jsoncharutils_tables.h */ -/* begin file include/simdjson/internal/numberparsing_tables.h */ +/* end file simdjson/internal/jsoncharutils_tables.h */ +/* including simdjson/internal/numberparsing_tables.h: #include "simdjson/internal/numberparsing_tables.h" */ +/* begin file simdjson/internal/numberparsing_tables.h */ #ifndef SIMDJSON_INTERNAL_NUMBERPARSING_TABLES_H #define SIMDJSON_INTERNAL_NUMBERPARSING_TABLES_H +/* skipped duplicate #include "simdjson/base.h" */ namespace simdjson { namespace internal { @@ -9694,11 +10185,14 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_INTERNAL_NUMBERPARSING_TABLES_H -/* end file include/simdjson/internal/numberparsing_tables.h */ -/* begin file include/simdjson/internal/simdprune_tables.h */ +/* end file simdjson/internal/numberparsing_tables.h */ +/* including simdjson/internal/simdprune_tables.h: #include "simdjson/internal/simdprune_tables.h" */ +/* begin file simdjson/internal/simdprune_tables.h */ #ifndef SIMDJSON_INTERNAL_SIMDPRUNE_TABLES_H #define SIMDJSON_INTERNAL_SIMDPRUNE_TABLES_H +/* skipped duplicate #include "simdjson/base.h" */ + #include namespace simdjson { // table modified and copied from @@ -9715,133 +10209,29 @@ namespace simdjson { // table modified and copied from } // namespace simdjson #endif // SIMDJSON_INTERNAL_SIMDPRUNE_TABLES_H -/* end file include/simdjson/internal/simdprune_tables.h */ +/* end file simdjson/internal/simdprune_tables.h */ -#endif // SIMDJSON_IMPLEMENTATION_BASE_H -/* end file include/simdjson/implementation-base.h */ +#endif // SIMDJSON_GENERIC_DEPENDENCIES_H +/* end file simdjson/generic/dependencies.h */ -// -// First, figure out which implementations can be run. Doing it here makes it so we don't have to worry about the order -// in which we include them. -// +/* defining SIMDJSON_CONDITIONAL_INCLUDE */ +#define SIMDJSON_CONDITIONAL_INCLUDE -#ifndef SIMDJSON_IMPLEMENTATION_ARM64 -#define SIMDJSON_IMPLEMENTATION_ARM64 (SIMDJSON_IS_ARM64) -#endif -#define SIMDJSON_CAN_ALWAYS_RUN_ARM64 SIMDJSON_IMPLEMENTATION_ARM64 && SIMDJSON_IS_ARM64 - -#ifdef __has_include -// How do we detect that a compiler supports vbmi2? -// For sure if the following header is found, we are ok? -#if __has_include() -#define SIMDJSON_COMPILER_SUPPORTS_VBMI2 1 -#endif -#endif - -#ifdef _MSC_VER -#if _MSC_VER >= 1920 -// Visual Studio 2019 and up support VBMI2 under x64 even if the header -// avx512vbmi2intrin.h is not found. -#define SIMDJSON_COMPILER_SUPPORTS_VBMI2 1 -#endif -#endif - -// By default, we allow AVX512. -#ifndef SIMDJSON_AVX512_ALLOWED -#define SIMDJSON_AVX512_ALLOWED 1 -#endif - -// Default Icelake to on if this is x86-64. Even if we're not compiled for it, it could be selected -// at runtime. -#ifndef SIMDJSON_IMPLEMENTATION_ICELAKE -#define SIMDJSON_IMPLEMENTATION_ICELAKE ((SIMDJSON_IS_X86_64) && (SIMDJSON_AVX512_ALLOWED) && (SIMDJSON_COMPILER_SUPPORTS_VBMI2)) -#endif - -#ifdef _MSC_VER -// To see why (__BMI__) && (__PCLMUL__) && (__LZCNT__) are not part of this next line, see -// https://github.com/simdjson/simdjson/issues/1247 -#define SIMDJSON_CAN_ALWAYS_RUN_ICELAKE ((SIMDJSON_IMPLEMENTATION_ICELAKE) && (__AVX2__) && (__AVX512F__) && (__AVX512DQ__) && (__AVX512CD__) && (__AVX512BW__) && (__AVX512VL__) && (__AVX512VBMI2__)) -#else -#define SIMDJSON_CAN_ALWAYS_RUN_ICELAKE ((SIMDJSON_IMPLEMENTATION_ICELAKE) && (__AVX2__) && (__BMI__) && (__PCLMUL__) && (__LZCNT__) && (__AVX512F__) && (__AVX512DQ__) && (__AVX512CD__) && (__AVX512BW__) && (__AVX512VL__) && (__AVX512VBMI2__)) -#endif - -// Default Haswell to on if this is x86-64. Even if we're not compiled for it, it could be selected -// at runtime. -#ifndef SIMDJSON_IMPLEMENTATION_HASWELL -#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE -// if icelake is always available, never enable haswell. -#define SIMDJSON_IMPLEMENTATION_HASWELL 0 -#else -#define SIMDJSON_IMPLEMENTATION_HASWELL SIMDJSON_IS_X86_64 -#endif -#endif -#ifdef _MSC_VER -// To see why (__BMI__) && (__PCLMUL__) && (__LZCNT__) are not part of this next line, see -// https://github.com/simdjson/simdjson/issues/1247 -#define SIMDJSON_CAN_ALWAYS_RUN_HASWELL ((SIMDJSON_IMPLEMENTATION_HASWELL) && (SIMDJSON_IS_X86_64) && (__AVX2__)) -#else -#define SIMDJSON_CAN_ALWAYS_RUN_HASWELL ((SIMDJSON_IMPLEMENTATION_HASWELL) && (SIMDJSON_IS_X86_64) && (__AVX2__) && (__BMI__) && (__PCLMUL__) && (__LZCNT__)) -#endif - -// Default Westmere to on if this is x86-64. -#ifndef SIMDJSON_IMPLEMENTATION_WESTMERE -#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE || SIMDJSON_CAN_ALWAYS_RUN_HASWELL -// if icelake or haswell are always available, never enable westmere. -#define SIMDJSON_IMPLEMENTATION_WESTMERE 0 -#else -#define SIMDJSON_IMPLEMENTATION_WESTMERE SIMDJSON_IS_X86_64 -#endif -#endif -#define SIMDJSON_CAN_ALWAYS_RUN_WESTMERE (SIMDJSON_IMPLEMENTATION_WESTMERE && SIMDJSON_IS_X86_64 && __SSE4_2__ && __PCLMUL__) - -#ifndef SIMDJSON_IMPLEMENTATION_PPC64 -#define SIMDJSON_IMPLEMENTATION_PPC64 (SIMDJSON_IS_PPC64) -#endif -#define SIMDJSON_CAN_ALWAYS_RUN_PPC64 SIMDJSON_IMPLEMENTATION_PPC64 && SIMDJSON_IS_PPC64 - -// Default Fallback to on unless a builtin implementation has already been selected. -#ifndef SIMDJSON_IMPLEMENTATION_FALLBACK -#if SIMDJSON_CAN_ALWAYS_RUN_ARM64 || SIMDJSON_CAN_ALWAYS_RUN_ICELAKE || SIMDJSON_CAN_ALWAYS_RUN_HASWELL || SIMDJSON_CAN_ALWAYS_RUN_WESTMERE || SIMDJSON_CAN_ALWAYS_RUN_PPC64 -// if anything at all except fallback can always run, then disable fallback. -#define SIMDJSON_IMPLEMENTATION_FALLBACK 0 -#else -#define SIMDJSON_IMPLEMENTATION_FALLBACK 1 -#endif -#endif -#define SIMDJSON_CAN_ALWAYS_RUN_FALLBACK SIMDJSON_IMPLEMENTATION_FALLBACK - -SIMDJSON_PUSH_DISABLE_WARNINGS -SIMDJSON_DISABLE_UNDESIRED_WARNINGS - -// Implementations -/* begin file include/simdjson/arm64.h */ -#ifndef SIMDJSON_ARM64_H -#define SIMDJSON_ARM64_H - - -#if SIMDJSON_IMPLEMENTATION_ARM64 - -namespace simdjson { - /** - * Implementation for NEON (ARMv8). - */ - namespace arm64 { - } // namespace arm64 -} // namespace simdjson - -/* begin file include/simdjson/arm64/implementation.h */ +#if SIMDJSON_BUILTIN_IMPLEMENTATION_IS(arm64) +/* including simdjson/arm64/implementation.h: #include "simdjson/arm64/implementation.h" */ +/* begin file simdjson/arm64/implementation.h */ #ifndef SIMDJSON_ARM64_IMPLEMENTATION_H #define SIMDJSON_ARM64_IMPLEMENTATION_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { - namespace { - using namespace simdjson; - using namespace simdjson::dom; - } - /** * @private */ @@ -9861,100 +10251,278 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_ARM64_IMPLEMENTATION_H -/* end file include/simdjson/arm64/implementation.h */ +/* end file simdjson/arm64/implementation.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(fallback) +/* including simdjson/fallback/implementation.h: #include "simdjson/fallback/implementation.h" */ +/* begin file simdjson/fallback/implementation.h */ +#ifndef SIMDJSON_FALLBACK_IMPLEMENTATION_H +#define SIMDJSON_FALLBACK_IMPLEMENTATION_H -/* begin file include/simdjson/arm64/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "arm64" -// #define SIMDJSON_IMPLEMENTATION arm64 -/* end file include/simdjson/arm64/begin.h */ - -// Declarations -/* begin file include/simdjson/generic/dom_parser_implementation.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace arm64 { + namespace fallback { - // expectation: sizeof(open_container) = 64/8. - struct open_container { - uint32_t tape_index; // where, on the tape, does the scope ([,{) begins - uint32_t count; // how many elements in the scope - }; // struct open_container - - static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); - - class dom_parser_implementation final : public internal::dom_parser_implementation { + /** + * @private + */ + class implementation final : public simdjson::implementation { public: - /** Tape location of each open { or [ */ - std::unique_ptr open_containers{}; - /** Whether each open container is a [ or { */ - std::unique_ptr is_array{}; - /** Buffer passed to stage 1 */ - const uint8_t* buf{}; - /** Length passed to stage 1 */ - size_t len{ 0 }; - /** Document passed to stage 2 */ - dom::document* doc{}; - - inline dom_parser_implementation() noexcept; - inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; - inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; - dom_parser_implementation(const dom_parser_implementation&) = delete; - dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; - - simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; - simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; - simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; - simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; - inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; - inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; - private: - simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); - + simdjson_inline implementation() : simdjson::implementation( + "fallback", + "Generic fallback implementation", + 0 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; }; - } // namespace arm64 + } // namespace fallback } // namespace simdjson +#endif // SIMDJSON_FALLBACK_IMPLEMENTATION_H +/* end file simdjson/fallback/implementation.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(haswell) +/* including simdjson/haswell/implementation.h: #include "simdjson/haswell/implementation.h" */ +/* begin file simdjson/haswell/implementation.h */ +#ifndef SIMDJSON_HASWELL_IMPLEMENTATION_H +#define SIMDJSON_HASWELL_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL +namespace simdjson { + namespace haswell { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "haswell", + "Intel/AMD AVX2", + internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_IMPLEMENTATION_H +/* end file simdjson/haswell/implementation.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(icelake) +/* including simdjson/icelake/implementation.h: #include "simdjson/icelake/implementation.h" */ +/* begin file simdjson/icelake/implementation.h */ +#ifndef SIMDJSON_ICELAKE_IMPLEMENTATION_H +#define SIMDJSON_ICELAKE_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE +namespace simdjson { + namespace icelake { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation( + "icelake", + "Intel/AMD AVX512", + internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 | internal::instruction_set::AVX512F | internal::instruction_set::AVX512DQ | internal::instruction_set::AVX512CD | internal::instruction_set::AVX512BW | internal::instruction_set::AVX512VL | internal::instruction_set::AVX512VBMI2 + ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_IMPLEMENTATION_H +/* end file simdjson/icelake/implementation.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(ppc64) +/* including simdjson/ppc64/implementation.h: #include "simdjson/ppc64/implementation.h" */ +/* begin file simdjson/ppc64/implementation.h */ +#ifndef SIMDJSON_PPC64_IMPLEMENTATION_H +#define SIMDJSON_PPC64_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { + + /** + * Implementation for ALTIVEC (PPC64). + */ + namespace ppc64 { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() + : simdjson::implementation("ppc64", "PPC64 ALTIVEC", + internal::instruction_set::ALTIVEC) {} + + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, size_t max_length, + std::unique_ptr& dst) + const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, + uint8_t* dst, + size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, + size_t len) const noexcept final; + }; + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_IMPLEMENTATION_H +/* end file simdjson/ppc64/implementation.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(westmere) +/* including simdjson/westmere/implementation.h: #include "simdjson/westmere/implementation.h" */ +/* begin file simdjson/westmere/implementation.h */ +#ifndef SIMDJSON_WESTMERE_IMPLEMENTATION_H +#define SIMDJSON_WESTMERE_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/instruction_set.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + namespace westmere { + + /** + * @private + */ + class implementation final : public simdjson::implementation { + public: + simdjson_inline implementation() : simdjson::implementation("westmere", "Intel/AMD SSE4.2", internal::instruction_set::SSE42 | internal::instruction_set::PCLMULQDQ) {} + simdjson_warn_unused error_code create_dom_parser_implementation( + size_t capacity, + size_t max_length, + std::unique_ptr& dst + ) const noexcept final; + simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; + simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; + }; + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_IMPLEMENTATION_H +/* end file simdjson/westmere/implementation.h */ +#else +#error Unknown SIMDJSON_BUILTIN_IMPLEMENTATION +#endif + +/* undefining SIMDJSON_CONDITIONAL_INCLUDE */ +#undef SIMDJSON_CONDITIONAL_INCLUDE + +namespace simdjson { + /** + * Function which returns a pointer to an implementation matching the "builtin" implementation. + * The builtin implementation is the best statically linked simdjson implementation that can be used by the compiling + * program. If you compile with g++ -march=haswell, this will return the haswell implementation. + * It is handy to be able to check what builtin was used: builtin_implementation()->name(). + */ + const implementation* builtin_implementation(); +} // namespace simdjson + +#endif // SIMDJSON_BUILTIN_IMPLEMENTATION_H +/* end file simdjson/builtin/implementation.h */ + +/* skipped duplicate #include "simdjson/generic/dependencies.h" */ + +/* defining SIMDJSON_CONDITIONAL_INCLUDE */ +#define SIMDJSON_CONDITIONAL_INCLUDE + +#if SIMDJSON_BUILTIN_IMPLEMENTATION_IS(arm64) +/* including simdjson/arm64.h: #include "simdjson/arm64.h" */ +/* begin file simdjson/arm64.h */ +#ifndef SIMDJSON_ARM64_H +#define SIMDJSON_ARM64_H + +/* including simdjson/arm64/begin.h: #include "simdjson/arm64/begin.h" */ +/* begin file simdjson/arm64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "arm64" */ +#define SIMDJSON_IMPLEMENTATION arm64 +/* including simdjson/arm64/base.h: #include "simdjson/arm64/base.h" */ +/* begin file simdjson/arm64/base.h */ +#ifndef SIMDJSON_ARM64_BASE_H +#define SIMDJSON_ARM64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for NEON (ARMv8). + */ namespace arm64 { - inline dom_parser_implementation::dom_parser_implementation() noexcept = default; - inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; - inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + class implementation; - // Leaving these here so they can be inlined if so desired - inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { - if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } - // Stage 1 index output - size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; - structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); - if (!structural_indexes) { _capacity = 0; return MEMALLOC; } - structural_indexes[0] = 0; - n_structural_indexes = 0; - - _capacity = capacity; - return SUCCESS; - } - - inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { - // Stage 2 stacks - open_containers.reset(new (std::nothrow) open_container[max_depth]); - is_array.reset(new (std::nothrow) bool[max_depth]); - if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } - - _max_depth = max_depth; - return SUCCESS; - } + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace } // namespace arm64 } // namespace simdjson -/* end file include/simdjson/generic/dom_parser_implementation.h */ -/* begin file include/simdjson/arm64/intrinsics.h */ + +#endif // SIMDJSON_ARM64_BASE_H +/* end file simdjson/arm64/base.h */ +/* including simdjson/arm64/intrinsics.h: #include "simdjson/arm64/intrinsics.h" */ +/* begin file simdjson/arm64/intrinsics.h */ #ifndef SIMDJSON_ARM64_INTRINSICS_H #define SIMDJSON_ARM64_INTRINSICS_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + // This should be the correct header whether // you use visual studio or other compilers. #include @@ -9962,11 +10530,17 @@ namespace simdjson { static_assert(sizeof(uint8x16_t) <= simdjson::SIMDJSON_PADDING, "insufficient padding for arm64"); #endif // SIMDJSON_ARM64_INTRINSICS_H -/* end file include/simdjson/arm64/intrinsics.h */ -/* begin file include/simdjson/arm64/bitmanipulation.h */ +/* end file simdjson/arm64/intrinsics.h */ +/* including simdjson/arm64/bitmanipulation.h: #include "simdjson/arm64/bitmanipulation.h" */ +/* begin file simdjson/arm64/bitmanipulation.h */ #ifndef SIMDJSON_ARM64_BITMANIPULATION_H #define SIMDJSON_ARM64_BITMANIPULATION_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace arm64 { namespace { @@ -10065,11 +10639,16 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_ARM64_BITMANIPULATION_H -/* end file include/simdjson/arm64/bitmanipulation.h */ -/* begin file include/simdjson/arm64/bitmask.h */ +/* end file simdjson/arm64/bitmanipulation.h */ +/* including simdjson/arm64/bitmask.h: #include "simdjson/arm64/bitmask.h" */ +/* begin file simdjson/arm64/bitmask.h */ #ifndef SIMDJSON_ARM64_BITMASK_H #define SIMDJSON_ARM64_BITMASK_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace arm64 { namespace { @@ -10107,13 +10686,76 @@ namespace simdjson { } // namespace simdjson #endif -/* end file include/simdjson/arm64/bitmask.h */ -/* begin file include/simdjson/arm64/simd.h */ +/* end file simdjson/arm64/bitmask.h */ +/* including simdjson/arm64/numberparsing_defs.h: #include "simdjson/arm64/numberparsing_defs.h" */ +/* begin file simdjson/arm64/numberparsing_defs.h */ +#ifndef SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +#define SIMDJSON_ARM64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if _M_ARM64 +// __umulh requires intrin.h +#include +#endif // _M_ARM64 + +namespace simdjson { + namespace arm64 { + namespace numberparsing { + + // we don't have SSE, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace arm64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +/* end file simdjson/arm64/numberparsing_defs.h */ +/* including simdjson/arm64/simd.h: #include "simdjson/arm64/simd.h" */ +/* begin file simdjson/arm64/simd.h */ #ifndef SIMDJSON_ARM64_SIMD_H #define SIMDJSON_ARM64_SIMD_H -#include - +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { @@ -10125,91 +10767,55 @@ namespace simdjson { // Start of private section with Visual Studio workaround - /** - * make_uint8x16_t initializes a SIMD register (uint8x16_t). - * This is needed because, incredibly, the syntax uint8x16_t x = {1,2,3...} - * is not recognized under Visual Studio! This is a workaround. - * Using a std::initializer_list as a parameter resulted in - * inefficient code. With the current approach, if the parameters are - * compile-time constants, - * GNU GCC compiles it to ldr, the same as uint8x16_t x = {1,2,3...}. - * You should not use this function except for compile-time constants: - * it is not efficient. - */ - simdjson_inline uint8x16_t make_uint8x16_t(uint8_t x1, uint8_t x2, uint8_t x3, uint8_t x4, - uint8_t x5, uint8_t x6, uint8_t x7, uint8_t x8, - uint8_t x9, uint8_t x10, uint8_t x11, uint8_t x12, - uint8_t x13, uint8_t x14, uint8_t x15, uint8_t x16) { - // Doing a load like so end ups generating worse code. - // uint8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, - // x9, x10,x11,x12,x13,x14,x15,x16}; - // return vld1q_u8(array); - uint8x16_t x{}; - // incredibly, Visual Studio does not allow x[0] = x1 - x = vsetq_lane_u8(x1, x, 0); - x = vsetq_lane_u8(x2, x, 1); - x = vsetq_lane_u8(x3, x, 2); - x = vsetq_lane_u8(x4, x, 3); - x = vsetq_lane_u8(x5, x, 4); - x = vsetq_lane_u8(x6, x, 5); - x = vsetq_lane_u8(x7, x, 6); - x = vsetq_lane_u8(x8, x, 7); - x = vsetq_lane_u8(x9, x, 8); - x = vsetq_lane_u8(x10, x, 9); - x = vsetq_lane_u8(x11, x, 10); - x = vsetq_lane_u8(x12, x, 11); - x = vsetq_lane_u8(x13, x, 12); - x = vsetq_lane_u8(x14, x, 13); - x = vsetq_lane_u8(x15, x, 14); - x = vsetq_lane_u8(x16, x, 15); - return x; - } +#ifndef simdjson_make_uint8x16_t +#define simdjson_make_uint8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + uint8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x16_t +#define simdjson_make_int8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + int8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_s8(array); \ + }()) +#endif - simdjson_inline uint8x8_t make_uint8x8_t(uint8_t x1, uint8_t x2, uint8_t x3, uint8_t x4, - uint8_t x5, uint8_t x6, uint8_t x7, uint8_t x8) { - uint8x8_t x{}; - x = vset_lane_u8(x1, x, 0); - x = vset_lane_u8(x2, x, 1); - x = vset_lane_u8(x3, x, 2); - x = vset_lane_u8(x4, x, 3); - x = vset_lane_u8(x5, x, 4); - x = vset_lane_u8(x6, x, 5); - x = vset_lane_u8(x7, x, 6); - x = vset_lane_u8(x8, x, 7); - return x; - } +#ifndef simdjson_make_uint8x8_t +#define simdjson_make_uint8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x8_t +#define simdjson_make_int8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_s8(array); \ + }()) +#endif +#ifndef simdjson_make_uint16x8_t +#define simdjson_make_uint16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_u16(array); \ + }()) +#endif +#ifndef simdjson_make_int16x8_t +#define simdjson_make_int16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_s16(array); \ + }()) +#endif - // We have to do the same work for make_int8x16_t - simdjson_inline int8x16_t make_int8x16_t(int8_t x1, int8_t x2, int8_t x3, int8_t x4, - int8_t x5, int8_t x6, int8_t x7, int8_t x8, - int8_t x9, int8_t x10, int8_t x11, int8_t x12, - int8_t x13, int8_t x14, int8_t x15, int8_t x16) { - // Doing a load like so end ups generating worse code. - // int8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, - // x9, x10,x11,x12,x13,x14,x15,x16}; - // return vld1q_s8(array); - int8x16_t x{}; - // incredibly, Visual Studio does not allow x[0] = x1 - x = vsetq_lane_s8(x1, x, 0); - x = vsetq_lane_s8(x2, x, 1); - x = vsetq_lane_s8(x3, x, 2); - x = vsetq_lane_s8(x4, x, 3); - x = vsetq_lane_s8(x5, x, 4); - x = vsetq_lane_s8(x6, x, 5); - x = vsetq_lane_s8(x7, x, 6); - x = vsetq_lane_s8(x8, x, 7); - x = vsetq_lane_s8(x9, x, 8); - x = vsetq_lane_s8(x10, x, 9); - x = vsetq_lane_s8(x11, x, 10); - x = vsetq_lane_s8(x12, x, 11); - x = vsetq_lane_s8(x13, x, 12); - x = vsetq_lane_s8(x14, x, 13); - x = vsetq_lane_s8(x15, x, 14); - x = vsetq_lane_s8(x16, x, 15); - return x; - } - - // End of private section with Visual Studio workaround +// End of private section with Visual Studio workaround } // namespace #endif // SIMDJSON_REGULAR_VISUAL_STUDIO @@ -10266,7 +10872,7 @@ namespace simdjson { // purposes (cutting it down to uint16_t costs performance in some compilers). simdjson_inline uint32_t to_bitmask() const { #ifdef SIMDJSON_REGULAR_VISUAL_STUDIO - const uint8x16_t bit_mask = make_uint8x16_t(0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + const uint8x16_t bit_mask = simdjson_make_uint8x16_t(0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80); #else const uint8x16_t bit_mask = { 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, @@ -10300,7 +10906,7 @@ namespace simdjson { simdjson_inline simd8( uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 - ) : simd8(make_uint8x16_t( + ) : simd8(simdjson_make_uint8x16_t( v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, v14, v15 )) {} @@ -10391,7 +10997,7 @@ namespace simdjson { uint8x16_t shufmask = vreinterpretq_u8_u64(shufmask64); // we increment by 0x08 the second half of the mask #ifdef SIMDJSON_REGULAR_VISUAL_STUDIO - uint8x16_t inc = make_uint8x16_t(0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); + uint8x16_t inc = simdjson_make_uint8x16_t(0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); #else uint8x16_t inc = { 0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; #endif @@ -10421,7 +11027,7 @@ namespace simdjson { uint8x8_t compactmask2 = vcreate_u8(thintable_epi8[mask2]); // we increment by 0x08 the second half of the mask #ifdef SIMDJSON_REGULAR_VISUAL_STUDIO - uint8x8_t inc = make_uint8x8_t(0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); + uint8x8_t inc = simdjson_make_uint8x8_t(0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); #else uint8x8_t inc = { 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; #endif @@ -10476,7 +11082,7 @@ namespace simdjson { simdjson_inline simd8( int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 - ) : simd8(make_int8x16_t( + ) : simd8(simdjson_make_int8x16_t( v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, v14, v15 )) {} @@ -10594,7 +11200,7 @@ namespace simdjson { simdjson_inline uint64_t to_bitmask() const { #ifdef SIMDJSON_REGULAR_VISUAL_STUDIO - const uint8x16_t bit_mask = make_uint8x16_t( + const uint8x16_t bit_mask = simdjson_make_uint8x16_t( 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 ); @@ -10639,196 +11245,17 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_ARM64_SIMD_H -/* end file include/simdjson/arm64/simd.h */ -/* begin file include/simdjson/generic/jsoncharutils.h */ - -namespace simdjson { - namespace arm64 { - namespace { - namespace jsoncharutils { - - // return non-zero if not a structural or whitespace char - // zero otherwise - simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { - return internal::structural_or_whitespace_negated[c]; - } - - simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { - return internal::structural_or_whitespace[c]; - } - - // returns a value with the high 16 bits set if not valid - // otherwise returns the conversion of the 4 hex digits at src into the bottom - // 16 bits of the 32-bit return register - // - // see - // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ - static inline uint32_t hex_to_u32_nocheck( - const uint8_t* src) { // strictly speaking, static inline is a C-ism - uint32_t v1 = internal::digit_to_val32[630 + src[0]]; - uint32_t v2 = internal::digit_to_val32[420 + src[1]]; - uint32_t v3 = internal::digit_to_val32[210 + src[2]]; - uint32_t v4 = internal::digit_to_val32[0 + src[3]]; - return v1 | v2 | v3 | v4; - } - - // given a code point cp, writes to c - // the utf-8 code, outputting the length in - // bytes, if the length is zero, the code point - // is invalid - // - // This can possibly be made faster using pdep - // and clz and table lookups, but JSON documents - // have few escaped code points, and the following - // function looks cheap. - // - // Note: we assume that surrogates are treated separately - // - simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { - if (cp <= 0x7F) { - c[0] = uint8_t(cp); - return 1; // ascii - } - if (cp <= 0x7FF) { - c[0] = uint8_t((cp >> 6) + 192); - c[1] = uint8_t((cp & 63) + 128); - return 2; // universal plane - // Surrogates are treated elsewhere... - //} //else if (0xd800 <= cp && cp <= 0xdfff) { - // return 0; // surrogates // could put assert here - } - else if (cp <= 0xFFFF) { - c[0] = uint8_t((cp >> 12) + 224); - c[1] = uint8_t(((cp >> 6) & 63) + 128); - c[2] = uint8_t((cp & 63) + 128); - return 3; - } - else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this - // is not needed - c[0] = uint8_t((cp >> 18) + 240); - c[1] = uint8_t(((cp >> 12) & 63) + 128); - c[2] = uint8_t(((cp >> 6) & 63) + 128); - c[3] = uint8_t((cp & 63) + 128); - return 4; - } - // will return 0 when the code point was too large. - return 0; // bad r - } - -#if SIMDJSON_IS_32BITS // _umul128 for x86, arm - // this is a slow emulation routine for 32-bit - // - static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { - return x * (uint64_t)y; - } - static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { - uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); - uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); - uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); - uint64_t adbc_carry = !!(adbc < ad); - uint64_t lo = bd + (adbc << 32); - *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + - (adbc_carry << 32) + !!(lo < bd); - return lo; - } -#endif - - using internal::value128; - - simdjson_inline value128 full_multiplication(uint64_t value1, uint64_t value2) { - value128 answer; -#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS -#ifdef _M_ARM64 - // ARM64 has native support for 64-bit multiplications, no need to emultate - answer.high = __umulh(value1, value2); - answer.low = value1 * value2; -#else - answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 -#endif // _M_ARM64 -#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS - __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; - answer.low = uint64_t(r); - answer.high = uint64_t(r >> 64); -#endif - return answer; - } - - } // namespace jsoncharutils - } // unnamed namespace - } // namespace arm64 -} // namespace simdjson -/* end file include/simdjson/generic/jsoncharutils.h */ -/* begin file include/simdjson/generic/atomparsing.h */ -namespace simdjson { - namespace arm64 { - namespace { - /// @private - namespace atomparsing { - - // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. - // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot - // be certain that the character pointer will be properly aligned. - // You might think that using memcpy makes this function expensive, but you'd be wrong. - // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); - // to the compile-time constant 1936482662. - simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } - - - // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. - // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. - simdjson_warn_unused - simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { - uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) - static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); - std::memcpy(&srcval, src, sizeof(uint32_t)); - return srcval ^ string_to_uint32(atom); - } - - simdjson_warn_unused - simdjson_inline bool is_valid_true_atom(const uint8_t* src) { - return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; - } - - simdjson_warn_unused - simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { - if (len > 4) { return is_valid_true_atom(src); } - else if (len == 4) { return !str4ncmp(src, "true"); } - else { return false; } - } - - simdjson_warn_unused - simdjson_inline bool is_valid_false_atom(const uint8_t* src) { - return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; - } - - simdjson_warn_unused - simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { - if (len > 5) { return is_valid_false_atom(src); } - else if (len == 5) { return !str4ncmp(src + 1, "alse"); } - else { return false; } - } - - simdjson_warn_unused - simdjson_inline bool is_valid_null_atom(const uint8_t* src) { - return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; - } - - simdjson_warn_unused - simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { - if (len > 4) { return is_valid_null_atom(src); } - else if (len == 4) { return !str4ncmp(src, "null"); } - else { return false; } - } - - } // namespace atomparsing - } // unnamed namespace - } // namespace arm64 -} // namespace simdjson -/* end file include/simdjson/generic/atomparsing.h */ -/* begin file include/simdjson/arm64/stringparsing.h */ -#ifndef SIMDJSON_ARM64_STRINGPARSING_H -#define SIMDJSON_ARM64_STRINGPARSING_H +/* end file simdjson/arm64/simd.h */ +/* including simdjson/arm64/stringparsing_defs.h: #include "simdjson/arm64/stringparsing_defs.h" */ +/* begin file simdjson/arm64/stringparsing_defs.h */ +#ifndef SIMDJSON_ARM64_STRINGPARSING_DEFS_H +#define SIMDJSON_ARM64_STRINGPARSING_DEFS_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { @@ -10873,54 +11300,502 @@ namespace simdjson { } // namespace arm64 } // namespace simdjson -#endif // SIMDJSON_ARM64_STRINGPARSING_H -/* end file include/simdjson/arm64/stringparsing.h */ -/* begin file include/simdjson/arm64/numberparsing.h */ -#ifndef SIMDJSON_ARM64_NUMBERPARSING_H -#define SIMDJSON_ARM64_NUMBERPARSING_H +#endif // SIMDJSON_ARM64_STRINGPARSING_DEFS_H +/* end file simdjson/arm64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/arm64/begin.h */ +/* including simdjson/generic/amalgamated.h for arm64: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for arm64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for arm64: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for arm64 */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for arm64 */ +/* including simdjson/generic/jsoncharutils.h for arm64: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for arm64 */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { namespace { + namespace jsoncharutils { - // we don't have SSE, so let us use a scalar function - // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ - static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { - uint64_t val; - std::memcpy(&val, chars, sizeof(uint64_t)); - val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; - val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; - return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); - } + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils } // unnamed namespace } // namespace arm64 } // namespace simdjson -#define SIMDJSON_SWAR_NUMBER_PARSING 1 +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for arm64 */ +/* including simdjson/generic/atomparsing.h for arm64: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H -/* begin file include/simdjson/generic/numberparsing.h */ -#include +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace arm64 { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for arm64 */ +/* including simdjson/generic/dom_parser_implementation.h for arm64: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for arm64 */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace arm64 { - namespace ondemand { - /** - * The type of a JSON number - */ - enum class number_type { - floating_point_number = 1, /// a binary64 number - signed_integer, /// a signed integer that fits in a 64-bit word using two's complement - unsigned_integer /// a positive integer larger or equal to 1<<63 - }; + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container + + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); + + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; + + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; + + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; + + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + namespace arm64 { + + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; } - namespace { - /// @private - namespace numberparsing { + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for arm64 */ +/* including simdjson/generic/implementation_simdjson_result_base.h for arm64: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for arm64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for arm64 */ +/* including simdjson/generic/numberparsing.h for arm64: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for arm64 */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace arm64 { + namespace numberparsing { #ifdef JSON_TEST_NUMBERS #define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) @@ -10934,19 +11809,20 @@ namespace simdjson { #define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) #endif - namespace { - // Convert a mantissa, an exponent and a sign bit into an ieee64 double. - // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). - // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. - simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { - double d; - mantissa &= ~(1ULL << 52); - mantissa |= real_exponent << 52; - mantissa |= ((static_cast(negative)) << 63); - std::memcpy(&d, &mantissa, sizeof(d)); - return d; - } + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; } + // Attempts to compute i * 10^(power) exactly; and if "negative" is // true, negate the result. // This function will only work in some cases, when it does not work, success is @@ -10963,10 +11839,11 @@ namespace simdjson { #endif #if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) // We cannot be certain that x/y is rounded to nearest. - if (0 <= power && power <= 22 && i <= 9007199254740991) { + if (0 <= power && power <= 22 && i <= 9007199254740991) #else - if (-22 <= power && power <= 22 && i <= 9007199254740991) { + if (-22 <= power && power <= 22 && i <= 9007199254740991) #endif + { // convert the integer into a double. This is lossless since // 0 <= i <= 2^53 - 1. d = double(i); @@ -11071,7 +11948,7 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 firstproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index]); + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); // Both i and power_of_five_128[index] have their most significant bit set to 1 which // implies that the either the most or the second most significant bit of the product // is 1. We pack values in this manner for efficiency reasons: it maximizes the use @@ -11092,8 +11969,7 @@ namespace simdjson { // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q // to the desired approximation using one multiplication. Sometimes it does not suffice. // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and - // then we get a better approximation to i * 5^q. In very rare cases, even that - // will not suffice, though it is seemingly very hard to find such a scenario. + // then we get a better approximation to i * 5^q. // // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat // more complicated. @@ -11105,15 +11981,12 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 secondproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); firstproduct.low += secondproduct.high; if (secondproduct.high > firstproduct.low) { firstproduct.high++; } - // At this point, we might need to add at most one to firstproduct, but this - // can only change the value of firstproduct.high if firstproduct.low is maximal. - if (simdjson_unlikely(firstproduct.low == 0xFFFFFFFFFFFFFFFF)) { - // This is very unlikely, but if so, we need to do much more work! - return false; - } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. } uint64_t lower = firstproduct.low; uint64_t upper = firstproduct.high; @@ -11196,7 +12069,7 @@ namespace simdjson { } d = to_double(mantissa, real_exponent, negative); return true; - } + } // We call a fallback floating-point parser that might be slow. Note // it will accept JSON numbers, but the JSON spec. is more restrictive so @@ -11205,7 +12078,7 @@ namespace simdjson { // It will return an error (false) if the parsed number is infinite. // The string parsing itself always succeeds. We know that there is at least // one digit. - static bool parse_float_fallback(const uint8_t * ptr, double* outDouble) { + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); // We do not accept infinite values. @@ -11219,7 +12092,8 @@ namespace simdjson { // to handle that max may be a macro on windows). return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); } - static bool parse_float_fallback(const uint8_t * ptr, const uint8_t * end_ptr, double* outDouble) { + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); // We do not accept infinite values. @@ -11237,7 +12111,7 @@ namespace simdjson { // check quickly whether the next 8 chars are made of digits // at a glance, it looks better than Mula's // http://0x80.pl/articles/swar-digits-validate.html - simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t * chars) { + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { uint64_t val; // this can read up to 7 bytes beyond the buffer size, but we require // SIMDJSON_PADDING of padding @@ -11252,19 +12126,9 @@ namespace simdjson { 0x3333333333333333); } - template - error_code slow_float_parsing(simdjson_unused const uint8_t * src, W writer) { - double d; - if (parse_float_fallback(src, &d)) { - writer.append_double(d); - return SUCCESS; - } - return INVALID_NUMBER(src); - } - template SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later - simdjson_inline bool parse_digit(const uint8_t c, I & i) { + simdjson_inline bool parse_digit(const uint8_t c, I& i) { const uint8_t digit = static_cast(c - '0'); if (digit > 9) { return false; @@ -11274,7 +12138,7 @@ namespace simdjson { return true; } - simdjson_inline error_code parse_decimal(simdjson_unused const uint8_t* const src, const uint8_t * &p, uint64_t & i, int64_t & exponent) { + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { // we continue with the fiction that we have an integer. If the // floating point number is representable as x * 10^z for some integer // z that fits in 53 bits, then we will be able to convert back the @@ -11302,7 +12166,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t * &p, int64_t & exponent) { + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { // Exp Sign: -123.456e[-]78 bool neg_exp = ('-' == *p); if (neg_exp || '+' == *p) { p++; } // Skip + as well @@ -11353,7 +12217,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline size_t significant_digits(const uint8_t * start_digits, size_t digit_count) { + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { // It is possible that the integer had an overflow. // We have to handle the case where we have 0.0000somenumber. const uint8_t* start = start_digits; @@ -11362,79 +12226,93 @@ namespace simdjson { return digit_count - size_t(start - start_digits); } - template - simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t * start_digits, size_t digit_count, int64_t exponent, W & writer) { - // If we frequently had to deal with long strings of digits, - // we could extend our code by using a 128-bit integer instead - // of a 64-bit integer. However, this is uncommon in practice. - // - // 9999999999999999999 < 2**64 so we can accommodate 19 digits. - // If we have a decimal separator, then digit_count - 1 is the number of digits, but we - // may not have a decimal separator! - if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { - // Ok, chances are good that we had an overflow! - // this is almost never going to get called!!! - // we start anew, going slowly!!! - // This will happen in the following examples: - // 10000000000000000000000000000000000000000000e+308 - // 3.1415926535897932384626433832795028841971693993751 - // - // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens - // because slow_float_parsing is a non-inlined function. If we passed our writer reference to - // it, it would force it to be stored in memory, preventing the compiler from picking it apart - // and putting into registers. i.e. if we pass it as reference, it gets slow. - // This is what forces the skip_double, as well. - error_code error = slow_float_parsing(src, writer); - writer.skip_double(); - return error; - } - // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other - // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 - // To future reader: we'd love if someone found a better way, or at least could explain this result! - if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { - // - // Important: smallest_power is such that it leads to a zero value. - // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero - // so something x 10^-343 goes to zero, but not so with something x 10^-342. - static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); - // - if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { - // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero - WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); - return SUCCESS; - } - else { // (exponent > largest_power) and (i != 0) - // We have, for sure, an infinite value and simdjson refuses to parse infinite values. - return INVALID_NUMBER(src); - } - } - double d; - if (!compute_float_64(exponent, i, negative, d)) { - // we are almost never going to get here. - if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } - } - WRITE_DOUBLE(d, src, writer); + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); return SUCCESS; } + return INVALID_NUMBER(src); + } - // for performance analysis, it is sometimes useful to skip parsing + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing #ifdef SIMDJSON_SKIPNUMBERPARSING - template - simdjson_inline error_code parse_number(const uint8_t* const, W & writer) { - writer.append_s64(0); // always write zero - return SUCCESS; // always succeeds - } + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t * src) noexcept { return ondemand::number_type::signed_integer; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } #else // parse the number at src @@ -11446,9 +12324,308 @@ namespace simdjson { // content and append a space before calling this function. // // Our objective is accurate parsing (ULP of 0) at high speed. - template - simdjson_inline error_code parse_number(const uint8_t* const src, W & writer) { + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { // // Check for minus sign // @@ -11466,857 +12643,563 @@ namespace simdjson { // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. // Optimization note: size_t is expected to be unsigned. size_t digit_count = size_t(p - start_digits); - if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } - - // - // Handle floats if there is a . or e (or both) - // - int64_t exponent = 0; - bool is_float = false; - if ('.' == *p) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_decimal(src, p, i, exponent)); - digit_count = int(p - start_digits); // used later to guard against overflows - } - if (('e' == *p) || ('E' == *p)) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_exponent(src, p, exponent)); - } - if (is_float) { - const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); - SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); - if (dirty_end) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // The longest negative 64-bit number is 19 digits. - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - size_t longest_digit_count = negative ? 19 : 20; - if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } - if (digit_count == longest_digit_count) { - if (negative) { - // Anything negative above INT64_MAX+1 is invalid - if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } - WRITE_INTEGER(~i + 1, src, writer); - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - } - else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } - } - - // Write unsigned if it doesn't fit in a signed integer. - if (i > uint64_t(INT64_MAX)) { - WRITE_UNSIGNED(i, src, writer); - } - else { - WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); - } - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; } - // Inlineable functions - namespace { + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); - // This table can be used to characterize the final character of an integer - // string. For JSON structural character and allowable white space characters, - // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise - // we return NUMBER_ERROR. - // Optimization note: we could easily reduce the size of the table by half (to 128) - // at the cost of an extra branch. - // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): - static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } - const uint8_t integer_string_finisher[256] = { - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR }; + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - - return i; + } + else { + overflow = p - src > 19; } + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // Parse any number from 0 to 18,446,744,073,709,551,615 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + exponent += exp_neg ? 0 - exp : exp; } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { - const uint8_t* p = src + 1; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*p != '"') { return NUMBER_ERROR; } + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - // Note: we use src[1] and not src[0] because src[0] is the quote character in this - // instance. - if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; } + return d; + } - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { - // - // Check for minus sign - // - if (src == src_end) { return NUMBER_ERROR; } - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = src; - uint64_t i = 0; - while (parse_digit(*src, i)) { src++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(src - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*src)) { - // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*src != '"') { return NUMBER_ERROR; } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; } } - else { - overflow = p - src > 19; + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; + } + else { + overflow = p - src > 19; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { - return (*src == '-'); - } - - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } - return false; - } - - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { - // We have an integer. - // If the number is negative and valid, it must be a signed integer. - if (negative) { return ondemand::number_type::signed_integer; } - // We want values larger or equal to 9223372036854775808 to be unsigned - // integers, and the other values to be signed integers. - int digit_count = int(p - src); - if (digit_count >= 19) { - const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); - if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { - return ondemand::number_type::unsigned_integer; - } - } - return ondemand::number_type::signed_integer; - } - // Hopefully, we have 'e' or 'E' or '.'. - return ondemand::number_type::floating_point_number; - } - - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { - if (src == src_end) { return NUMBER_ERROR; } - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; if (p == src_end) { return NUMBER_ERROR; } - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while ((p != src_end) && parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely((p != src_end) && (*p == '.'))) { - p++; - const uint8_t* start_decimal_digits = p; - if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if ((p != src_end) && (*p == 'e' || *p == 'E')) { - p++; - if (p == src_end) { return NUMBER_ERROR; } - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while ((p != src_end) && parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { - return NUMBER_ERROR; - } - return d; + exponent += exp_neg ? 0 - exp : exp; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + exponent = -(p - start_decimal_digits); - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (*p != '"') { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; } - } //namespace {} + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace #endif // SIMDJSON_SKIPNUMBERPARSING - } // namespace numberparsing - } // unnamed namespace - } // namespace arm64 - } // namespace simdjson - /* end file include/simdjson/generic/numberparsing.h */ + } // namespace numberparsing -#endif // SIMDJSON_ARM64_NUMBERPARSING_H -/* end file include/simdjson/arm64/numberparsing.h */ -/* begin file include/simdjson/arm64/end.h */ -/* end file include/simdjson/arm64/end.h */ + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } -#endif // SIMDJSON_IMPLEMENTATION_ARM64 + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for arm64 */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for arm64: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for arm64 */ +/* end file simdjson/generic/amalgamated.h for arm64 */ +/* including simdjson/arm64/end.h: #include "simdjson/arm64/end.h" */ +/* begin file simdjson/arm64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "arm64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/arm64/end.h */ #endif // SIMDJSON_ARM64_H -/* end file include/simdjson/arm64.h */ -/* begin file include/simdjson/fallback.h */ +/* end file simdjson/arm64.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(fallback) +/* including simdjson/fallback.h: #include "simdjson/fallback.h" */ +/* begin file simdjson/fallback.h */ #ifndef SIMDJSON_FALLBACK_H #define SIMDJSON_FALLBACK_H +/* including simdjson/fallback/begin.h: #include "simdjson/fallback/begin.h" */ +/* begin file simdjson/fallback/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "fallback" */ +#define SIMDJSON_IMPLEMENTATION fallback +/* including simdjson/fallback/base.h: #include "simdjson/fallback/base.h" */ +/* begin file simdjson/fallback/base.h */ +#ifndef SIMDJSON_FALLBACK_BASE_H +#define SIMDJSON_FALLBACK_BASE_H -#if SIMDJSON_IMPLEMENTATION_FALLBACK +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { /** * Fallback implementation (runs on any machine). */ namespace fallback { - } // namespace fallback -} // namespace simdjson -/* begin file include/simdjson/fallback/implementation.h */ -#ifndef SIMDJSON_FALLBACK_IMPLEMENTATION_H -#define SIMDJSON_FALLBACK_IMPLEMENTATION_H - - -namespace simdjson { - namespace fallback { - - namespace { - using namespace simdjson; - using namespace simdjson::dom; - } - - /** - * @private - */ - class implementation final : public simdjson::implementation { - public: - simdjson_inline implementation() : simdjson::implementation( - "fallback", - "Generic fallback implementation", - 0 - ) {} - simdjson_warn_unused error_code create_dom_parser_implementation( - size_t capacity, - size_t max_length, - std::unique_ptr& dst - ) const noexcept final; - simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; - simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; - }; + class implementation; } // namespace fallback } // namespace simdjson -#endif // SIMDJSON_FALLBACK_IMPLEMENTATION_H -/* end file include/simdjson/fallback/implementation.h */ - -/* begin file include/simdjson/fallback/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "fallback" -// #define SIMDJSON_IMPLEMENTATION fallback -/* end file include/simdjson/fallback/begin.h */ - -// Declarations -/* begin file include/simdjson/generic/dom_parser_implementation.h */ - -namespace simdjson { - namespace fallback { - - // expectation: sizeof(open_container) = 64/8. - struct open_container { - uint32_t tape_index; // where, on the tape, does the scope ([,{) begins - uint32_t count; // how many elements in the scope - }; // struct open_container - - static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); - - class dom_parser_implementation final : public internal::dom_parser_implementation { - public: - /** Tape location of each open { or [ */ - std::unique_ptr open_containers{}; - /** Whether each open container is a [ or { */ - std::unique_ptr is_array{}; - /** Buffer passed to stage 1 */ - const uint8_t* buf{}; - /** Length passed to stage 1 */ - size_t len{ 0 }; - /** Document passed to stage 2 */ - dom::document* doc{}; - - inline dom_parser_implementation() noexcept; - inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; - inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; - dom_parser_implementation(const dom_parser_implementation&) = delete; - dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; - - simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; - simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; - simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; - simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; - inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; - inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; - private: - simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); - - }; - - } // namespace fallback -} // namespace simdjson - -namespace simdjson { - namespace fallback { - - inline dom_parser_implementation::dom_parser_implementation() noexcept = default; - inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; - inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; - - // Leaving these here so they can be inlined if so desired - inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { - if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } - // Stage 1 index output - size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; - structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); - if (!structural_indexes) { _capacity = 0; return MEMALLOC; } - structural_indexes[0] = 0; - n_structural_indexes = 0; - - _capacity = capacity; - return SUCCESS; - } - - inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { - // Stage 2 stacks - open_containers.reset(new (std::nothrow) open_container[max_depth]); - is_array.reset(new (std::nothrow) bool[max_depth]); - if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } - - _max_depth = max_depth; - return SUCCESS; - } - - } // namespace fallback -} // namespace simdjson -/* end file include/simdjson/generic/dom_parser_implementation.h */ -/* begin file include/simdjson/fallback/bitmanipulation.h */ +#endif // SIMDJSON_FALLBACK_BASE_H +/* end file simdjson/fallback/base.h */ +/* including simdjson/fallback/bitmanipulation.h: #include "simdjson/fallback/bitmanipulation.h" */ +/* begin file simdjson/fallback/bitmanipulation.h */ #ifndef SIMDJSON_FALLBACK_BITMANIPULATION_H #define SIMDJSON_FALLBACK_BITMANIPULATION_H -#include +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace fallback { @@ -12359,8 +13242,195 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_FALLBACK_BITMANIPULATION_H -/* end file include/simdjson/fallback/bitmanipulation.h */ -/* begin file include/simdjson/generic/jsoncharutils.h */ +/* end file simdjson/fallback/bitmanipulation.h */ +/* including simdjson/fallback/stringparsing_defs.h: #include "simdjson/fallback/stringparsing_defs.h" */ +/* begin file simdjson/fallback/stringparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +#define SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 1; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return c == '"'; } + simdjson_inline bool has_backslash() { return c == '\\'; } + simdjson_inline int quote_index() { return c == '"' ? 0 : 1; } + simdjson_inline int backslash_index() { return c == '\\' ? 0 : 1; } + + uint8_t c; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // store to dest unconditionally - we can overwrite the bits we don't like later + dst[0] = src[0]; + return { src[0] }; + } + + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +/* end file simdjson/fallback/stringparsing_defs.h */ +/* including simdjson/fallback/numberparsing_defs.h: #include "simdjson/fallback/numberparsing_defs.h" */ +/* begin file simdjson/fallback/numberparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +#define SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#ifdef JSON_TEST_NUMBERS // for unit testing +void found_invalid_number(const uint8_t* buf); +void found_integer(int64_t result, const uint8_t* buf); +void found_unsigned_integer(uint64_t result, const uint8_t* buf); +void found_float(double result, const uint8_t* buf); +#endif + +namespace simdjson { + namespace fallback { + namespace numberparsing { + + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const char* chars) { + uint64_t val; + memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + return parse_eight_digits_unrolled(reinterpret_cast(chars)); + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace fallback +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +/* end file simdjson/fallback/numberparsing_defs.h */ +/* end file simdjson/fallback/begin.h */ +/* including simdjson/generic/amalgamated.h for fallback: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for fallback */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for fallback: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for fallback */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for fallback */ +/* including simdjson/generic/jsoncharutils.h for fallback: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for fallback */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace fallback { @@ -12453,32 +13523,25 @@ namespace simdjson { } #endif - using internal::value128; - - simdjson_inline value128 full_multiplication(uint64_t value1, uint64_t value2) { - value128 answer; -#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS -#ifdef _M_ARM64 - // ARM64 has native support for 64-bit multiplications, no need to emultate - answer.high = __umulh(value1, value2); - answer.low = value1 * value2; -#else - answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 -#endif // _M_ARM64 -#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS - __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; - answer.low = uint64_t(r); - answer.high = uint64_t(r >> 64); -#endif - return answer; - } - } // namespace jsoncharutils } // unnamed namespace } // namespace fallback } // namespace simdjson -/* end file include/simdjson/generic/jsoncharutils.h */ -/* begin file include/simdjson/generic/atomparsing.h */ + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for fallback */ +/* including simdjson/generic/atomparsing.h for fallback: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for fallback */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + namespace simdjson { namespace fallback { namespace { @@ -12544,1480 +13607,21 @@ namespace simdjson { } // unnamed namespace } // namespace fallback } // namespace simdjson -/* end file include/simdjson/generic/atomparsing.h */ -/* begin file include/simdjson/fallback/stringparsing.h */ -#ifndef SIMDJSON_FALLBACK_STRINGPARSING_H -#define SIMDJSON_FALLBACK_STRINGPARSING_H +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for fallback */ +/* including simdjson/generic/dom_parser_implementation.h for fallback: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for fallback */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace fallback { - namespace { - - // Holds backslashes and quotes locations. - struct backslash_and_quote { - public: - static constexpr uint32_t BYTES_PROCESSED = 1; - simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); - - simdjson_inline bool has_quote_first() { return c == '"'; } - simdjson_inline bool has_backslash() { return c == '\\'; } - simdjson_inline int quote_index() { return c == '"' ? 0 : 1; } - simdjson_inline int backslash_index() { return c == '\\' ? 0 : 1; } - - uint8_t c; - }; // struct backslash_and_quote - - simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { - // store to dest unconditionally - we can overwrite the bits we don't like later - dst[0] = src[0]; - return { src[0] }; - } - - } // unnamed namespace - } // namespace fallback -} // namespace simdjson - -#endif // SIMDJSON_FALLBACK_STRINGPARSING_H -/* end file include/simdjson/fallback/stringparsing.h */ -/* begin file include/simdjson/fallback/numberparsing.h */ -#ifndef SIMDJSON_FALLBACK_NUMBERPARSING_H -#define SIMDJSON_FALLBACK_NUMBERPARSING_H - -#ifdef JSON_TEST_NUMBERS // for unit testing -void found_invalid_number(const uint8_t* buf); -void found_integer(int64_t result, const uint8_t* buf); -void found_unsigned_integer(uint64_t result, const uint8_t* buf); -void found_float(double result, const uint8_t* buf); -#endif - -namespace simdjson { - namespace fallback { - namespace { - // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ - static simdjson_inline uint32_t parse_eight_digits_unrolled(const char* chars) { - uint64_t val; - memcpy(&val, chars, sizeof(uint64_t)); - val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; - val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; - return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); - } - static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { - return parse_eight_digits_unrolled(reinterpret_cast(chars)); - } - - } // unnamed namespace - } // namespace fallback -} // namespace simdjson - -#define SIMDJSON_SWAR_NUMBER_PARSING 1 - -/* begin file include/simdjson/generic/numberparsing.h */ -#include - -namespace simdjson { - namespace fallback { - - namespace ondemand { - /** - * The type of a JSON number - */ - enum class number_type { - floating_point_number = 1, /// a binary64 number - signed_integer, /// a signed integer that fits in a 64-bit word using two's complement - unsigned_integer /// a positive integer larger or equal to 1<<63 - }; - } - - namespace { - /// @private - namespace numberparsing { - - - -#ifdef JSON_TEST_NUMBERS -#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) -#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) -#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) -#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) -#else -#define INVALID_NUMBER(SRC) (NUMBER_ERROR) -#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) -#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) -#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) -#endif - - namespace { - // Convert a mantissa, an exponent and a sign bit into an ieee64 double. - // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). - // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. - simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { - double d; - mantissa &= ~(1ULL << 52); - mantissa |= real_exponent << 52; - mantissa |= ((static_cast(negative)) << 63); - std::memcpy(&d, &mantissa, sizeof(d)); - return d; - } - } - // Attempts to compute i * 10^(power) exactly; and if "negative" is - // true, negate the result. - // This function will only work in some cases, when it does not work, success is - // set to false. This should work *most of the time* (like 99% of the time). - // We assume that power is in the [smallest_power, - // largest_power] interval: the caller is responsible for this check. - simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { - // we start with a fast path - // It was described in - // Clinger WD. How to read floating point numbers accurately. - // ACM SIGPLAN Notices. 1990 -#ifndef FLT_EVAL_METHOD -#error "FLT_EVAL_METHOD should be defined, please include cfloat." -#endif -#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) - // We cannot be certain that x/y is rounded to nearest. - if (0 <= power && power <= 22 && i <= 9007199254740991) { -#else - if (-22 <= power && power <= 22 && i <= 9007199254740991) { -#endif - // convert the integer into a double. This is lossless since - // 0 <= i <= 2^53 - 1. - d = double(i); - // - // The general idea is as follows. - // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then - // 1) Both s and p can be represented exactly as 64-bit floating-point - // values - // (binary64). - // 2) Because s and p can be represented exactly as floating-point values, - // then s * p - // and s / p will produce correctly rounded values. - // - if (power < 0) { - d = d / simdjson::internal::power_of_ten[-power]; - } - else { - d = d * simdjson::internal::power_of_ten[power]; - } - if (negative) { - d = -d; - } - return true; - } - // When 22 < power && power < 22 + 16, we could - // hope for another, secondary fast path. It was - // described by David M. Gay in "Correctly rounded - // binary-decimal and decimal-binary conversions." (1990) - // If you need to compute i * 10^(22 + x) for x < 16, - // first compute i * 10^x, if you know that result is exact - // (e.g., when i * 10^x < 2^53), - // then you can still proceed and do (i * 10^x) * 10^22. - // Is this worth your time? - // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) - // for this second fast path to work. - // If you you have 22 < power *and* power < 22 + 16, and then you - // optimistically compute "i * 10^(x-22)", there is still a chance that you - // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of - // this optimization maybe less common than we would like. Source: - // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ - // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html - - // The fast path has now failed, so we are failing back on the slower path. - - // In the slow path, we need to adjust i so that it is > 1<<63 which is always - // possible, except if i == 0, so we handle i == 0 separately. - if (i == 0) { - d = negative ? -0.0 : 0.0; - return true; - } - - - // The exponent is 1024 + 63 + power - // + floor(log(5**power)/log(2)). - // The 1024 comes from the ieee64 standard. - // The 63 comes from the fact that we use a 64-bit word. - // - // Computing floor(log(5**power)/log(2)) could be - // slow. Instead we use a fast function. - // - // For power in (-400,350), we have that - // (((152170 + 65536) * power ) >> 16); - // is equal to - // floor(log(5**power)/log(2)) + power when power >= 0 - // and it is equal to - // ceil(log(5**-power)/log(2)) + power when power < 0 - // - // The 65536 is (1<<16) and corresponds to - // (65536 * power) >> 16 ---> power - // - // ((152170 * power ) >> 16) is equal to - // floor(log(5**power)/log(2)) - // - // Note that this is not magic: 152170/(1<<16) is - // approximatively equal to log(5)/log(2). - // The 1<<16 value is a power of two; we could use a - // larger power of 2 if we wanted to. - // - int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; - - - // We want the most significant bit of i to be 1. Shift if needed. - int lz = leading_zeroes(i); - i <<= lz; - - - // We are going to need to do some 64-bit arithmetic to get a precise product. - // We use a table lookup approach. - // It is safe because - // power >= smallest_power - // and power <= largest_power - // We recover the mantissa of the power, it has a leading 1. It is always - // rounded down. - // - // We want the most significant 64 bits of the product. We know - // this will be non-zero because the most significant bit of i is - // 1. - const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); - // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) - // - // The full_multiplication function computes the 128-bit product of two 64-bit words - // with a returned value of type value128 with a "low component" corresponding to the - // 64-bit least significant bits of the product and with a "high component" corresponding - // to the 64-bit most significant bits of the product. - simdjson::internal::value128 firstproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index]); - // Both i and power_of_five_128[index] have their most significant bit set to 1 which - // implies that the either the most or the second most significant bit of the product - // is 1. We pack values in this manner for efficiency reasons: it maximizes the use - // we make of the product. It also makes it easy to reason about the product: there - // is 0 or 1 leading zero in the product. - - // Unless the least significant 9 bits of the high (64-bit) part of the full - // product are all 1s, then we know that the most significant 55 bits are - // exact and no further work is needed. Having 55 bits is necessary because - // we need 53 bits for the mantissa but we have to have one rounding bit and - // we can waste a bit if the most significant bit of the product is zero. - if ((firstproduct.high & 0x1FF) == 0x1FF) { - // We want to compute i * 5^q, but only care about the top 55 bits at most. - // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing - // the full computation is wasteful. So we do what is called a "truncated - // multiplication". - // We take the most significant 64-bits, and we put them in - // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q - // to the desired approximation using one multiplication. Sometimes it does not suffice. - // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and - // then we get a better approximation to i * 5^q. In very rare cases, even that - // will not suffice, though it is seemingly very hard to find such a scenario. - // - // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat - // more complicated. - // - // There is an extra layer of complexity in that we need more than 55 bits of - // accuracy in the round-to-even scenario. - // - // The full_multiplication function computes the 128-bit product of two 64-bit words - // with a returned value of type value128 with a "low component" corresponding to the - // 64-bit least significant bits of the product and with a "high component" corresponding - // to the 64-bit most significant bits of the product. - simdjson::internal::value128 secondproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); - firstproduct.low += secondproduct.high; - if (secondproduct.high > firstproduct.low) { firstproduct.high++; } - // At this point, we might need to add at most one to firstproduct, but this - // can only change the value of firstproduct.high if firstproduct.low is maximal. - if (simdjson_unlikely(firstproduct.low == 0xFFFFFFFFFFFFFFFF)) { - // This is very unlikely, but if so, we need to do much more work! - return false; - } - } - uint64_t lower = firstproduct.low; - uint64_t upper = firstproduct.high; - // The final mantissa should be 53 bits with a leading 1. - // We shift it so that it occupies 54 bits with a leading 1. - /////// - uint64_t upperbit = upper >> 63; - uint64_t mantissa = upper >> (upperbit + 9); - lz += int(1 ^ upperbit); - - // Here we have mantissa < (1<<54). - int64_t real_exponent = exponent - lz; - if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? - // Here have that real_exponent <= 0 so -real_exponent >= 0 - if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. - d = negative ? -0.0 : 0.0; - return true; - } - // next line is safe because -real_exponent + 1 < 0 - mantissa >>= -real_exponent + 1; - // Thankfully, we can't have both "round-to-even" and subnormals because - // "round-to-even" only occurs for powers close to 0. - mantissa += (mantissa & 1); // round up - mantissa >>= 1; - // There is a weird scenario where we don't have a subnormal but just. - // Suppose we start with 2.2250738585072013e-308, we end up - // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal - // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round - // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer - // subnormal, but we can only know this after rounding. - // So we only declare a subnormal if we are smaller than the threshold. - real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; - d = to_double(mantissa, real_exponent, negative); - return true; - } - // We have to round to even. The "to even" part - // is only a problem when we are right in between two floats - // which we guard against. - // If we have lots of trailing zeros, we may fall right between two - // floating-point values. - // - // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] - // times a power of two. That is, it is right between a number with binary significand - // m and another number with binary significand m+1; and it must be the case - // that it cannot be represented by a float itself. - // - // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. - // Recall that 10^q = 5^q * 2^q. - // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that - // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. - // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so - // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have - // 2^{53} x 5^{-q} < 2^{64}. - // Hence we have 5^{-q} < 2^{11}$ or q>= -4. - // - // We require lower <= 1 and not lower == 0 because we could not prove that - // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. - if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { - if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { - mantissa &= ~1; // flip it so that we do not round up - } - } - - mantissa += mantissa & 1; - mantissa >>= 1; - - // Here we have mantissa < (1<<53), unless there was an overflow - if (mantissa >= (1ULL << 53)) { - ////////// - // This will happen when parsing values such as 7.2057594037927933e+16 - //////// - mantissa = (1ULL << 52); - real_exponent++; - } - mantissa &= ~(1ULL << 52); - // we have to check that real_exponent is in range, otherwise we bail out - if (simdjson_unlikely(real_exponent > 2046)) { - // We have an infinite value!!! We could actually throw an error here if we could. - return false; - } - d = to_double(mantissa, real_exponent, negative); - return true; - } - - // We call a fallback floating-point parser that might be slow. Note - // it will accept JSON numbers, but the JSON spec. is more restrictive so - // before you call parse_float_fallback, you need to have validated the input - // string with the JSON grammar. - // It will return an error (false) if the parsed number is infinite. - // The string parsing itself always succeeds. We know that there is at least - // one digit. - static bool parse_float_fallback(const uint8_t * ptr, double* outDouble) { - *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); - // We do not accept infinite values. - - // Detecting finite values in a portable manner is ridiculously hard, ideally - // we would want to do: - // return !std::isfinite(*outDouble); - // but that mysteriously fails under legacy/old libc++ libraries, see - // https://github.com/simdjson/simdjson/issues/1286 - // - // Therefore, fall back to this solution (the extra parens are there - // to handle that max may be a macro on windows). - return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); - } - static bool parse_float_fallback(const uint8_t * ptr, const uint8_t * end_ptr, double* outDouble) { - *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); - // We do not accept infinite values. - - // Detecting finite values in a portable manner is ridiculously hard, ideally - // we would want to do: - // return !std::isfinite(*outDouble); - // but that mysteriously fails under legacy/old libc++ libraries, see - // https://github.com/simdjson/simdjson/issues/1286 - // - // Therefore, fall back to this solution (the extra parens are there - // to handle that max may be a macro on windows). - return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); - } - - // check quickly whether the next 8 chars are made of digits - // at a glance, it looks better than Mula's - // http://0x80.pl/articles/swar-digits-validate.html - simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t * chars) { - uint64_t val; - // this can read up to 7 bytes beyond the buffer size, but we require - // SIMDJSON_PADDING of padding - static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); - std::memcpy(&val, chars, 8); - // a branchy method might be faster: - // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) - // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == - // 0x3030303030303030); - return (((val & 0xF0F0F0F0F0F0F0F0) | - (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == - 0x3333333333333333); - } - - template - error_code slow_float_parsing(simdjson_unused const uint8_t * src, W writer) { - double d; - if (parse_float_fallback(src, &d)) { - writer.append_double(d); - return SUCCESS; - } - return INVALID_NUMBER(src); - } - - template - SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later - simdjson_inline bool parse_digit(const uint8_t c, I & i) { - const uint8_t digit = static_cast(c - '0'); - if (digit > 9) { - return false; - } - // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication - i = 10 * i + digit; // might overflow, we will handle the overflow later - return true; - } - - simdjson_inline error_code parse_decimal(simdjson_unused const uint8_t* const src, const uint8_t * &p, uint64_t & i, int64_t & exponent) { - // we continue with the fiction that we have an integer. If the - // floating point number is representable as x * 10^z for some integer - // z that fits in 53 bits, then we will be able to convert back the - // the integer into a float in a lossless manner. - const uint8_t* const first_after_period = p; - -#ifdef SIMDJSON_SWAR_NUMBER_PARSING -#if SIMDJSON_SWAR_NUMBER_PARSING - // this helps if we have lots of decimals! - // this turns out to be frequent enough. - if (is_made_of_eight_digits_fast(p)) { - i = i * 100000000 + parse_eight_digits_unrolled(p); - p += 8; - } -#endif // SIMDJSON_SWAR_NUMBER_PARSING -#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING - // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) - if (parse_digit(*p, i)) { ++p; } - while (parse_digit(*p, i)) { p++; } - exponent = first_after_period - p; - // Decimal without digits (123.) is illegal - if (exponent == 0) { - return INVALID_NUMBER(src); - } - return SUCCESS; - } - - simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t * &p, int64_t & exponent) { - // Exp Sign: -123.456e[-]78 - bool neg_exp = ('-' == *p); - if (neg_exp || '+' == *p) { p++; } // Skip + as well - - // Exponent: -123.456e-[78] - auto start_exp = p; - int64_t exp_number = 0; - while (parse_digit(*p, exp_number)) { ++p; } - // It is possible for parse_digit to overflow. - // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. - // Thus we *must* check for possible overflow before we negate exp_number. - - // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into - // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may - // not oblige and may, in fact, generate two distinct paths in any case. It might be - // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off - // instructions for a simdjson_likely branch, an unconclusive gain. - - // If there were no digits, it's an error. - if (simdjson_unlikely(p == start_exp)) { - return INVALID_NUMBER(src); - } - // We have a valid positive exponent in exp_number at this point, except that - // it may have overflowed. - - // If there were more than 18 digits, we may have overflowed the integer. We have to do - // something!!!! - if (simdjson_unlikely(p > start_exp + 18)) { - // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow - while (*start_exp == '0') { start_exp++; } - // 19 digits could overflow int64_t and is kind of absurd anyway. We don't - // support exponents smaller than -999,999,999,999,999,999 and bigger - // than 999,999,999,999,999,999. - // We can truncate. - // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before - // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could - // truncate at 324. - // Note that there is no reason to fail per se at this point in time. - // E.g., 0e999999999999999999999 is a fine number. - if (p > start_exp + 18) { exp_number = 999999999999999999; } - } - // At this point, we know that exp_number is a sane, positive, signed integer. - // It is <= 999,999,999,999,999,999. As long as 'exponent' is in - // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' - // is bounded in magnitude by the size of the JSON input, we are fine in this universe. - // To sum it up: the next line should never overflow. - exponent += (neg_exp ? -exp_number : exp_number); - return SUCCESS; - } - - simdjson_inline size_t significant_digits(const uint8_t * start_digits, size_t digit_count) { - // It is possible that the integer had an overflow. - // We have to handle the case where we have 0.0000somenumber. - const uint8_t* start = start_digits; - while ((*start == '0') || (*start == '.')) { ++start; } - // we over-decrement by one when there is a '.' - return digit_count - size_t(start - start_digits); - } - - template - simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t * start_digits, size_t digit_count, int64_t exponent, W & writer) { - // If we frequently had to deal with long strings of digits, - // we could extend our code by using a 128-bit integer instead - // of a 64-bit integer. However, this is uncommon in practice. - // - // 9999999999999999999 < 2**64 so we can accommodate 19 digits. - // If we have a decimal separator, then digit_count - 1 is the number of digits, but we - // may not have a decimal separator! - if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { - // Ok, chances are good that we had an overflow! - // this is almost never going to get called!!! - // we start anew, going slowly!!! - // This will happen in the following examples: - // 10000000000000000000000000000000000000000000e+308 - // 3.1415926535897932384626433832795028841971693993751 - // - // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens - // because slow_float_parsing is a non-inlined function. If we passed our writer reference to - // it, it would force it to be stored in memory, preventing the compiler from picking it apart - // and putting into registers. i.e. if we pass it as reference, it gets slow. - // This is what forces the skip_double, as well. - error_code error = slow_float_parsing(src, writer); - writer.skip_double(); - return error; - } - // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other - // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 - // To future reader: we'd love if someone found a better way, or at least could explain this result! - if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { - // - // Important: smallest_power is such that it leads to a zero value. - // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero - // so something x 10^-343 goes to zero, but not so with something x 10^-342. - static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); - // - if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { - // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero - WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); - return SUCCESS; - } - else { // (exponent > largest_power) and (i != 0) - // We have, for sure, an infinite value and simdjson refuses to parse infinite values. - return INVALID_NUMBER(src); - } - } - double d; - if (!compute_float_64(exponent, i, negative, d)) { - // we are almost never going to get here. - if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } - } - WRITE_DOUBLE(d, src, writer); - return SUCCESS; - } - - // for performance analysis, it is sometimes useful to skip parsing -#ifdef SIMDJSON_SKIPNUMBERPARSING - - template - simdjson_inline error_code parse_number(const uint8_t* const, W & writer) { - writer.append_s64(0); // always write zero - return SUCCESS; // always succeeds - } - - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t * src) noexcept { return ondemand::number_type::signed_integer; } -#else - -// parse the number at src -// define JSON_TEST_NUMBERS for unit testing -// -// It is assumed that the number is followed by a structural ({,},],[) character -// or a white space character. If that is not the case (e.g., when the JSON -// document is made of a single number), then it is necessary to copy the -// content and append a space before calling this function. -// -// Our objective is accurate parsing (ULP of 0) at high speed. - template - simdjson_inline error_code parse_number(const uint8_t* const src, W & writer) { - - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } - - // - // Handle floats if there is a . or e (or both) - // - int64_t exponent = 0; - bool is_float = false; - if ('.' == *p) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_decimal(src, p, i, exponent)); - digit_count = int(p - start_digits); // used later to guard against overflows - } - if (('e' == *p) || ('E' == *p)) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_exponent(src, p, exponent)); - } - if (is_float) { - const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); - SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); - if (dirty_end) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // The longest negative 64-bit number is 19 digits. - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - size_t longest_digit_count = negative ? 19 : 20; - if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } - if (digit_count == longest_digit_count) { - if (negative) { - // Anything negative above INT64_MAX+1 is invalid - if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } - WRITE_INTEGER(~i + 1, src, writer); - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - } - else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } - } - - // Write unsigned if it doesn't fit in a signed integer. - if (i > uint64_t(INT64_MAX)) { - WRITE_UNSIGNED(i, src, writer); - } - else { - WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); - } - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // Inlineable functions - namespace { - - // This table can be used to characterize the final character of an integer - // string. For JSON structural character and allowable white space characters, - // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise - // we return NUMBER_ERROR. - // Optimization note: we could easily reduce the size of the table by half (to 128) - // at the cost of an extra branch. - // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): - static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); - - const uint8_t integer_string_finisher[256] = { - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR }; - - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; - } - - - // Parse any number from 0 to 18,446,744,073,709,551,615 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; - } - - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { - const uint8_t* p = src + 1; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*p != '"') { return NUMBER_ERROR; } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - // Note: we use src[1] and not src[0] because src[0] is the quote character in this - // instance. - if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { - // - // Check for minus sign - // - if (src == src_end) { return NUMBER_ERROR; } - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = src; - uint64_t i = 0; - while (parse_digit(*src, i)) { src++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(src - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*src)) { - // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*src != '"') { return NUMBER_ERROR; } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; - } - - simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { - return (*src == '-'); - } - - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } - return false; - } - - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { - // We have an integer. - // If the number is negative and valid, it must be a signed integer. - if (negative) { return ondemand::number_type::signed_integer; } - // We want values larger or equal to 9223372036854775808 to be unsigned - // integers, and the other values to be signed integers. - int digit_count = int(p - src); - if (digit_count >= 19) { - const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); - if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { - return ondemand::number_type::unsigned_integer; - } - } - return ondemand::number_type::signed_integer; - } - // Hopefully, we have 'e' or 'E' or '.'. - return ondemand::number_type::floating_point_number; - } - - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { - if (src == src_end) { return NUMBER_ERROR; } - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - if (p == src_end) { return NUMBER_ERROR; } - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while ((p != src_end) && parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely((p != src_end) && (*p == '.'))) { - p++; - const uint8_t* start_decimal_digits = p; - if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if ((p != src_end) && (*p == 'e' || *p == 'E')) { - p++; - if (p == src_end) { return NUMBER_ERROR; } - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while ((p != src_end) && parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { - return NUMBER_ERROR; - } - return d; - } - - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (*p != '"') { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; - } - } //namespace {} -#endif // SIMDJSON_SKIPNUMBERPARSING - - } // namespace numberparsing - } // unnamed namespace - } // namespace fallback - } // namespace simdjson - /* end file include/simdjson/generic/numberparsing.h */ - -#endif // SIMDJSON_FALLBACK_NUMBERPARSING_H -/* end file include/simdjson/fallback/numberparsing.h */ -/* begin file include/simdjson/fallback/end.h */ -/* end file include/simdjson/fallback/end.h */ - -#endif // SIMDJSON_IMPLEMENTATION_FALLBACK -#endif // SIMDJSON_FALLBACK_H -/* end file include/simdjson/fallback.h */ -/* begin file include/simdjson/icelake.h */ -#ifndef SIMDJSON_ICELAKE_H -#define SIMDJSON_ICELAKE_H - - -#if SIMDJSON_IMPLEMENTATION_ICELAKE - -#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE -#define SIMDJSON_TARGET_ICELAKE -#define SIMDJSON_UNTARGET_ICELAKE -#else -#define SIMDJSON_TARGET_ICELAKE SIMDJSON_TARGET_REGION("avx512f,avx512dq,avx512cd,avx512bw,avx512vbmi,avx512vbmi2,avx512vl,avx2,bmi,pclmul,lzcnt") -#define SIMDJSON_UNTARGET_ICELAKE SIMDJSON_UNTARGET_REGION -#endif - -namespace simdjson { - /** - * Implementation for Icelake (Intel AVX512). - */ - namespace icelake { - } // namespace icelake -} // namespace simdjson - -// -// These two need to be included outside SIMDJSON_TARGET_ICELAKE -// -/* begin file include/simdjson/icelake/implementation.h */ -#ifndef SIMDJSON_ICELAKE_IMPLEMENTATION_H -#define SIMDJSON_ICELAKE_IMPLEMENTATION_H - - -// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE -namespace simdjson { - namespace icelake { - - using namespace simdjson; - - /** - * @private - */ - class implementation final : public simdjson::implementation { - public: - simdjson_inline implementation() : simdjson::implementation( - "icelake", - "Intel/AMD AVX512", - internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 | internal::instruction_set::AVX512F | internal::instruction_set::AVX512DQ | internal::instruction_set::AVX512CD | internal::instruction_set::AVX512BW | internal::instruction_set::AVX512VL | internal::instruction_set::AVX512VBMI2 - ) {} - simdjson_warn_unused error_code create_dom_parser_implementation( - size_t capacity, - size_t max_length, - std::unique_ptr& dst - ) const noexcept final; - simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; - simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; - }; - - } // namespace icelake -} // namespace simdjson - -#endif // SIMDJSON_ICELAKE_IMPLEMENTATION_H -/* end file include/simdjson/icelake/implementation.h */ -/* begin file include/simdjson/icelake/intrinsics.h */ -#ifndef SIMDJSON_ICELAKE_INTRINSICS_H -#define SIMDJSON_ICELAKE_INTRINSICS_H - - -#if SIMDJSON_VISUAL_STUDIO -// under clang within visual studio, this will include -#include // visual studio or clang -#else -#include // elsewhere -#endif // SIMDJSON_VISUAL_STUDIO - -#if SIMDJSON_CLANG_VISUAL_STUDIO -/** - * You are not supposed, normally, to include these - * headers directly. Instead you should either include intrin.h - * or x86intrin.h. However, when compiling with clang - * under Windows (i.e., when _MSC_VER is set), these headers - * only get included *if* the corresponding features are detected - * from macros: - * e.g., if __AVX2__ is set... in turn, we normally set these - * macros by compiling against the corresponding architecture - * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole - * software with these advanced instructions. In simdjson, we - * want to compile the whole program for a generic target, - * and only target our specific kernels. As a workaround, - * we directly include the needed headers. These headers would - * normally guard against such usage, but we carefully included - * (or ) before, so the headers - * are fooled. - */ -#include // for _blsr_u64 -#include // for __lzcnt64 -#include // for most things (AVX2, AVX512, _popcnt64) -#include -#include -#include -#include -#include // for _mm_clmulepi64_si128 - // Important: we need the AVX-512 headers: -#include -#include -#include -#include -#include -#include -#include -// unfortunately, we may not get _blsr_u64, but, thankfully, clang -// has it as a macro. -#ifndef _blsr_u64 -// we roll our own -#define _blsr_u64(n) ((n - 1) & n) -#endif // _blsr_u64 -#endif // SIMDJSON_CLANG_VISUAL_STUDIO - -static_assert(sizeof(__m512i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for icelake"); - -#endif // SIMDJSON_ICELAKE_INTRINSICS_H -/* end file include/simdjson/icelake/intrinsics.h */ - -// -// The rest need to be inside the region -// -/* begin file include/simdjson/icelake/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "icelake" -// #define SIMDJSON_IMPLEMENTATION icelake -SIMDJSON_TARGET_ICELAKE -/* end file include/simdjson/icelake/begin.h */ - -// Declarations -/* begin file include/simdjson/generic/dom_parser_implementation.h */ - -namespace simdjson { - namespace icelake { // expectation: sizeof(open_container) = 64/8. struct open_container { @@ -14059,11 +13663,11 @@ namespace simdjson { }; - } // namespace icelake + } // namespace fallback } // namespace simdjson namespace simdjson { - namespace icelake { + namespace fallback { inline dom_parser_implementation::dom_parser_implementation() noexcept = default; inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; @@ -14093,757 +13697,166 @@ namespace simdjson { return SUCCESS; } - } // namespace icelake -} // namespace simdjson -/* end file include/simdjson/generic/dom_parser_implementation.h */ -/* begin file include/simdjson/icelake/bitmanipulation.h */ -#ifndef SIMDJSON_ICELAKE_BITMANIPULATION_H -#define SIMDJSON_ICELAKE_BITMANIPULATION_H - -namespace simdjson { - namespace icelake { - namespace { - - // We sometimes call trailing_zero on inputs that are zero, - // but the algorithms do not end up using the returned value. - // Sadly, sanitizers are not smart enough to figure it out. - SIMDJSON_NO_SANITIZE_UNDEFINED - // This function can be used safely even if not all bytes have been - // initialized. - // See issue https://github.com/simdjson/simdjson/issues/1965 - SIMDJSON_NO_SANITIZE_MEMORY - simdjson_inline int trailing_zeroes(uint64_t input_num) { -#if SIMDJSON_REGULAR_VISUAL_STUDIO - return (int)_tzcnt_u64(input_num); -#else // SIMDJSON_REGULAR_VISUAL_STUDIO - //////// - // You might expect the next line to be equivalent to - // return (int)_tzcnt_u64(input_num); - // but the generated code differs and might be less efficient? - //////// - return __builtin_ctzll(input_num); -#endif // SIMDJSON_REGULAR_VISUAL_STUDIO - } - - /* result might be undefined when input_num is zero */ - simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { - return _blsr_u64(input_num); - } - - /* result might be undefined when input_num is zero */ - simdjson_inline int leading_zeroes(uint64_t input_num) { - return int(_lzcnt_u64(input_num)); - } - -#if SIMDJSON_REGULAR_VISUAL_STUDIO - simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { - // note: we do not support legacy 32-bit Windows - return __popcnt64(input_num);// Visual Studio wants two underscores - } -#else - simdjson_inline long long int count_ones(uint64_t input_num) { - return _popcnt64(input_num); - } -#endif - - simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, - uint64_t* result) { -#if SIMDJSON_REGULAR_VISUAL_STUDIO - return _addcarry_u64(0, value1, value2, - reinterpret_cast(result)); -#else - return __builtin_uaddll_overflow(value1, value2, - reinterpret_cast(result)); -#endif - } - - } // unnamed namespace - } // namespace icelake + } // namespace fallback } // namespace simdjson -#endif // SIMDJSON_ICELAKE_BITMANIPULATION_H -/* end file include/simdjson/icelake/bitmanipulation.h */ -/* begin file include/simdjson/icelake/bitmask.h */ -#ifndef SIMDJSON_ICELAKE_BITMASK_H -#define SIMDJSON_ICELAKE_BITMASK_H +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for fallback */ +/* including simdjson/generic/implementation_simdjson_result_base.h for fallback: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for fallback */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace icelake { - namespace { + namespace fallback { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { - // - // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. - // - // For example, prefix_xor(00100100) == 00011100 - // - simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { - // There should be no such thing with a processor supporting avx2 - // but not clmul. - __m128i all_ones = _mm_set1_epi8('\xFF'); - __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); - return _mm_cvtsi128_si64(result); - } - - } // unnamed namespace - } // namespace icelake -} // namespace simdjson - -#endif // SIMDJSON_ICELAKE_BITMASK_H -/* end file include/simdjson/icelake/bitmask.h */ -/* begin file include/simdjson/icelake/simd.h */ -#ifndef SIMDJSON_ICELAKE_SIMD_H -#define SIMDJSON_ICELAKE_SIMD_H - - - - -#if defined(__GNUC__) && !defined(__clang__) -#if __GNUC__ == 8 -#define SIMDJSON_GCC8 1 -#endif // __GNUC__ == 8 -#endif // defined(__GNUC__) && !defined(__clang__) - -#if SIMDJSON_GCC8 -/** - * GCC 8 fails to provide _mm512_set_epi8. We roll our own. - */ -inline __m512i _mm512_set_epi8(uint8_t a0, uint8_t a1, uint8_t a2, uint8_t a3, uint8_t a4, uint8_t a5, uint8_t a6, uint8_t a7, uint8_t a8, uint8_t a9, uint8_t a10, uint8_t a11, uint8_t a12, uint8_t a13, uint8_t a14, uint8_t a15, uint8_t a16, uint8_t a17, uint8_t a18, uint8_t a19, uint8_t a20, uint8_t a21, uint8_t a22, uint8_t a23, uint8_t a24, uint8_t a25, uint8_t a26, uint8_t a27, uint8_t a28, uint8_t a29, uint8_t a30, uint8_t a31, uint8_t a32, uint8_t a33, uint8_t a34, uint8_t a35, uint8_t a36, uint8_t a37, uint8_t a38, uint8_t a39, uint8_t a40, uint8_t a41, uint8_t a42, uint8_t a43, uint8_t a44, uint8_t a45, uint8_t a46, uint8_t a47, uint8_t a48, uint8_t a49, uint8_t a50, uint8_t a51, uint8_t a52, uint8_t a53, uint8_t a54, uint8_t a55, uint8_t a56, uint8_t a57, uint8_t a58, uint8_t a59, uint8_t a60, uint8_t a61, uint8_t a62, uint8_t a63) { - return _mm512_set_epi64(uint64_t(a7) + (uint64_t(a6) << 8) + (uint64_t(a5) << 16) + (uint64_t(a4) << 24) + (uint64_t(a3) << 32) + (uint64_t(a2) << 40) + (uint64_t(a1) << 48) + (uint64_t(a0) << 56), - uint64_t(a15) + (uint64_t(a14) << 8) + (uint64_t(a13) << 16) + (uint64_t(a12) << 24) + (uint64_t(a11) << 32) + (uint64_t(a10) << 40) + (uint64_t(a9) << 48) + (uint64_t(a8) << 56), - uint64_t(a23) + (uint64_t(a22) << 8) + (uint64_t(a21) << 16) + (uint64_t(a20) << 24) + (uint64_t(a19) << 32) + (uint64_t(a18) << 40) + (uint64_t(a17) << 48) + (uint64_t(a16) << 56), - uint64_t(a31) + (uint64_t(a30) << 8) + (uint64_t(a29) << 16) + (uint64_t(a28) << 24) + (uint64_t(a27) << 32) + (uint64_t(a26) << 40) + (uint64_t(a25) << 48) + (uint64_t(a24) << 56), - uint64_t(a39) + (uint64_t(a38) << 8) + (uint64_t(a37) << 16) + (uint64_t(a36) << 24) + (uint64_t(a35) << 32) + (uint64_t(a34) << 40) + (uint64_t(a33) << 48) + (uint64_t(a32) << 56), - uint64_t(a47) + (uint64_t(a46) << 8) + (uint64_t(a45) << 16) + (uint64_t(a44) << 24) + (uint64_t(a43) << 32) + (uint64_t(a42) << 40) + (uint64_t(a41) << 48) + (uint64_t(a40) << 56), - uint64_t(a55) + (uint64_t(a54) << 8) + (uint64_t(a53) << 16) + (uint64_t(a52) << 24) + (uint64_t(a51) << 32) + (uint64_t(a50) << 40) + (uint64_t(a49) << 48) + (uint64_t(a48) << 56), - uint64_t(a63) + (uint64_t(a62) << 8) + (uint64_t(a61) << 16) + (uint64_t(a60) << 24) + (uint64_t(a59) << 32) + (uint64_t(a58) << 40) + (uint64_t(a57) << 48) + (uint64_t(a56) << 56)); -} -#endif // SIMDJSON_GCC8 - - - -namespace simdjson { - namespace icelake { - namespace { - namespace simd { - - // Forward-declared so they can be used by splat and friends. - template - struct base { - __m512i value; - - // Zero constructor - simdjson_inline base() : value{ __m512i() } {} - - // Conversion from SIMD register - simdjson_inline base(const __m512i _value) : value(_value) {} - - // Conversion to SIMD register - simdjson_inline operator const __m512i& () const { return this->value; } - simdjson_inline operator __m512i& () { return this->value; } - - // Bit operations - simdjson_inline Child operator|(const Child other) const { return _mm512_or_si512(*this, other); } - simdjson_inline Child operator&(const Child other) const { return _mm512_and_si512(*this, other); } - simdjson_inline Child operator^(const Child other) const { return _mm512_xor_si512(*this, other); } - simdjson_inline Child bit_andnot(const Child other) const { return _mm512_andnot_si512(other, *this); } - simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } - simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } - simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } - }; - - // Forward-declared so they can be used by splat and friends. - template - struct simd8; - - template> - struct base8 : base> { - typedef uint32_t bitmask_t; - typedef uint64_t bitmask2_t; - - simdjson_inline base8() : base>() {} - simdjson_inline base8(const __m512i _value) : base>(_value) {} - - friend simdjson_really_inline uint64_t operator==(const simd8 lhs, const simd8 rhs) { - return _mm512_cmpeq_epi8_mask(lhs, rhs); - } - - static const int SIZE = sizeof(base::value); - - template - simdjson_inline simd8 prev(const simd8 prev_chunk) const { - // workaround for compilers unable to figure out that 16 - N is a constant (GCC 8) - constexpr int shift = 16 - N; - return _mm512_alignr_epi8(*this, _mm512_permutex2var_epi64(prev_chunk, _mm512_set_epi64(13, 12, 11, 10, 9, 8, 7, 6), *this), shift); - } - }; - - // SIMD byte mask type (returned by things like eq and gt) - template<> - struct simd8 : base8 { - static simdjson_inline simd8 splat(bool _value) { return _mm512_set1_epi8(uint8_t(-(!!_value))); } - - simdjson_inline simd8() : base8() {} - simdjson_inline simd8(const __m512i _value) : base8(_value) {} - // Splat constructor - simdjson_inline simd8(bool _value) : base8(splat(_value)) {} - simdjson_inline bool any() const { return !!_mm512_test_epi8_mask(*this, *this); } - simdjson_inline simd8 operator~() const { return *this ^ true; } - }; - - template - struct base8_numeric : base8 { - static simdjson_inline simd8 splat(T _value) { return _mm512_set1_epi8(_value); } - static simdjson_inline simd8 zero() { return _mm512_setzero_si512(); } - static simdjson_inline simd8 load(const T values[64]) { - return _mm512_loadu_si512(reinterpret_cast(values)); - } - // Repeat 16 values as many times as necessary (usually for lookup tables) - static simdjson_inline simd8 repeat_16( - T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, - T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 - ) { - return simd8( - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15 - ); - } - - simdjson_inline base8_numeric() : base8() {} - simdjson_inline base8_numeric(const __m512i _value) : base8(_value) {} - - // Store to array - simdjson_inline void store(T dst[64]) const { return _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), *this); } - - // Addition/subtraction are the same for signed and unsigned - simdjson_inline simd8 operator+(const simd8 other) const { return _mm512_add_epi8(*this, other); } - simdjson_inline simd8 operator-(const simd8 other) const { return _mm512_sub_epi8(*this, other); } - simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } - simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } - - // Override to distinguish from bool version - simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } - - // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) - template - simdjson_inline simd8 lookup_16(simd8 lookup_table) const { - return _mm512_shuffle_epi8(lookup_table, *this); - } - - // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). - // Passing a 0 value for mask would be equivalent to writing out every byte to output. - // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes - // get written. - // Design consideration: it seems like a function with the - // signature simd8 compress(uint32_t mask) would be - // sensible, but the AVX ISA makes this kind of approach difficult. - template - simdjson_inline void compress(uint64_t mask, L* output) const { - _mm512_mask_compressstoreu_epi8(output, ~mask, *this); - } - - template - simdjson_inline simd8 lookup_16( - L replace0, L replace1, L replace2, L replace3, - L replace4, L replace5, L replace6, L replace7, - L replace8, L replace9, L replace10, L replace11, - L replace12, L replace13, L replace14, L replace15) const { - return lookup_16(simd8::repeat_16( - replace0, replace1, replace2, replace3, - replace4, replace5, replace6, replace7, - replace8, replace9, replace10, replace11, - replace12, replace13, replace14, replace15 - )); - } - }; - - // Signed bytes - template<> - struct simd8 : base8_numeric { - simdjson_inline simd8() : base8_numeric() {} - simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} - // Splat constructor - simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} - // Array constructor - simdjson_inline simd8(const int8_t values[64]) : simd8(load(values)) {} - // Member-by-member initialization - simdjson_inline simd8( - int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, - int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, - int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, - int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31, - int8_t v32, int8_t v33, int8_t v34, int8_t v35, int8_t v36, int8_t v37, int8_t v38, int8_t v39, - int8_t v40, int8_t v41, int8_t v42, int8_t v43, int8_t v44, int8_t v45, int8_t v46, int8_t v47, - int8_t v48, int8_t v49, int8_t v50, int8_t v51, int8_t v52, int8_t v53, int8_t v54, int8_t v55, - int8_t v56, int8_t v57, int8_t v58, int8_t v59, int8_t v60, int8_t v61, int8_t v62, int8_t v63 - ) : simd8(_mm512_set_epi8( - v63, v62, v61, v60, v59, v58, v57, v56, - v55, v54, v53, v52, v51, v50, v49, v48, - v47, v46, v45, v44, v43, v42, v41, v40, - v39, v38, v37, v36, v35, v34, v33, v32, - v31, v30, v29, v28, v27, v26, v25, v24, - v23, v22, v21, v20, v19, v18, v17, v16, - v15, v14, v13, v12, v11, v10, v9, v8, - v7, v6, v5, v4, v3, v2, v1, v0 - )) {} - - // Repeat 16 values as many times as necessary (usually for lookup tables) - simdjson_inline static simd8 repeat_16( - int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, - int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 - ) { - return simd8( - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15 - ); - } - - // Order-sensitive comparisons - simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epi8(*this, other); } - simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epi8(*this, other); } - - simdjson_inline simd8 operator>(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(*this, other), _mm512_set1_epi8(uint8_t(0x80))); } - simdjson_inline simd8 operator<(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(other, *this), _mm512_set1_epi8(uint8_t(0x80))); } - }; - - // Unsigned bytes - template<> - struct simd8 : base8_numeric { - simdjson_inline simd8() : base8_numeric() {} - simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} - // Splat constructor - simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} - // Array constructor - simdjson_inline simd8(const uint8_t values[64]) : simd8(load(values)) {} - // Member-by-member initialization - simdjson_inline simd8( - uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, - uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, - uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, - uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31, - uint8_t v32, uint8_t v33, uint8_t v34, uint8_t v35, uint8_t v36, uint8_t v37, uint8_t v38, uint8_t v39, - uint8_t v40, uint8_t v41, uint8_t v42, uint8_t v43, uint8_t v44, uint8_t v45, uint8_t v46, uint8_t v47, - uint8_t v48, uint8_t v49, uint8_t v50, uint8_t v51, uint8_t v52, uint8_t v53, uint8_t v54, uint8_t v55, - uint8_t v56, uint8_t v57, uint8_t v58, uint8_t v59, uint8_t v60, uint8_t v61, uint8_t v62, uint8_t v63 - ) : simd8(_mm512_set_epi8( - v63, v62, v61, v60, v59, v58, v57, v56, - v55, v54, v53, v52, v51, v50, v49, v48, - v47, v46, v45, v44, v43, v42, v41, v40, - v39, v38, v37, v36, v35, v34, v33, v32, - v31, v30, v29, v28, v27, v26, v25, v24, - v23, v22, v21, v20, v19, v18, v17, v16, - v15, v14, v13, v12, v11, v10, v9, v8, - v7, v6, v5, v4, v3, v2, v1, v0 - )) {} - - // Repeat 16 values as many times as necessary (usually for lookup tables) - simdjson_inline static simd8 repeat_16( - uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, - uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 - ) { - return simd8( - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15, - v0, v1, v2, v3, v4, v5, v6, v7, - v8, v9, v10, v11, v12, v13, v14, v15 - ); - } - - // Saturated math - simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm512_adds_epu8(*this, other); } - simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm512_subs_epu8(*this, other); } - - // Order-specific operations - simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epu8(*this, other); } - simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epu8(other, *this); } - // Same as >, but only guarantees true is nonzero (< guarantees true = -1) - simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } - // Same as <, but only guarantees true is nonzero (< guarantees true = -1) - simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } - simdjson_inline uint64_t operator<=(const simd8 other) const { return other.max_val(*this) == other; } - simdjson_inline uint64_t operator>=(const simd8 other) const { return other.min_val(*this) == other; } - simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } - simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } - - // Bit-specific operations - simdjson_inline simd8 bits_not_set() const { return _mm512_mask_blend_epi8(*this == uint8_t(0), _mm512_set1_epi8(0), _mm512_set1_epi8(-1)); } - simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } - simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } - simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } - - simdjson_inline bool is_ascii() const { return _mm512_movepi8_mask(*this) == 0; } - simdjson_inline bool bits_not_set_anywhere() const { - return !_mm512_test_epi8_mask(*this, *this); - } - simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } - simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return !_mm512_test_epi8_mask(*this, bits); } - simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } - template - simdjson_inline simd8 shr() const { return simd8(_mm512_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } - template - simdjson_inline simd8 shl() const { return simd8(_mm512_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } - // Get one of the bits and make a bitmask out of it. - // e.g. value.get_bit<7>() gets the high bit - template - simdjson_inline uint64_t get_bit() const { return _mm512_movepi8_mask(_mm512_slli_epi16(*this, 7 - N)); } - }; - - template - struct simd8x64 { - static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); - static_assert(NUM_CHUNKS == 1, "Icelake kernel should use one register per 64-byte block."); - const simd8 chunks[NUM_CHUNKS]; - - simd8x64(const simd8x64& o) = delete; // no copy allowed - simd8x64& operator=(const simd8& other) = delete; // no assignment allowed - simd8x64() = delete; // no default constructor allowed - - simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} - simdjson_inline simd8x64(const simd8 chunk0) : chunks{ chunk0 } {} - simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr) } {} - - simdjson_inline uint64_t compress(uint64_t mask, T* output) const { - this->chunks[0].compress(mask, output); - return 64 - count_ones(mask); - } - - simdjson_inline void store(T ptr[64]) const { - this->chunks[0].store(ptr + sizeof(simd8) * 0); - } - - simdjson_inline simd8 reduce_or() const { - return this->chunks[0]; - } - - simdjson_inline simd8x64 bit_or(const T m) const { - const simd8 mask = simd8::splat(m); - return simd8x64( - this->chunks[0] | mask - ); - } - - simdjson_inline uint64_t eq(const T m) const { - const simd8 mask = simd8::splat(m); - return this->chunks[0] == mask; - } - - simdjson_inline uint64_t eq(const simd8x64& other) const { - return this->chunks[0] == other.chunks[0]; - } - - simdjson_inline uint64_t lteq(const T m) const { - const simd8 mask = simd8::splat(m); - return this->chunks[0] <= mask; - } - }; // struct simd8x64 - - } // namespace simd - - } // unnamed namespace - } // namespace icelake -} // namespace simdjson - -#endif // SIMDJSON_ICELAKE_SIMD_H -/* end file include/simdjson/icelake/simd.h */ -/* begin file include/simdjson/generic/jsoncharutils.h */ - -namespace simdjson { - namespace icelake { - namespace { - namespace jsoncharutils { - - // return non-zero if not a structural or whitespace char - // zero otherwise - simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { - return internal::structural_or_whitespace_negated[c]; - } - - simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { - return internal::structural_or_whitespace[c]; - } - - // returns a value with the high 16 bits set if not valid - // otherwise returns the conversion of the 4 hex digits at src into the bottom - // 16 bits of the 32-bit return register - // - // see - // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ - static inline uint32_t hex_to_u32_nocheck( - const uint8_t* src) { // strictly speaking, static inline is a C-ism - uint32_t v1 = internal::digit_to_val32[630 + src[0]]; - uint32_t v2 = internal::digit_to_val32[420 + src[1]]; - uint32_t v3 = internal::digit_to_val32[210 + src[2]]; - uint32_t v4 = internal::digit_to_val32[0 + src[3]]; - return v1 | v2 | v3 | v4; - } - - // given a code point cp, writes to c - // the utf-8 code, outputting the length in - // bytes, if the length is zero, the code point - // is invalid - // - // This can possibly be made faster using pdep - // and clz and table lookups, but JSON documents - // have few escaped code points, and the following - // function looks cheap. - // - // Note: we assume that surrogates are treated separately - // - simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { - if (cp <= 0x7F) { - c[0] = uint8_t(cp); - return 1; // ascii - } - if (cp <= 0x7FF) { - c[0] = uint8_t((cp >> 6) + 192); - c[1] = uint8_t((cp & 63) + 128); - return 2; // universal plane - // Surrogates are treated elsewhere... - //} //else if (0xd800 <= cp && cp <= 0xdfff) { - // return 0; // surrogates // could put assert here - } - else if (cp <= 0xFFFF) { - c[0] = uint8_t((cp >> 12) + 224); - c[1] = uint8_t(((cp >> 6) & 63) + 128); - c[2] = uint8_t((cp & 63) + 128); - return 3; - } - else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this - // is not needed - c[0] = uint8_t((cp >> 18) + 240); - c[1] = uint8_t(((cp >> 12) & 63) + 128); - c[2] = uint8_t(((cp >> 6) & 63) + 128); - c[3] = uint8_t((cp & 63) + 128); - return 4; - } - // will return 0 when the code point was too large. - return 0; // bad r - } - -#if SIMDJSON_IS_32BITS // _umul128 for x86, arm - // this is a slow emulation routine for 32-bit - // - static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { - return x * (uint64_t)y; - } - static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { - uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); - uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); - uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); - uint64_t adbc_carry = !!(adbc < ad); - uint64_t lo = bd + (adbc << 32); - *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + - (adbc_carry << 32) + !!(lo < bd); - return lo; - } -#endif - - using internal::value128; - - simdjson_inline value128 full_multiplication(uint64_t value1, uint64_t value2) { - value128 answer; -#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS -#ifdef _M_ARM64 - // ARM64 has native support for 64-bit multiplications, no need to emultate - answer.high = __umulh(value1, value2); - answer.low = value1 * value2; -#else - answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 -#endif // _M_ARM64 -#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS - __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; - answer.low = uint64_t(r); - answer.high = uint64_t(r >> 64); -#endif - return answer; - } - - } // namespace jsoncharutils - } // unnamed namespace - } // namespace icelake -} // namespace simdjson -/* end file include/simdjson/generic/jsoncharutils.h */ -/* begin file include/simdjson/generic/atomparsing.h */ -namespace simdjson { - namespace icelake { - namespace { - /// @private - namespace atomparsing { - - // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. - // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot - // be certain that the character pointer will be properly aligned. - // You might think that using memcpy makes this function expensive, but you'd be wrong. - // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); - // to the compile-time constant 1936482662. - simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } - - - // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. - // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. - simdjson_warn_unused - simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { - uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) - static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); - std::memcpy(&srcval, src, sizeof(uint32_t)); - return srcval ^ string_to_uint32(atom); - } - - simdjson_warn_unused - simdjson_inline bool is_valid_true_atom(const uint8_t* src) { - return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; - } - - simdjson_warn_unused - simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { - if (len > 4) { return is_valid_true_atom(src); } - else if (len == 4) { return !str4ncmp(src, "true"); } - else { return false; } - } - - simdjson_warn_unused - simdjson_inline bool is_valid_false_atom(const uint8_t* src) { - return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; - } - - simdjson_warn_unused - simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { - if (len > 5) { return is_valid_false_atom(src); } - else if (len == 5) { return !str4ncmp(src + 1, "alse"); } - else { return false; } - } - - simdjson_warn_unused - simdjson_inline bool is_valid_null_atom(const uint8_t* src) { - return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; - } - - simdjson_warn_unused - simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { - if (len > 4) { return is_valid_null_atom(src); } - else if (len == 4) { return !str4ncmp(src, "null"); } - else { return false; } - } - - } // namespace atomparsing - } // unnamed namespace - } // namespace icelake -} // namespace simdjson -/* end file include/simdjson/generic/atomparsing.h */ -/* begin file include/simdjson/icelake/stringparsing.h */ -#ifndef SIMDJSON_ICELAKE_STRINGPARSING_H -#define SIMDJSON_ICELAKE_STRINGPARSING_H - - -namespace simdjson { - namespace icelake { - namespace { - - using namespace simd; - - // Holds backslashes and quotes locations. - struct backslash_and_quote { - public: - static constexpr uint32_t BYTES_PROCESSED = 32; - simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); - - simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } - simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } - simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } - simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } - - uint64_t bs_bits; - uint64_t quote_bits; - }; // struct backslash_and_quote - - simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { - // this can read up to 15 bytes beyond the buffer size, but we require - // SIMDJSON_PADDING of padding - static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); - simd8 v(src); - // store to dest unconditionally - we can overwrite the bits we don't like later - v.store(dst); - return { - static_cast(v == '\\'), // bs_bits - static_cast(v == '"'), // quote_bits - }; - } - - } // unnamed namespace - } // namespace icelake -} // namespace simdjson - -#endif // SIMDJSON_ICELAKE_STRINGPARSING_H -/* end file include/simdjson/icelake/stringparsing.h */ -/* begin file include/simdjson/icelake/numberparsing.h */ -#ifndef SIMDJSON_ICELAKE_NUMBERPARSING_H -#define SIMDJSON_ICELAKE_NUMBERPARSING_H - -namespace simdjson { - namespace icelake { - namespace { - - static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { - // this actually computes *16* values so we are being wasteful. - const __m128i ascii0 = _mm_set1_epi8('0'); - const __m128i mul_1_10 = - _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); - const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); - const __m128i mul_1_10000 = - _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); - const __m128i input = _mm_sub_epi8( - _mm_loadu_si128(reinterpret_cast(chars)), ascii0); - const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); - const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); - const __m128i t3 = _mm_packus_epi32(t2, t2); - const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); - return _mm_cvtsi128_si32( - t4); // only captures the sum of the first 8 digits, drop the rest - } - - } // unnamed namespace - } // namespace icelake -} // namespace simdjson - -#define SIMDJSON_SWAR_NUMBER_PARSING 1 - -/* begin file include/simdjson/generic/numberparsing.h */ -#include - -namespace simdjson { - namespace icelake { - - namespace ondemand { /** - * The type of a JSON number + * Create a new empty result with error = UNINITIALIZED. */ - enum class number_type { - floating_point_number = 1, /// a binary64 number - signed_integer, /// a signed integer that fits in a 64-bit word using two's complement - unsigned_integer /// a positive integer larger or equal to 1<<63 - }; - } + simdjson_inline implementation_simdjson_result_base() noexcept = default; - namespace { - /// @private - namespace numberparsing { + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for fallback */ +/* including simdjson/generic/numberparsing.h for fallback: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for fallback */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace fallback { + namespace numberparsing { #ifdef JSON_TEST_NUMBERS #define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) @@ -14857,19 +13870,20 @@ namespace simdjson { #define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) #endif - namespace { - // Convert a mantissa, an exponent and a sign bit into an ieee64 double. - // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). - // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. - simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { - double d; - mantissa &= ~(1ULL << 52); - mantissa |= real_exponent << 52; - mantissa |= ((static_cast(negative)) << 63); - std::memcpy(&d, &mantissa, sizeof(d)); - return d; - } + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; } + // Attempts to compute i * 10^(power) exactly; and if "negative" is // true, negate the result. // This function will only work in some cases, when it does not work, success is @@ -14886,10 +13900,11 @@ namespace simdjson { #endif #if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) // We cannot be certain that x/y is rounded to nearest. - if (0 <= power && power <= 22 && i <= 9007199254740991) { + if (0 <= power && power <= 22 && i <= 9007199254740991) #else - if (-22 <= power && power <= 22 && i <= 9007199254740991) { + if (-22 <= power && power <= 22 && i <= 9007199254740991) #endif + { // convert the integer into a double. This is lossless since // 0 <= i <= 2^53 - 1. d = double(i); @@ -14994,7 +14009,7 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 firstproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index]); + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); // Both i and power_of_five_128[index] have their most significant bit set to 1 which // implies that the either the most or the second most significant bit of the product // is 1. We pack values in this manner for efficiency reasons: it maximizes the use @@ -15015,8 +14030,7 @@ namespace simdjson { // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q // to the desired approximation using one multiplication. Sometimes it does not suffice. // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and - // then we get a better approximation to i * 5^q. In very rare cases, even that - // will not suffice, though it is seemingly very hard to find such a scenario. + // then we get a better approximation to i * 5^q. // // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat // more complicated. @@ -15028,15 +14042,12 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 secondproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); firstproduct.low += secondproduct.high; if (secondproduct.high > firstproduct.low) { firstproduct.high++; } - // At this point, we might need to add at most one to firstproduct, but this - // can only change the value of firstproduct.high if firstproduct.low is maximal. - if (simdjson_unlikely(firstproduct.low == 0xFFFFFFFFFFFFFFFF)) { - // This is very unlikely, but if so, we need to do much more work! - return false; - } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. } uint64_t lower = firstproduct.low; uint64_t upper = firstproduct.high; @@ -15119,7 +14130,7 @@ namespace simdjson { } d = to_double(mantissa, real_exponent, negative); return true; - } + } // We call a fallback floating-point parser that might be slow. Note // it will accept JSON numbers, but the JSON spec. is more restrictive so @@ -15128,7 +14139,7 @@ namespace simdjson { // It will return an error (false) if the parsed number is infinite. // The string parsing itself always succeeds. We know that there is at least // one digit. - static bool parse_float_fallback(const uint8_t * ptr, double* outDouble) { + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); // We do not accept infinite values. @@ -15142,7 +14153,8 @@ namespace simdjson { // to handle that max may be a macro on windows). return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); } - static bool parse_float_fallback(const uint8_t * ptr, const uint8_t * end_ptr, double* outDouble) { + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); // We do not accept infinite values. @@ -15160,7 +14172,7 @@ namespace simdjson { // check quickly whether the next 8 chars are made of digits // at a glance, it looks better than Mula's // http://0x80.pl/articles/swar-digits-validate.html - simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t * chars) { + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { uint64_t val; // this can read up to 7 bytes beyond the buffer size, but we require // SIMDJSON_PADDING of padding @@ -15175,19 +14187,9 @@ namespace simdjson { 0x3333333333333333); } - template - error_code slow_float_parsing(simdjson_unused const uint8_t * src, W writer) { - double d; - if (parse_float_fallback(src, &d)) { - writer.append_double(d); - return SUCCESS; - } - return INVALID_NUMBER(src); - } - template SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later - simdjson_inline bool parse_digit(const uint8_t c, I & i) { + simdjson_inline bool parse_digit(const uint8_t c, I& i) { const uint8_t digit = static_cast(c - '0'); if (digit > 9) { return false; @@ -15197,7 +14199,7 @@ namespace simdjson { return true; } - simdjson_inline error_code parse_decimal(simdjson_unused const uint8_t* const src, const uint8_t * &p, uint64_t & i, int64_t & exponent) { + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { // we continue with the fiction that we have an integer. If the // floating point number is representable as x * 10^z for some integer // z that fits in 53 bits, then we will be able to convert back the @@ -15225,7 +14227,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t * &p, int64_t & exponent) { + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { // Exp Sign: -123.456e[-]78 bool neg_exp = ('-' == *p); if (neg_exp || '+' == *p) { p++; } // Skip + as well @@ -15276,7 +14278,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline size_t significant_digits(const uint8_t * start_digits, size_t digit_count) { + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { // It is possible that the integer had an overflow. // We have to handle the case where we have 0.0000somenumber. const uint8_t* start = start_digits; @@ -15285,79 +14287,93 @@ namespace simdjson { return digit_count - size_t(start - start_digits); } - template - simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t * start_digits, size_t digit_count, int64_t exponent, W & writer) { - // If we frequently had to deal with long strings of digits, - // we could extend our code by using a 128-bit integer instead - // of a 64-bit integer. However, this is uncommon in practice. - // - // 9999999999999999999 < 2**64 so we can accommodate 19 digits. - // If we have a decimal separator, then digit_count - 1 is the number of digits, but we - // may not have a decimal separator! - if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { - // Ok, chances are good that we had an overflow! - // this is almost never going to get called!!! - // we start anew, going slowly!!! - // This will happen in the following examples: - // 10000000000000000000000000000000000000000000e+308 - // 3.1415926535897932384626433832795028841971693993751 - // - // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens - // because slow_float_parsing is a non-inlined function. If we passed our writer reference to - // it, it would force it to be stored in memory, preventing the compiler from picking it apart - // and putting into registers. i.e. if we pass it as reference, it gets slow. - // This is what forces the skip_double, as well. - error_code error = slow_float_parsing(src, writer); - writer.skip_double(); - return error; - } - // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other - // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 - // To future reader: we'd love if someone found a better way, or at least could explain this result! - if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { - // - // Important: smallest_power is such that it leads to a zero value. - // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero - // so something x 10^-343 goes to zero, but not so with something x 10^-342. - static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); - // - if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { - // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero - WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); - return SUCCESS; - } - else { // (exponent > largest_power) and (i != 0) - // We have, for sure, an infinite value and simdjson refuses to parse infinite values. - return INVALID_NUMBER(src); - } - } - double d; - if (!compute_float_64(exponent, i, negative, d)) { - // we are almost never going to get here. - if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } - } - WRITE_DOUBLE(d, src, writer); + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); return SUCCESS; } + return INVALID_NUMBER(src); + } - // for performance analysis, it is sometimes useful to skip parsing + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing #ifdef SIMDJSON_SKIPNUMBERPARSING - template - simdjson_inline error_code parse_number(const uint8_t* const, W & writer) { - writer.append_s64(0); // always write zero - return SUCCESS; // always succeeds - } + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t * src) noexcept { return ondemand::number_type::signed_integer; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } #else // parse the number at src @@ -15369,9 +14385,308 @@ namespace simdjson { // content and append a space before calling this function. // // Our objective is accurate parsing (ULP of 0) at high speed. - template - simdjson_inline error_code parse_number(const uint8_t* const src, W & writer) { + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { // // Check for minus sign // @@ -15389,776 +14704,571 @@ namespace simdjson { // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. // Optimization note: size_t is expected to be unsigned. size_t digit_count = size_t(p - start_digits); - if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } - - // - // Handle floats if there is a . or e (or both) - // - int64_t exponent = 0; - bool is_float = false; - if ('.' == *p) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_decimal(src, p, i, exponent)); - digit_count = int(p - start_digits); // used later to guard against overflows - } - if (('e' == *p) || ('E' == *p)) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_exponent(src, p, exponent)); - } - if (is_float) { - const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); - SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); - if (dirty_end) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // The longest negative 64-bit number is 19 digits. - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - size_t longest_digit_count = negative ? 19 : 20; - if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } - if (digit_count == longest_digit_count) { - if (negative) { - // Anything negative above INT64_MAX+1 is invalid - if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } - WRITE_INTEGER(~i + 1, src, writer); - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - } - else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } - } - - // Write unsigned if it doesn't fit in a signed integer. - if (i > uint64_t(INT64_MAX)) { - WRITE_UNSIGNED(i, src, writer); - } - else { - WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); - } - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; } - // Inlineable functions - namespace { + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); - // This table can be used to characterize the final character of an integer - // string. For JSON structural character and allowable white space characters, - // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise - // we return NUMBER_ERROR. - // Optimization note: we could easily reduce the size of the table by half (to 128) - // at the cost of an extra branch. - // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): - static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } - const uint8_t integer_string_finisher[256] = { - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR }; + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - - return i; + } + else { + overflow = p - src > 19; } + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // Parse any number from 0 to 18,446,744,073,709,551,615 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + exponent += exp_neg ? 0 - exp : exp; } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { - const uint8_t* p = src + 1; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*p != '"') { return NUMBER_ERROR; } + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - // Note: we use src[1] and not src[0] because src[0] is the quote character in this - // instance. - if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; } + return d; + } - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { - // - // Check for minus sign - // - if (src == src_end) { return NUMBER_ERROR; } - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = src; - uint64_t i = 0; - while (parse_digit(*src, i)) { src++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(src - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*src)) { - // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*src != '"') { return NUMBER_ERROR; } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; } } - else { - overflow = p - src > 19; + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; + } + else { + overflow = p - src > 19; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { - return (*src == '-'); - } - - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } - return false; - } - - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { - // We have an integer. - // If the number is negative and valid, it must be a signed integer. - if (negative) { return ondemand::number_type::signed_integer; } - // We want values larger or equal to 9223372036854775808 to be unsigned - // integers, and the other values to be signed integers. - int digit_count = int(p - src); - if (digit_count >= 19) { - const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); - if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { - return ondemand::number_type::unsigned_integer; - } - } - return ondemand::number_type::signed_integer; - } - // Hopefully, we have 'e' or 'E' or '.'. - return ondemand::number_type::floating_point_number; - } - - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { - if (src == src_end) { return NUMBER_ERROR; } - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; if (p == src_end) { return NUMBER_ERROR; } - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while ((p != src_end) && parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely((p != src_end) && (*p == '.'))) { - p++; - const uint8_t* start_decimal_digits = p; - if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if ((p != src_end) && (*p == 'e' || *p == 'E')) { - p++; - if (p == src_end) { return NUMBER_ERROR; } - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while ((p != src_end) && parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { - return NUMBER_ERROR; - } - return d; + exponent += exp_neg ? 0 - exp : exp; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + exponent = -(p - start_decimal_digits); - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (*p != '"') { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; } - } //namespace {} + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace #endif // SIMDJSON_SKIPNUMBERPARSING - } // namespace numberparsing - } // unnamed namespace - } // namespace icelake - } // namespace simdjson - /* end file include/simdjson/generic/numberparsing.h */ + } // namespace numberparsing -#endif // SIMDJSON_ICELAKE_NUMBERPARSING_H -/* end file include/simdjson/icelake/numberparsing.h */ -/* begin file include/simdjson/icelake/end.h */ -SIMDJSON_UNTARGET_ICELAKE -/* end file include/simdjson/icelake/end.h */ + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } -#endif // SIMDJSON_IMPLEMENTATION_ICELAKE -#endif // SIMDJSON_ICELAKE_H -/* end file include/simdjson/icelake.h */ -/* begin file include/simdjson/haswell.h */ + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for fallback */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for fallback: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for fallback */ +/* end file simdjson/generic/amalgamated.h for fallback */ +/* including simdjson/fallback/end.h: #include "simdjson/fallback/end.h" */ +/* begin file simdjson/fallback/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* undefining SIMDJSON_IMPLEMENTATION from "fallback" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/fallback/end.h */ + +#endif // SIMDJSON_FALLBACK_H +/* end file simdjson/fallback.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(haswell) +/* including simdjson/haswell.h: #include "simdjson/haswell.h" */ +/* begin file simdjson/haswell.h */ #ifndef SIMDJSON_HASWELL_H #define SIMDJSON_HASWELL_H +/* including simdjson/haswell/begin.h: #include "simdjson/haswell/begin.h" */ +/* begin file simdjson/haswell/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "haswell" */ +#define SIMDJSON_IMPLEMENTATION haswell -#if SIMDJSON_IMPLEMENTATION_HASWELL +/* including simdjson/haswell/base.h: #include "simdjson/haswell/base.h" */ +/* begin file simdjson/haswell/base.h */ +#ifndef SIMDJSON_HASWELL_BASE_H +#define SIMDJSON_HASWELL_BASE_H -#if SIMDJSON_CAN_ALWAYS_RUN_HASWELL -#define SIMDJSON_TARGET_HASWELL -#define SIMDJSON_UNTARGET_HASWELL -#else -#define SIMDJSON_TARGET_HASWELL SIMDJSON_TARGET_REGION("avx2,bmi,pclmul,lzcnt") -#define SIMDJSON_UNTARGET_HASWELL SIMDJSON_UNTARGET_REGION -#endif +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL namespace simdjson { /** * Implementation for Haswell (Intel AVX2). */ namespace haswell { - } // namespace haswell -} // namespace simdjson -// -// These two need to be included outside SIMDJSON_TARGET_HASWELL -// -/* begin file include/simdjson/haswell/implementation.h */ -#ifndef SIMDJSON_HASWELL_IMPLEMENTATION_H -#define SIMDJSON_HASWELL_IMPLEMENTATION_H + class implementation; - -// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL -namespace simdjson { - namespace haswell { - - using namespace simdjson; - - /** - * @private - */ - class implementation final : public simdjson::implementation { - public: - simdjson_inline implementation() : simdjson::implementation( - "haswell", - "Intel/AMD AVX2", - internal::instruction_set::AVX2 | internal::instruction_set::PCLMULQDQ | internal::instruction_set::BMI1 | internal::instruction_set::BMI2 - ) {} - simdjson_warn_unused error_code create_dom_parser_implementation( - size_t capacity, - size_t max_length, - std::unique_ptr& dst - ) const noexcept final; - simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; - simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; - }; + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace } // namespace haswell } // namespace simdjson -#endif // SIMDJSON_HASWELL_IMPLEMENTATION_H -/* end file include/simdjson/haswell/implementation.h */ -/* begin file include/simdjson/haswell/intrinsics.h */ +#endif // SIMDJSON_HASWELL_BASE_H +/* end file simdjson/haswell/base.h */ +/* including simdjson/haswell/intrinsics.h: #include "simdjson/haswell/intrinsics.h" */ +/* begin file simdjson/haswell/intrinsics.h */ #ifndef SIMDJSON_HASWELL_INTRINSICS_H #define SIMDJSON_HASWELL_INTRINSICS_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ #if SIMDJSON_VISUAL_STUDIO // under clang within visual studio, this will include @@ -16205,104 +15315,23 @@ namespace simdjson { static_assert(sizeof(__m256i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for haswell kernel."); #endif // SIMDJSON_HASWELL_INTRINSICS_H -/* end file include/simdjson/haswell/intrinsics.h */ +/* end file simdjson/haswell/intrinsics.h */ -// -// The rest need to be inside the region -// -/* begin file include/simdjson/haswell/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "haswell" -// #define SIMDJSON_IMPLEMENTATION haswell -SIMDJSON_TARGET_HASWELL -/* end file include/simdjson/haswell/begin.h */ +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_TARGET_REGION("avx2,bmi,pclmul,lzcnt,popcnt") +#endif -// Declarations -/* begin file include/simdjson/generic/dom_parser_implementation.h */ - -namespace simdjson { - namespace haswell { - - // expectation: sizeof(open_container) = 64/8. - struct open_container { - uint32_t tape_index; // where, on the tape, does the scope ([,{) begins - uint32_t count; // how many elements in the scope - }; // struct open_container - - static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); - - class dom_parser_implementation final : public internal::dom_parser_implementation { - public: - /** Tape location of each open { or [ */ - std::unique_ptr open_containers{}; - /** Whether each open container is a [ or { */ - std::unique_ptr is_array{}; - /** Buffer passed to stage 1 */ - const uint8_t* buf{}; - /** Length passed to stage 1 */ - size_t len{ 0 }; - /** Document passed to stage 2 */ - dom::document* doc{}; - - inline dom_parser_implementation() noexcept; - inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; - inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; - dom_parser_implementation(const dom_parser_implementation&) = delete; - dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; - - simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; - simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; - simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; - simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; - inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; - inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; - private: - simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); - - }; - - } // namespace haswell -} // namespace simdjson - -namespace simdjson { - namespace haswell { - - inline dom_parser_implementation::dom_parser_implementation() noexcept = default; - inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; - inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; - - // Leaving these here so they can be inlined if so desired - inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { - if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } - // Stage 1 index output - size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; - structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); - if (!structural_indexes) { _capacity = 0; return MEMALLOC; } - structural_indexes[0] = 0; - n_structural_indexes = 0; - - _capacity = capacity; - return SUCCESS; - } - - inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { - // Stage 2 stacks - open_containers.reset(new (std::nothrow) open_container[max_depth]); - is_array.reset(new (std::nothrow) bool[max_depth]); - if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } - - _max_depth = max_depth; - return SUCCESS; - } - - } // namespace haswell -} // namespace simdjson -/* end file include/simdjson/generic/dom_parser_implementation.h */ -/* begin file include/simdjson/haswell/bitmanipulation.h */ +/* including simdjson/haswell/bitmanipulation.h: #include "simdjson/haswell/bitmanipulation.h" */ +/* begin file simdjson/haswell/bitmanipulation.h */ #ifndef SIMDJSON_HASWELL_BITMANIPULATION_H #define SIMDJSON_HASWELL_BITMANIPULATION_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmask.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace haswell { namespace { @@ -16340,7 +15369,7 @@ namespace simdjson { #if SIMDJSON_REGULAR_VISUAL_STUDIO simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { - // note: we do not support legacy 32-bit Windows + // note: we do not support legacy 32-bit Windows in this kernel return __popcnt64(input_num);// Visual Studio wants two underscores } #else @@ -16365,11 +15394,17 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_HASWELL_BITMANIPULATION_H -/* end file include/simdjson/haswell/bitmanipulation.h */ -/* begin file include/simdjson/haswell/bitmask.h */ +/* end file simdjson/haswell/bitmanipulation.h */ +/* including simdjson/haswell/bitmask.h: #include "simdjson/haswell/bitmask.h" */ +/* begin file simdjson/haswell/bitmask.h */ #ifndef SIMDJSON_HASWELL_BITMASK_H #define SIMDJSON_HASWELL_BITMASK_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace haswell { namespace { @@ -16392,11 +15427,82 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_HASWELL_BITMASK_H -/* end file include/simdjson/haswell/bitmask.h */ -/* begin file include/simdjson/haswell/simd.h */ +/* end file simdjson/haswell/bitmask.h */ +/* including simdjson/haswell/numberparsing_defs.h: #include "simdjson/haswell/numberparsing_defs.h" */ +/* begin file simdjson/haswell/numberparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +#define SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace haswell +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +/* end file simdjson/haswell/numberparsing_defs.h */ +/* including simdjson/haswell/simd.h: #include "simdjson/haswell/simd.h" */ +/* begin file simdjson/haswell/simd.h */ #ifndef SIMDJSON_HASWELL_SIMD_H #define SIMDJSON_HASWELL_SIMD_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace haswell { @@ -16760,8 +15866,124 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_HASWELL_SIMD_H -/* end file include/simdjson/haswell/simd.h */ -/* begin file include/simdjson/generic/jsoncharutils.h */ +/* end file simdjson/haswell/simd.h */ +/* including simdjson/haswell/stringparsing_defs.h: #include "simdjson/haswell/stringparsing_defs.h" */ +/* begin file simdjson/haswell/stringparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +#define SIMDJSON_HASWELL_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast((v == '\\').to_bitmask()), // bs_bits + static_cast((v == '"').to_bitmask()), // quote_bits + }; + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +/* end file simdjson/haswell/stringparsing_defs.h */ +/* end file simdjson/haswell/begin.h */ +/* including simdjson/generic/amalgamated.h for haswell: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for haswell */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for haswell: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for haswell */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for haswell */ +/* including simdjson/generic/jsoncharutils.h for haswell: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for haswell */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace haswell { @@ -16854,32 +16076,25 @@ namespace simdjson { } #endif - using internal::value128; - - simdjson_inline value128 full_multiplication(uint64_t value1, uint64_t value2) { - value128 answer; -#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS -#ifdef _M_ARM64 - // ARM64 has native support for 64-bit multiplications, no need to emultate - answer.high = __umulh(value1, value2); - answer.low = value1 * value2; -#else - answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 -#endif // _M_ARM64 -#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS - __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; - answer.low = uint64_t(r); - answer.high = uint64_t(r >> 64); -#endif - return answer; - } - } // namespace jsoncharutils } // unnamed namespace } // namespace haswell } // namespace simdjson -/* end file include/simdjson/generic/jsoncharutils.h */ -/* begin file include/simdjson/generic/atomparsing.h */ + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for haswell */ +/* including simdjson/generic/atomparsing.h for haswell: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for haswell */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + namespace simdjson { namespace haswell { namespace { @@ -16945,106 +16160,256 @@ namespace simdjson { } // unnamed namespace } // namespace haswell } // namespace simdjson -/* end file include/simdjson/generic/atomparsing.h */ -/* begin file include/simdjson/haswell/stringparsing.h */ -#ifndef SIMDJSON_HASWELL_STRINGPARSING_H -#define SIMDJSON_HASWELL_STRINGPARSING_H +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for haswell */ +/* including simdjson/generic/dom_parser_implementation.h for haswell: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for haswell */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace haswell { - namespace { - using namespace simd; + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container - // Holds backslashes and quotes locations. - struct backslash_and_quote { - public: - static constexpr uint32_t BYTES_PROCESSED = 32; - simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); - simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } - simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } - simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } - simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; - uint32_t bs_bits; - uint32_t quote_bits; - }; // struct backslash_and_quote + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; - simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { - // this can read up to 15 bytes beyond the buffer size, but we require - // SIMDJSON_PADDING of padding - static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); - simd8 v(src); - // store to dest unconditionally - we can overwrite the bits we don't like later - v.store(dst); - return { - static_cast((v == '\\').to_bitmask()), // bs_bits - static_cast((v == '"').to_bitmask()), // quote_bits - }; - } + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; - } // unnamed namespace } // namespace haswell } // namespace simdjson -#endif // SIMDJSON_HASWELL_STRINGPARSING_H -/* end file include/simdjson/haswell/stringparsing.h */ -/* begin file include/simdjson/haswell/numberparsing.h */ -#ifndef SIMDJSON_HASWELL_NUMBERPARSING_H -#define SIMDJSON_HASWELL_NUMBERPARSING_H - -namespace simdjson { - namespace haswell { - namespace { - - static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { - // this actually computes *16* values so we are being wasteful. - const __m128i ascii0 = _mm_set1_epi8('0'); - const __m128i mul_1_10 = - _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); - const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); - const __m128i mul_1_10000 = - _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); - const __m128i input = _mm_sub_epi8( - _mm_loadu_si128(reinterpret_cast(chars)), ascii0); - const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); - const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); - const __m128i t3 = _mm_packus_epi32(t2, t2); - const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); - return _mm_cvtsi128_si32( - t4); // only captures the sum of the first 8 digits, drop the rest - } - - } // unnamed namespace - } // namespace haswell -} // namespace simdjson - -#define SIMDJSON_SWAR_NUMBER_PARSING 1 - -/* begin file include/simdjson/generic/numberparsing.h */ -#include - namespace simdjson { namespace haswell { - namespace ondemand { - /** - * The type of a JSON number - */ - enum class number_type { - floating_point_number = 1, /// a binary64 number - signed_integer, /// a signed integer that fits in a 64-bit word using two's complement - unsigned_integer /// a positive integer larger or equal to 1<<63 - }; + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; } - namespace { - /// @private - namespace numberparsing { + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for haswell */ +/* including simdjson/generic/implementation_simdjson_result_base.h for haswell: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for haswell */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for haswell */ +/* including simdjson/generic/numberparsing.h for haswell: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for haswell */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace haswell { + namespace numberparsing { #ifdef JSON_TEST_NUMBERS #define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) @@ -17058,19 +16423,20 @@ namespace simdjson { #define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) #endif - namespace { - // Convert a mantissa, an exponent and a sign bit into an ieee64 double. - // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). - // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. - simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { - double d; - mantissa &= ~(1ULL << 52); - mantissa |= real_exponent << 52; - mantissa |= ((static_cast(negative)) << 63); - std::memcpy(&d, &mantissa, sizeof(d)); - return d; - } + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; } + // Attempts to compute i * 10^(power) exactly; and if "negative" is // true, negate the result. // This function will only work in some cases, when it does not work, success is @@ -17087,10 +16453,11 @@ namespace simdjson { #endif #if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) // We cannot be certain that x/y is rounded to nearest. - if (0 <= power && power <= 22 && i <= 9007199254740991) { + if (0 <= power && power <= 22 && i <= 9007199254740991) #else - if (-22 <= power && power <= 22 && i <= 9007199254740991) { + if (-22 <= power && power <= 22 && i <= 9007199254740991) #endif + { // convert the integer into a double. This is lossless since // 0 <= i <= 2^53 - 1. d = double(i); @@ -17195,7 +16562,7 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 firstproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index]); + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); // Both i and power_of_five_128[index] have their most significant bit set to 1 which // implies that the either the most or the second most significant bit of the product // is 1. We pack values in this manner for efficiency reasons: it maximizes the use @@ -17216,8 +16583,7 @@ namespace simdjson { // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q // to the desired approximation using one multiplication. Sometimes it does not suffice. // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and - // then we get a better approximation to i * 5^q. In very rare cases, even that - // will not suffice, though it is seemingly very hard to find such a scenario. + // then we get a better approximation to i * 5^q. // // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat // more complicated. @@ -17229,15 +16595,12 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 secondproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); firstproduct.low += secondproduct.high; if (secondproduct.high > firstproduct.low) { firstproduct.high++; } - // At this point, we might need to add at most one to firstproduct, but this - // can only change the value of firstproduct.high if firstproduct.low is maximal. - if (simdjson_unlikely(firstproduct.low == 0xFFFFFFFFFFFFFFFF)) { - // This is very unlikely, but if so, we need to do much more work! - return false; - } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. } uint64_t lower = firstproduct.low; uint64_t upper = firstproduct.high; @@ -17320,7 +16683,7 @@ namespace simdjson { } d = to_double(mantissa, real_exponent, negative); return true; - } + } // We call a fallback floating-point parser that might be slow. Note // it will accept JSON numbers, but the JSON spec. is more restrictive so @@ -17329,7 +16692,7 @@ namespace simdjson { // It will return an error (false) if the parsed number is infinite. // The string parsing itself always succeeds. We know that there is at least // one digit. - static bool parse_float_fallback(const uint8_t * ptr, double* outDouble) { + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); // We do not accept infinite values. @@ -17343,7 +16706,8 @@ namespace simdjson { // to handle that max may be a macro on windows). return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); } - static bool parse_float_fallback(const uint8_t * ptr, const uint8_t * end_ptr, double* outDouble) { + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); // We do not accept infinite values. @@ -17361,7 +16725,7 @@ namespace simdjson { // check quickly whether the next 8 chars are made of digits // at a glance, it looks better than Mula's // http://0x80.pl/articles/swar-digits-validate.html - simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t * chars) { + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { uint64_t val; // this can read up to 7 bytes beyond the buffer size, but we require // SIMDJSON_PADDING of padding @@ -17376,19 +16740,9 @@ namespace simdjson { 0x3333333333333333); } - template - error_code slow_float_parsing(simdjson_unused const uint8_t * src, W writer) { - double d; - if (parse_float_fallback(src, &d)) { - writer.append_double(d); - return SUCCESS; - } - return INVALID_NUMBER(src); - } - template SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later - simdjson_inline bool parse_digit(const uint8_t c, I & i) { + simdjson_inline bool parse_digit(const uint8_t c, I& i) { const uint8_t digit = static_cast(c - '0'); if (digit > 9) { return false; @@ -17398,7 +16752,7 @@ namespace simdjson { return true; } - simdjson_inline error_code parse_decimal(simdjson_unused const uint8_t* const src, const uint8_t * &p, uint64_t & i, int64_t & exponent) { + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { // we continue with the fiction that we have an integer. If the // floating point number is representable as x * 10^z for some integer // z that fits in 53 bits, then we will be able to convert back the @@ -17426,7 +16780,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t * &p, int64_t & exponent) { + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { // Exp Sign: -123.456e[-]78 bool neg_exp = ('-' == *p); if (neg_exp || '+' == *p) { p++; } // Skip + as well @@ -17477,7 +16831,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline size_t significant_digits(const uint8_t * start_digits, size_t digit_count) { + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { // It is possible that the integer had an overflow. // We have to handle the case where we have 0.0000somenumber. const uint8_t* start = start_digits; @@ -17486,79 +16840,93 @@ namespace simdjson { return digit_count - size_t(start - start_digits); } - template - simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t * start_digits, size_t digit_count, int64_t exponent, W & writer) { - // If we frequently had to deal with long strings of digits, - // we could extend our code by using a 128-bit integer instead - // of a 64-bit integer. However, this is uncommon in practice. - // - // 9999999999999999999 < 2**64 so we can accommodate 19 digits. - // If we have a decimal separator, then digit_count - 1 is the number of digits, but we - // may not have a decimal separator! - if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { - // Ok, chances are good that we had an overflow! - // this is almost never going to get called!!! - // we start anew, going slowly!!! - // This will happen in the following examples: - // 10000000000000000000000000000000000000000000e+308 - // 3.1415926535897932384626433832795028841971693993751 - // - // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens - // because slow_float_parsing is a non-inlined function. If we passed our writer reference to - // it, it would force it to be stored in memory, preventing the compiler from picking it apart - // and putting into registers. i.e. if we pass it as reference, it gets slow. - // This is what forces the skip_double, as well. - error_code error = slow_float_parsing(src, writer); - writer.skip_double(); - return error; - } - // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other - // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 - // To future reader: we'd love if someone found a better way, or at least could explain this result! - if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { - // - // Important: smallest_power is such that it leads to a zero value. - // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero - // so something x 10^-343 goes to zero, but not so with something x 10^-342. - static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); - // - if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { - // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero - WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); - return SUCCESS; - } - else { // (exponent > largest_power) and (i != 0) - // We have, for sure, an infinite value and simdjson refuses to parse infinite values. - return INVALID_NUMBER(src); - } - } - double d; - if (!compute_float_64(exponent, i, negative, d)) { - // we are almost never going to get here. - if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } - } - WRITE_DOUBLE(d, src, writer); + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); return SUCCESS; } + return INVALID_NUMBER(src); + } - // for performance analysis, it is sometimes useful to skip parsing + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing #ifdef SIMDJSON_SKIPNUMBERPARSING - template - simdjson_inline error_code parse_number(const uint8_t* const, W & writer) { - writer.append_s64(0); // always write zero - return SUCCESS; // always succeeds - } + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t * src) noexcept { return ondemand::number_type::signed_integer; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } #else // parse the number at src @@ -17570,9 +16938,308 @@ namespace simdjson { // content and append a space before calling this function. // // Our objective is accurate parsing (ULP of 0) at high speed. - template - simdjson_inline error_code parse_number(const uint8_t* const src, W & writer) { + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { // // Check for minus sign // @@ -17590,774 +17257,1476 @@ namespace simdjson { // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. // Optimization note: size_t is expected to be unsigned. size_t digit_count = size_t(p - start_digits); - if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } - - // - // Handle floats if there is a . or e (or both) - // - int64_t exponent = 0; - bool is_float = false; - if ('.' == *p) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_decimal(src, p, i, exponent)); - digit_count = int(p - start_digits); // used later to guard against overflows - } - if (('e' == *p) || ('E' == *p)) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_exponent(src, p, exponent)); - } - if (is_float) { - const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); - SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); - if (dirty_end) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // The longest negative 64-bit number is 19 digits. - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - size_t longest_digit_count = negative ? 19 : 20; - if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } - if (digit_count == longest_digit_count) { - if (negative) { - // Anything negative above INT64_MAX+1 is invalid - if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } - WRITE_INTEGER(~i + 1, src, writer); - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - } - else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } - } - - // Write unsigned if it doesn't fit in a signed integer. - if (i > uint64_t(INT64_MAX)) { - WRITE_UNSIGNED(i, src, writer); - } - else { - WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); - } - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; } - // Inlineable functions - namespace { + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); - // This table can be used to characterize the final character of an integer - // string. For JSON structural character and allowable white space characters, - // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise - // we return NUMBER_ERROR. - // Optimization note: we could easily reduce the size of the table by half (to 128) - // at the cost of an extra branch. - // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): - static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } - const uint8_t integer_string_finisher[256] = { - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR }; + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - - return i; + } + else { + overflow = p - src > 19; } + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // Parse any number from 0 to 18,446,744,073,709,551,615 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + exponent += exp_neg ? 0 - exp : exp; } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { - const uint8_t* p = src + 1; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*p != '"') { return NUMBER_ERROR; } + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - // Note: we use src[1] and not src[0] because src[0] is the quote character in this - // instance. - if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; } + return d; + } - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { - // - // Check for minus sign - // - if (src == src_end) { return NUMBER_ERROR; } - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = src; - uint64_t i = 0; - while (parse_digit(*src, i)) { src++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(src - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*src)) { - // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*src != '"') { return NUMBER_ERROR; } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; } } - else { - overflow = p - src > 19; + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; + } + else { + overflow = p - src > 19; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { - return (*src == '-'); - } - - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } - return false; - } - - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { - // We have an integer. - // If the number is negative and valid, it must be a signed integer. - if (negative) { return ondemand::number_type::signed_integer; } - // We want values larger or equal to 9223372036854775808 to be unsigned - // integers, and the other values to be signed integers. - int digit_count = int(p - src); - if (digit_count >= 19) { - const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); - if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { - return ondemand::number_type::unsigned_integer; - } - } - return ondemand::number_type::signed_integer; - } - // Hopefully, we have 'e' or 'E' or '.'. - return ondemand::number_type::floating_point_number; - } - - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { - if (src == src_end) { return NUMBER_ERROR; } - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; if (p == src_end) { return NUMBER_ERROR; } - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while ((p != src_end) && parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely((p != src_end) && (*p == '.'))) { - p++; - const uint8_t* start_decimal_digits = p; - if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if ((p != src_end) && (*p == 'e' || *p == 'E')) { - p++; - if (p == src_end) { return NUMBER_ERROR; } - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while ((p != src_end) && parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { - return NUMBER_ERROR; - } - return d; + exponent += exp_neg ? 0 - exp : exp; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + exponent = -(p - start_decimal_digits); - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (*p != '"') { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; } - } //namespace {} + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace #endif // SIMDJSON_SKIPNUMBERPARSING - } // namespace numberparsing - } // unnamed namespace - } // namespace haswell - } // namespace simdjson - /* end file include/simdjson/generic/numberparsing.h */ + } // namespace numberparsing -#endif // SIMDJSON_HASWELL_NUMBERPARSING_H -/* end file include/simdjson/haswell/numberparsing.h */ -/* begin file include/simdjson/haswell/end.h */ -SIMDJSON_UNTARGET_HASWELL -/* end file include/simdjson/haswell/end.h */ + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } -#endif // SIMDJSON_IMPLEMENTATION_HASWELL -#endif // SIMDJSON_HASWELL_COMMON_H -/* end file include/simdjson/haswell.h */ -/* begin file include/simdjson/ppc64.h */ -#ifndef SIMDJSON_PPC64_H -#define SIMDJSON_PPC64_H + } // namespace haswell +} // namespace simdjson +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for haswell */ -#if SIMDJSON_IMPLEMENTATION_PPC64 +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for haswell: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for haswell */ +/* end file simdjson/generic/amalgamated.h for haswell */ +/* including simdjson/haswell/end.h: #include "simdjson/haswell/end.h" */ +/* begin file simdjson/haswell/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "haswell" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/haswell/end.h */ + +#endif // SIMDJSON_HASWELL_H +/* end file simdjson/haswell.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(icelake) +/* including simdjson/icelake.h: #include "simdjson/icelake.h" */ +/* begin file simdjson/icelake.h */ +#ifndef SIMDJSON_ICELAKE_H +#define SIMDJSON_ICELAKE_H + +/* including simdjson/icelake/begin.h: #include "simdjson/icelake/begin.h" */ +/* begin file simdjson/icelake/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "icelake" */ +#define SIMDJSON_IMPLEMENTATION icelake +/* including simdjson/icelake/base.h: #include "simdjson/icelake/base.h" */ +/* begin file simdjson/icelake/base.h */ +#ifndef SIMDJSON_ICELAKE_BASE_H +#define SIMDJSON_ICELAKE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE namespace simdjson { /** - * Implementation for ALTIVEC (PPC64). + * Implementation for Icelake (Intel AVX512). */ - namespace ppc64 { - } // namespace ppc64 + namespace icelake { + + class implementation; + + } // namespace icelake } // namespace simdjson -/* begin file include/simdjson/ppc64/implementation.h */ -#ifndef SIMDJSON_PPC64_IMPLEMENTATION_H -#define SIMDJSON_PPC64_IMPLEMENTATION_H +#endif // SIMDJSON_ICELAKE_BASE_H +/* end file simdjson/icelake/base.h */ +/* including simdjson/icelake/intrinsics.h: #include "simdjson/icelake/intrinsics.h" */ +/* begin file simdjson/icelake/intrinsics.h */ +#ifndef SIMDJSON_ICELAKE_INTRINSICS_H +#define SIMDJSON_ICELAKE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + * e.g., if __AVX2__ is set... in turn, we normally set these + * macros by compiling against the corresponding architecture + * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole + * software with these advanced instructions. In simdjson, we + * want to compile the whole program for a generic target, + * and only target our specific kernels. As a workaround, + * we directly include the needed headers. These headers would + * normally guard against such usage, but we carefully included + * (or ) before, so the headers + * are fooled. + */ +#include // for _blsr_u64 +#include // for __lzcnt64 +#include // for most things (AVX2, AVX512, _popcnt64) +#include +#include +#include +#include +#include // for _mm_clmulepi64_si128 + // Important: we need the AVX-512 headers: +#include +#include +#include +#include +#include +#include +#include +// unfortunately, we may not get _blsr_u64, but, thankfully, clang +// has it as a macro. +#ifndef _blsr_u64 +// we roll our own +#define _blsr_u64(n) ((n - 1) & n) +#endif // _blsr_u64 +#endif // SIMDJSON_CLANG_VISUAL_STUDIO + +static_assert(sizeof(__m512i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for icelake"); + +#endif // SIMDJSON_ICELAKE_INTRINSICS_H +/* end file simdjson/icelake/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_TARGET_REGION("avx512f,avx512dq,avx512cd,avx512bw,avx512vbmi,avx512vbmi2,avx512vl,avx2,bmi,pclmul,lzcnt,popcnt") +#endif + +/* including simdjson/icelake/bitmanipulation.h: #include "simdjson/icelake/bitmanipulation.h" */ +/* begin file simdjson/icelake/bitmanipulation.h */ +#ifndef SIMDJSON_ICELAKE_BITMANIPULATION_H +#define SIMDJSON_ICELAKE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return (int)_tzcnt_u64(input_num); +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + //////// + // You might expect the next line to be equivalent to + // return (int)_tzcnt_u64(input_num); + // but the generated code differs and might be less efficient? + //////// + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return _blsr_u64(input_num); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { + return int(_lzcnt_u64(input_num)); + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMANIPULATION_H +/* end file simdjson/icelake/bitmanipulation.h */ +/* including simdjson/icelake/bitmask.h: #include "simdjson/icelake/bitmask.h" */ +/* begin file simdjson/icelake/bitmask.h */ +#ifndef SIMDJSON_ICELAKE_BITMASK_H +#define SIMDJSON_ICELAKE_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processor supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMASK_H +/* end file simdjson/icelake/bitmask.h */ +/* including simdjson/icelake/simd.h: #include "simdjson/icelake/simd.h" */ +/* begin file simdjson/icelake/simd.h */ +#ifndef SIMDJSON_ICELAKE_SIMD_H +#define SIMDJSON_ICELAKE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if defined(__GNUC__) && !defined(__clang__) +#if __GNUC__ == 8 +#define SIMDJSON_GCC8 1 +#endif // __GNUC__ == 8 +#endif // defined(__GNUC__) && !defined(__clang__) + +#if SIMDJSON_GCC8 +/** + * GCC 8 fails to provide _mm512_set_epi8. We roll our own. + */ +inline __m512i _mm512_set_epi8(uint8_t a0, uint8_t a1, uint8_t a2, uint8_t a3, uint8_t a4, uint8_t a5, uint8_t a6, uint8_t a7, uint8_t a8, uint8_t a9, uint8_t a10, uint8_t a11, uint8_t a12, uint8_t a13, uint8_t a14, uint8_t a15, uint8_t a16, uint8_t a17, uint8_t a18, uint8_t a19, uint8_t a20, uint8_t a21, uint8_t a22, uint8_t a23, uint8_t a24, uint8_t a25, uint8_t a26, uint8_t a27, uint8_t a28, uint8_t a29, uint8_t a30, uint8_t a31, uint8_t a32, uint8_t a33, uint8_t a34, uint8_t a35, uint8_t a36, uint8_t a37, uint8_t a38, uint8_t a39, uint8_t a40, uint8_t a41, uint8_t a42, uint8_t a43, uint8_t a44, uint8_t a45, uint8_t a46, uint8_t a47, uint8_t a48, uint8_t a49, uint8_t a50, uint8_t a51, uint8_t a52, uint8_t a53, uint8_t a54, uint8_t a55, uint8_t a56, uint8_t a57, uint8_t a58, uint8_t a59, uint8_t a60, uint8_t a61, uint8_t a62, uint8_t a63) { + return _mm512_set_epi64(uint64_t(a7) + (uint64_t(a6) << 8) + (uint64_t(a5) << 16) + (uint64_t(a4) << 24) + (uint64_t(a3) << 32) + (uint64_t(a2) << 40) + (uint64_t(a1) << 48) + (uint64_t(a0) << 56), + uint64_t(a15) + (uint64_t(a14) << 8) + (uint64_t(a13) << 16) + (uint64_t(a12) << 24) + (uint64_t(a11) << 32) + (uint64_t(a10) << 40) + (uint64_t(a9) << 48) + (uint64_t(a8) << 56), + uint64_t(a23) + (uint64_t(a22) << 8) + (uint64_t(a21) << 16) + (uint64_t(a20) << 24) + (uint64_t(a19) << 32) + (uint64_t(a18) << 40) + (uint64_t(a17) << 48) + (uint64_t(a16) << 56), + uint64_t(a31) + (uint64_t(a30) << 8) + (uint64_t(a29) << 16) + (uint64_t(a28) << 24) + (uint64_t(a27) << 32) + (uint64_t(a26) << 40) + (uint64_t(a25) << 48) + (uint64_t(a24) << 56), + uint64_t(a39) + (uint64_t(a38) << 8) + (uint64_t(a37) << 16) + (uint64_t(a36) << 24) + (uint64_t(a35) << 32) + (uint64_t(a34) << 40) + (uint64_t(a33) << 48) + (uint64_t(a32) << 56), + uint64_t(a47) + (uint64_t(a46) << 8) + (uint64_t(a45) << 16) + (uint64_t(a44) << 24) + (uint64_t(a43) << 32) + (uint64_t(a42) << 40) + (uint64_t(a41) << 48) + (uint64_t(a40) << 56), + uint64_t(a55) + (uint64_t(a54) << 8) + (uint64_t(a53) << 16) + (uint64_t(a52) << 24) + (uint64_t(a51) << 32) + (uint64_t(a50) << 40) + (uint64_t(a49) << 48) + (uint64_t(a48) << 56), + uint64_t(a63) + (uint64_t(a62) << 8) + (uint64_t(a61) << 16) + (uint64_t(a60) << 24) + (uint64_t(a59) << 32) + (uint64_t(a58) << 40) + (uint64_t(a57) << 48) + (uint64_t(a56) << 56)); +} +#endif // SIMDJSON_GCC8 + namespace simdjson { - namespace ppc64 { - + namespace icelake { namespace { - using namespace simdjson; - using namespace simdjson::dom; - } // namespace + namespace simd { + + // Forward-declared so they can be used by splat and friends. + template + struct base { + __m512i value; + + // Zero constructor + simdjson_inline base() : value{ __m512i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m512i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m512i& () const { return this->value; } + simdjson_inline operator __m512i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm512_or_si512(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm512_and_si512(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm512_xor_si512(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm512_andnot_si512(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + // Forward-declared so they can be used by splat and friends. + template + struct simd8; + + template> + struct base8 : base> { + typedef uint32_t bitmask_t; + typedef uint64_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m512i _value) : base>(_value) {} + + friend simdjson_really_inline uint64_t operator==(const simd8 lhs, const simd8 rhs) { + return _mm512_cmpeq_epi8_mask(lhs, rhs); + } + + static const int SIZE = sizeof(base::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + // workaround for compilers unable to figure out that 16 - N is a constant (GCC 8) + constexpr int shift = 16 - N; + return _mm512_alignr_epi8(*this, _mm512_permutex2var_epi64(prev_chunk, _mm512_set_epi64(13, 12, 11, 10, 9, 8, 7, 6), *this), shift); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm512_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m512i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + simdjson_inline bool any() const { return !!_mm512_test_epi8_mask(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm512_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm512_setzero_si512(); } + static simdjson_inline simd8 load(const T values[64]) { + return _mm512_loadu_si512(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m512i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[64]) const { return _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), *this); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm512_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm512_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm512_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint64_t mask, L* output) const { + _mm512_mask_compressstoreu_epi8(output, ~mask, *this); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, + int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, + int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31, + int8_t v32, int8_t v33, int8_t v34, int8_t v35, int8_t v36, int8_t v37, int8_t v38, int8_t v39, + int8_t v40, int8_t v41, int8_t v42, int8_t v43, int8_t v44, int8_t v45, int8_t v46, int8_t v47, + int8_t v48, int8_t v49, int8_t v50, int8_t v51, int8_t v52, int8_t v53, int8_t v54, int8_t v55, + int8_t v56, int8_t v57, int8_t v58, int8_t v59, int8_t v60, int8_t v61, int8_t v62, int8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epi8(*this, other); } + + simdjson_inline simd8 operator>(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(*this, other), _mm512_set1_epi8(uint8_t(0x80))); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(other, *this), _mm512_set1_epi8(uint8_t(0x80))); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, + uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, + uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31, + uint8_t v32, uint8_t v33, uint8_t v34, uint8_t v35, uint8_t v36, uint8_t v37, uint8_t v38, uint8_t v39, + uint8_t v40, uint8_t v41, uint8_t v42, uint8_t v43, uint8_t v44, uint8_t v45, uint8_t v46, uint8_t v47, + uint8_t v48, uint8_t v49, uint8_t v50, uint8_t v51, uint8_t v52, uint8_t v53, uint8_t v54, uint8_t v55, + uint8_t v56, uint8_t v57, uint8_t v58, uint8_t v59, uint8_t v60, uint8_t v61, uint8_t v62, uint8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm512_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm512_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epu8(other, *this); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline uint64_t operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline uint64_t operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return _mm512_mask_blend_epi8(*this == uint8_t(0), _mm512_set1_epi8(0), _mm512_set1_epi8(-1)); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + + simdjson_inline bool is_ascii() const { return _mm512_movepi8_mask(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { + return !_mm512_test_epi8_mask(*this, *this); + } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return !_mm512_test_epi8_mask(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm512_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm512_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline uint64_t get_bit() const { return _mm512_movepi8_mask(_mm512_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 1, "Icelake kernel should use one register per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} + simdjson_inline simd8x64(const simd8 chunk0) : chunks{ chunk0 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr) } {} + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(mask, output); + return 64 - count_ones(mask); + } + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + } + + simdjson_inline simd8 reduce_or() const { + return this->chunks[0]; + } + + simdjson_inline simd8x64 bit_or(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] | mask + ); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] == mask; + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return this->chunks[0] == other.chunks[0]; + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] <= mask; + } + }; // struct simd8x64 + + } // namespace simd + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_SIMD_H +/* end file simdjson/icelake/simd.h */ +/* including simdjson/icelake/stringparsing_defs.h: #include "simdjson/icelake/stringparsing_defs.h" */ +/* begin file simdjson/icelake/stringparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +#define SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 64; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint64_t bs_bits; + uint64_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast(v == '\\'), // bs_bits + static_cast(v == '"'), // quote_bits + }; + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +/* end file simdjson/icelake/stringparsing_defs.h */ +/* including simdjson/icelake/numberparsing_defs.h: #include "simdjson/icelake/numberparsing_defs.h" */ +/* begin file simdjson/icelake/numberparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +#define SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace numberparsing { + + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace icelake +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +/* end file simdjson/icelake/numberparsing_defs.h */ +/* end file simdjson/icelake/begin.h */ +/* including simdjson/generic/amalgamated.h for icelake: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for icelake */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for icelake: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for icelake */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + + struct open_container; + class dom_parser_implementation; /** - * @private + * The type of a JSON number */ - class implementation final : public simdjson::implementation { - public: - simdjson_inline implementation() - : simdjson::implementation("ppc64", "PPC64 ALTIVEC", - internal::instruction_set::ALTIVEC) {} - simdjson_warn_unused error_code create_dom_parser_implementation( - size_t capacity, size_t max_length, - std::unique_ptr& dst) - const noexcept final; - simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, - uint8_t* dst, - size_t& dst_len) const noexcept final; - simdjson_warn_unused bool validate_utf8(const char* buf, - size_t len) const noexcept final; + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 }; - } // namespace ppc64 + } // namespace icelake } // namespace simdjson -#endif // SIMDJSON_PPC64_IMPLEMENTATION_H -/* end file include/simdjson/ppc64/implementation.h */ +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for icelake */ +/* including simdjson/generic/jsoncharutils.h for icelake: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for icelake */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H -/* begin file include/simdjson/ppc64/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "ppc64" -// #define SIMDJSON_IMPLEMENTATION ppc64 -/* end file include/simdjson/ppc64/begin.h */ - -// Declarations -/* begin file include/simdjson/generic/dom_parser_implementation.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace ppc64 { + namespace icelake { + namespace { + namespace jsoncharutils { + + // return non-zero if not a structural or whitespace char + // zero otherwise + simdjson_inline uint32_t is_not_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace_negated[c]; + } + + simdjson_inline uint32_t is_structural_or_whitespace(uint8_t c) { + return internal::structural_or_whitespace[c]; + } + + // returns a value with the high 16 bits set if not valid + // otherwise returns the conversion of the 4 hex digits at src into the bottom + // 16 bits of the 32-bit return register + // + // see + // https://lemire.me/blog/2019/04/17/parsing-short-hexadecimal-strings-efficiently/ + static inline uint32_t hex_to_u32_nocheck( + const uint8_t* src) { // strictly speaking, static inline is a C-ism + uint32_t v1 = internal::digit_to_val32[630 + src[0]]; + uint32_t v2 = internal::digit_to_val32[420 + src[1]]; + uint32_t v3 = internal::digit_to_val32[210 + src[2]]; + uint32_t v4 = internal::digit_to_val32[0 + src[3]]; + return v1 | v2 | v3 | v4; + } + + // given a code point cp, writes to c + // the utf-8 code, outputting the length in + // bytes, if the length is zero, the code point + // is invalid + // + // This can possibly be made faster using pdep + // and clz and table lookups, but JSON documents + // have few escaped code points, and the following + // function looks cheap. + // + // Note: we assume that surrogates are treated separately + // + simdjson_inline size_t codepoint_to_utf8(uint32_t cp, uint8_t* c) { + if (cp <= 0x7F) { + c[0] = uint8_t(cp); + return 1; // ascii + } + if (cp <= 0x7FF) { + c[0] = uint8_t((cp >> 6) + 192); + c[1] = uint8_t((cp & 63) + 128); + return 2; // universal plane + // Surrogates are treated elsewhere... + //} //else if (0xd800 <= cp && cp <= 0xdfff) { + // return 0; // surrogates // could put assert here + } + else if (cp <= 0xFFFF) { + c[0] = uint8_t((cp >> 12) + 224); + c[1] = uint8_t(((cp >> 6) & 63) + 128); + c[2] = uint8_t((cp & 63) + 128); + return 3; + } + else if (cp <= 0x10FFFF) { // if you know you have a valid code point, this + // is not needed + c[0] = uint8_t((cp >> 18) + 240); + c[1] = uint8_t(((cp >> 12) & 63) + 128); + c[2] = uint8_t(((cp >> 6) & 63) + 128); + c[3] = uint8_t((cp & 63) + 128); + return 4; + } + // will return 0 when the code point was too large. + return 0; // bad r + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + } // namespace jsoncharutils + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for icelake */ +/* including simdjson/generic/atomparsing.h for icelake: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for icelake */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace icelake { + namespace { + /// @private + namespace atomparsing { + + // The string_to_uint32 is exclusively used to map literal strings to 32-bit values. + // We use memcpy instead of a pointer cast to avoid undefined behaviors since we cannot + // be certain that the character pointer will be properly aligned. + // You might think that using memcpy makes this function expensive, but you'd be wrong. + // All decent optimizing compilers (GCC, clang, Visual Studio) will compile string_to_uint32("false"); + // to the compile-time constant 1936482662. + simdjson_inline uint32_t string_to_uint32(const char* str) { uint32_t val; std::memcpy(&val, str, sizeof(uint32_t)); return val; } + + + // Again in str4ncmp we use a memcpy to avoid undefined behavior. The memcpy may appear expensive. + // Yet all decent optimizing compilers will compile memcpy to a single instruction, just about. + simdjson_warn_unused + simdjson_inline uint32_t str4ncmp(const uint8_t* src, const char* atom) { + uint32_t srcval; // we want to avoid unaligned 32-bit loads (undefined in C/C++) + static_assert(sizeof(uint32_t) <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be larger than 4 bytes"); + std::memcpy(&srcval, src, sizeof(uint32_t)); + return srcval ^ string_to_uint32(atom); + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src) { + return (str4ncmp(src, "true") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_true_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_true_atom(src); } + else if (len == 4) { return !str4ncmp(src, "true"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src) { + return (str4ncmp(src + 1, "alse") | jsoncharutils::is_not_structural_or_whitespace(src[5])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_false_atom(const uint8_t* src, size_t len) { + if (len > 5) { return is_valid_false_atom(src); } + else if (len == 5) { return !str4ncmp(src + 1, "alse"); } + else { return false; } + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src) { + return (str4ncmp(src, "null") | jsoncharutils::is_not_structural_or_whitespace(src[4])) == 0; + } + + simdjson_warn_unused + simdjson_inline bool is_valid_null_atom(const uint8_t* src, size_t len) { + if (len > 4) { return is_valid_null_atom(src); } + else if (len == 4) { return !str4ncmp(src, "null"); } + else { return false; } + } + + } // namespace atomparsing + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for icelake */ +/* including simdjson/generic/dom_parser_implementation.h for icelake: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for icelake */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { // expectation: sizeof(open_container) = 64/8. struct open_container { @@ -18399,11 +18768,11 @@ namespace simdjson { }; - } // namespace ppc64 + } // namespace icelake } // namespace simdjson namespace simdjson { - namespace ppc64 { + namespace icelake { inline dom_parser_implementation::dom_parser_implementation() noexcept = default; inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; @@ -18433,13 +18802,1580 @@ namespace simdjson { return SUCCESS; } + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for icelake */ +/* including simdjson/generic/implementation_simdjson_result_base.h for icelake: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for icelake */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); + + +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for icelake */ +/* including simdjson/generic/numberparsing.h for icelake: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for icelake */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace icelake { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing +// +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. +// +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for icelake */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for icelake: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for icelake */ +/* end file simdjson/generic/amalgamated.h for icelake */ +/* including simdjson/icelake/end.h: #include "simdjson/icelake/end.h" */ +/* begin file simdjson/icelake/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "icelake" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/icelake/end.h */ + +#endif // SIMDJSON_ICELAKE_H +/* end file simdjson/icelake.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(ppc64) +/* including simdjson/ppc64.h: #include "simdjson/ppc64.h" */ +/* begin file simdjson/ppc64.h */ +#ifndef SIMDJSON_PPC64_H +#define SIMDJSON_PPC64_H + +/* including simdjson/ppc64/begin.h: #include "simdjson/ppc64/begin.h" */ +/* begin file simdjson/ppc64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "ppc64" */ +#define SIMDJSON_IMPLEMENTATION ppc64 +/* including simdjson/ppc64/base.h: #include "simdjson/ppc64/base.h" */ +/* begin file simdjson/ppc64/base.h */ +#ifndef SIMDJSON_PPC64_BASE_H +#define SIMDJSON_PPC64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for ALTIVEC (PPC64). + */ + namespace ppc64 { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + } // namespace ppc64 } // namespace simdjson -/* end file include/simdjson/generic/dom_parser_implementation.h */ -/* begin file include/simdjson/ppc64/intrinsics.h */ + +#endif // SIMDJSON_PPC64_BASE_H +/* end file simdjson/ppc64/base.h */ +/* including simdjson/ppc64/intrinsics.h: #include "simdjson/ppc64/intrinsics.h" */ +/* begin file simdjson/ppc64/intrinsics.h */ #ifndef SIMDJSON_PPC64_INTRINSICS_H #define SIMDJSON_PPC64_INTRINSICS_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ // This should be the correct header whether // you use visual studio or other compilers. @@ -18457,11 +20393,16 @@ namespace simdjson { static_assert(sizeof(__vector unsigned char) <= simdjson::SIMDJSON_PADDING, "insufficient padding for ppc64"); #endif // SIMDJSON_PPC64_INTRINSICS_H -/* end file include/simdjson/ppc64/intrinsics.h */ -/* begin file include/simdjson/ppc64/bitmanipulation.h */ +/* end file simdjson/ppc64/intrinsics.h */ +/* including simdjson/ppc64/bitmanipulation.h: #include "simdjson/ppc64/bitmanipulation.h" */ +/* begin file simdjson/ppc64/bitmanipulation.h */ #ifndef SIMDJSON_PPC64_BITMANIPULATION_H #define SIMDJSON_PPC64_BITMANIPULATION_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace ppc64 { namespace { @@ -18508,7 +20449,7 @@ namespace simdjson { #if SIMDJSON_REGULAR_VISUAL_STUDIO simdjson_inline int count_ones(uint64_t input_num) { - // note: we do not support legacy 32-bit Windows + // note: we do not support legacy 32-bit Windows in this kernel return __popcnt64(input_num); // Visual Studio wants two underscores } #else @@ -18533,11 +20474,16 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_PPC64_BITMANIPULATION_H -/* end file include/simdjson/ppc64/bitmanipulation.h */ -/* begin file include/simdjson/ppc64/bitmask.h */ +/* end file simdjson/ppc64/bitmanipulation.h */ +/* including simdjson/ppc64/bitmask.h: #include "simdjson/ppc64/bitmask.h" */ +/* begin file simdjson/ppc64/bitmask.h */ #ifndef SIMDJSON_PPC64_BITMASK_H #define SIMDJSON_PPC64_BITMASK_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace ppc64 { namespace { @@ -18577,11 +20523,86 @@ namespace simdjson { } // namespace simdjson #endif -/* end file include/simdjson/ppc64/bitmask.h */ -/* begin file include/simdjson/ppc64/simd.h */ +/* end file simdjson/ppc64/bitmask.h */ +/* including simdjson/ppc64/numberparsing_defs.h: #include "simdjson/ppc64/numberparsing_defs.h" */ +/* begin file simdjson/ppc64/numberparsing_defs.h */ +#ifndef SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +#define SIMDJSON_PPC64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if defined(__linux__) +#include +#elif defined(__FreeBSD__) +#include +#endif + +namespace simdjson { + namespace ppc64 { + namespace numberparsing { + + // we don't have appropriate instructions, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); +#ifdef __BIG_ENDIAN__ +#if defined(__linux__) + val = bswap_64(val); +#elif defined(__FreeBSD__) + val = bswap64(val); +#endif +#endif + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace ppc64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +/* end file simdjson/ppc64/numberparsing_defs.h */ +/* including simdjson/ppc64/simd.h: #include "simdjson/ppc64/simd.h" */ +/* begin file simdjson/ppc64/simd.h */ #ifndef SIMDJSON_PPC64_SIMD_H #define SIMDJSON_PPC64_SIMD_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + #include namespace simdjson { @@ -18636,9 +20657,6 @@ namespace simdjson { } }; - // Forward-declared so they can be used by splat and friends. - template struct simd8; - template > struct base8 : base> { typedef uint16_t bitmask_t; @@ -18674,7 +20692,7 @@ namespace simdjson { return (__m128i)vec_splats((unsigned char)(-(!!_value))); } - simdjson_inline simd8() : base8() {} + simdjson_inline simd8() : base8() {} simdjson_inline simd8(const __m128i _value) : base8(_value) {} // Splat constructor @@ -18834,36 +20852,36 @@ namespace simdjson { v8, v9, v10, v11, v12, v13, v14, v15 }) {} - // Repeat 16 values as many times as necessary (usually for lookup tables) - simdjson_inline static simd8 - repeat_16(int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, - int8_t v6, int8_t v7, int8_t v8, int8_t v9, int8_t v10, int8_t v11, - int8_t v12, int8_t v13, int8_t v14, int8_t v15) { - return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, - v13, v14, v15); - } + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, + int8_t v6, int8_t v7, int8_t v8, int8_t v9, int8_t v10, int8_t v11, + int8_t v12, int8_t v13, int8_t v14, int8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } - // Order-sensitive comparisons - simdjson_inline simd8 - max_val(const simd8 other) const { - return (__m128i)vec_max((__vector signed char)this->value, - (__vector signed char)(__m128i)other); - } - simdjson_inline simd8 - min_val(const simd8 other) const { - return (__m128i)vec_min((__vector signed char)this->value, - (__vector signed char)(__m128i)other); - } - simdjson_inline simd8 - operator>(const simd8 other) const { - return (__m128i)vec_cmpgt((__vector signed char)this->value, - (__vector signed char)(__m128i)other); - } - simdjson_inline simd8 - operator<(const simd8 other) const { - return (__m128i)vec_cmplt((__vector signed char)this->value, - (__vector signed char)(__m128i)other); - } + // Order-sensitive comparisons + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return (__m128i)vec_cmpgt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return (__m128i)vec_cmplt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } }; // Unsigned bytes @@ -18884,96 +20902,96 @@ namespace simdjson { v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, v14, v15 }) {} - // Repeat 16 values as many times as necessary (usually for lookup tables) - simdjson_inline static simd8 - repeat_16(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, - uint8_t v5, uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, - uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, - uint8_t v15) { - return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, - v13, v14, v15); - } + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, + uint8_t v5, uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, + uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, + uint8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } - // Saturated math - simdjson_inline simd8 - saturating_add(const simd8 other) const { - return (__m128i)vec_adds(this->value, (__m128i)other); - } - simdjson_inline simd8 - saturating_sub(const simd8 other) const { - return (__m128i)vec_subs(this->value, (__m128i)other); - } + // Saturated math + simdjson_inline simd8 + saturating_add(const simd8 other) const { + return (__m128i)vec_adds(this->value, (__m128i)other); + } + simdjson_inline simd8 + saturating_sub(const simd8 other) const { + return (__m128i)vec_subs(this->value, (__m128i)other); + } - // Order-specific operations - simdjson_inline simd8 - max_val(const simd8 other) const { - return (__m128i)vec_max(this->value, (__m128i)other); - } - simdjson_inline simd8 - min_val(const simd8 other) const { - return (__m128i)vec_min(this->value, (__m128i)other); - } - // Same as >, but only guarantees true is nonzero (< guarantees true = -1) - simdjson_inline simd8 - gt_bits(const simd8 other) const { - return this->saturating_sub(other); - } - // Same as <, but only guarantees true is nonzero (< guarantees true = -1) - simdjson_inline simd8 - lt_bits(const simd8 other) const { - return other.saturating_sub(*this); - } - simdjson_inline simd8 - operator<=(const simd8 other) const { - return other.max_val(*this) == other; - } - simdjson_inline simd8 - operator>=(const simd8 other) const { - return other.min_val(*this) == other; - } - simdjson_inline simd8 - operator>(const simd8 other) const { - return this->gt_bits(other).any_bits_set(); - } - simdjson_inline simd8 - operator<(const simd8 other) const { - return this->gt_bits(other).any_bits_set(); - } + // Order-specific operations + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max(this->value, (__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min(this->value, (__m128i)other); + } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + gt_bits(const simd8 other) const { + return this->saturating_sub(other); + } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + lt_bits(const simd8 other) const { + return other.saturating_sub(*this); + } + simdjson_inline simd8 + operator<=(const simd8 other) const { + return other.max_val(*this) == other; + } + simdjson_inline simd8 + operator>=(const simd8 other) const { + return other.min_val(*this) == other; + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } - // Bit-specific operations - simdjson_inline simd8 bits_not_set() const { - return (__m128i)vec_cmpeq(this->value, (__m128i)vec_splats(uint8_t(0))); - } - simdjson_inline simd8 bits_not_set(simd8 bits) const { - return (*this & bits).bits_not_set(); - } - simdjson_inline simd8 any_bits_set() const { - return ~this->bits_not_set(); - } - simdjson_inline simd8 any_bits_set(simd8 bits) const { - return ~this->bits_not_set(bits); - } - simdjson_inline bool bits_not_set_anywhere() const { - return vec_all_eq(this->value, (__m128i)vec_splats(0)); - } - simdjson_inline bool any_bits_set_anywhere() const { - return !bits_not_set_anywhere(); - } - simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { - return vec_all_eq(vec_and(this->value, (__m128i)bits), - (__m128i)vec_splats(0)); - } - simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { - return !bits_not_set_anywhere(bits); - } - template simdjson_inline simd8 shr() const { - return simd8( - (__m128i)vec_sr(this->value, (__m128i)vec_splat_u8(N))); - } - template simdjson_inline simd8 shl() const { - return simd8( - (__m128i)vec_sl(this->value, (__m128i)vec_splat_u8(N))); - } + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { + return (__m128i)vec_cmpeq(this->value, (__m128i)vec_splats(uint8_t(0))); + } + simdjson_inline simd8 bits_not_set(simd8 bits) const { + return (*this & bits).bits_not_set(); + } + simdjson_inline simd8 any_bits_set() const { + return ~this->bits_not_set(); + } + simdjson_inline simd8 any_bits_set(simd8 bits) const { + return ~this->bits_not_set(bits); + } + simdjson_inline bool bits_not_set_anywhere() const { + return vec_all_eq(this->value, (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere() const { + return !bits_not_set_anywhere(); + } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { + return vec_all_eq(vec_and(this->value, (__m128i)bits), + (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { + return !bits_not_set_anywhere(bits); + } + template simdjson_inline simd8 shr() const { + return simd8( + (__m128i)vec_sr(this->value, (__m128i)vec_splat_u8(N))); + } + template simdjson_inline simd8 shl() const { + return simd8( + (__m128i)vec_sl(this->value, (__m128i)vec_splat_u8(N))); + } }; template struct simd8x64 { @@ -19054,8 +21072,143 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_PPC64_SIMD_INPUT_H -/* end file include/simdjson/ppc64/simd.h */ -/* begin file include/simdjson/generic/jsoncharutils.h */ +/* end file simdjson/ppc64/simd.h */ +/* including simdjson/ppc64/stringparsing_defs.h: #include "simdjson/ppc64/stringparsing_defs.h" */ +/* begin file simdjson/ppc64/stringparsing_defs.h */ +#ifndef SIMDJSON_PPC64_STRINGPARSING_DEFS_H +#define SIMDJSON_PPC64_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/simd.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote + copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { + return ((bs_bits - 1) & quote_bits) != 0; + } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { + return trailing_zeroes(quote_bits); + } + simdjson_inline int backslash_index() { + return trailing_zeroes(bs_bits); + } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote + backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), + "backslash and quote finder must process fewer than " + "SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + sizeof(v0)); + v0.store(dst); + v1.store(dst + sizeof(v0)); + + // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on + // PPC; therefore, we smash them together into a 64-byte mask and get the + // bitmask from there. + uint64_t bs_and_quote = + simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_STRINGPARSING_DEFS_H +/* end file simdjson/ppc64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/ppc64/begin.h */ +/* including simdjson/generic/amalgamated.h for ppc64: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for ppc64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for ppc64: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for ppc64 */ +/* including simdjson/generic/jsoncharutils.h for ppc64: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace ppc64 { @@ -19148,32 +21301,25 @@ namespace simdjson { } #endif - using internal::value128; - - simdjson_inline value128 full_multiplication(uint64_t value1, uint64_t value2) { - value128 answer; -#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS -#ifdef _M_ARM64 - // ARM64 has native support for 64-bit multiplications, no need to emultate - answer.high = __umulh(value1, value2); - answer.low = value1 * value2; -#else - answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 -#endif // _M_ARM64 -#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS - __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; - answer.low = uint64_t(r); - answer.high = uint64_t(r >> 64); -#endif - return answer; - } - } // namespace jsoncharutils } // unnamed namespace } // namespace ppc64 } // namespace simdjson -/* end file include/simdjson/generic/jsoncharutils.h */ -/* begin file include/simdjson/generic/atomparsing.h */ + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for ppc64 */ +/* including simdjson/generic/atomparsing.h for ppc64: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + namespace simdjson { namespace ppc64 { namespace { @@ -19239,129 +21385,256 @@ namespace simdjson { } // unnamed namespace } // namespace ppc64 } // namespace simdjson -/* end file include/simdjson/generic/atomparsing.h */ -/* begin file include/simdjson/ppc64/stringparsing.h */ -#ifndef SIMDJSON_PPC64_STRINGPARSING_H -#define SIMDJSON_PPC64_STRINGPARSING_H +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for ppc64 */ +/* including simdjson/generic/dom_parser_implementation.h for ppc64: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace ppc64 { - namespace { - using namespace simd; + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container - // Holds backslashes and quotes locations. - struct backslash_and_quote { - public: - static constexpr uint32_t BYTES_PROCESSED = 32; - simdjson_inline static backslash_and_quote - copy_and_find(const uint8_t* src, uint8_t* dst); + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); - simdjson_inline bool has_quote_first() { - return ((bs_bits - 1) & quote_bits) != 0; - } - simdjson_inline bool has_backslash() { return bs_bits != 0; } - simdjson_inline int quote_index() { - return trailing_zeroes(quote_bits); - } - simdjson_inline int backslash_index() { - return trailing_zeroes(bs_bits); - } + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; - uint32_t bs_bits; - uint32_t quote_bits; - }; // struct backslash_and_quote + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; - simdjson_inline backslash_and_quote - backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { - // this can read up to 31 bytes beyond the buffer size, but we require - // SIMDJSON_PADDING of padding - static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), - "backslash and quote finder must process fewer than " - "SIMDJSON_PADDING bytes"); - simd8 v0(src); - simd8 v1(src + sizeof(v0)); - v0.store(dst); - v1.store(dst + sizeof(v0)); + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); - // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on - // PPC; therefore, we smash them together into a 64-byte mask and get the - // bitmask from there. - uint64_t bs_and_quote = - simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); - return { - uint32_t(bs_and_quote), // bs_bits - uint32_t(bs_and_quote >> 32) // quote_bits - }; - } + }; - } // unnamed namespace } // namespace ppc64 } // namespace simdjson -#endif // SIMDJSON_PPC64_STRINGPARSING_H -/* end file include/simdjson/ppc64/stringparsing.h */ -/* begin file include/simdjson/ppc64/numberparsing.h */ -#ifndef SIMDJSON_PPC64_NUMBERPARSING_H -#define SIMDJSON_PPC64_NUMBERPARSING_H - -#if defined(__linux__) -#include -#elif defined(__FreeBSD__) -#include -#endif - -namespace simdjson { - namespace ppc64 { - namespace { - - // we don't have appropriate instructions, so let us use a scalar function - // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ - static simdjson_inline uint32_t - parse_eight_digits_unrolled(const uint8_t* chars) { - uint64_t val; - std::memcpy(&val, chars, sizeof(uint64_t)); -#ifdef __BIG_ENDIAN__ -#if defined(__linux__) - val = bswap_64(val); -#elif defined(__FreeBSD__) - val = bswap64(val); -#endif -#endif - val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; - val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; - return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); - } - - } // unnamed namespace - } // namespace ppc64 -} // namespace simdjson - -#define SIMDJSON_SWAR_NUMBER_PARSING 1 - -/* begin file include/simdjson/generic/numberparsing.h */ -#include - namespace simdjson { namespace ppc64 { - namespace ondemand { - /** - * The type of a JSON number - */ - enum class number_type { - floating_point_number = 1, /// a binary64 number - signed_integer, /// a signed integer that fits in a 64-bit word using two's complement - unsigned_integer /// a positive integer larger or equal to 1<<63 - }; + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; } - namespace { - /// @private - namespace numberparsing { + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for ppc64 */ +/* including simdjson/generic/implementation_simdjson_result_base.h for ppc64: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + + // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair + // so we can avoid inlining errors + // TODO reconcile these! + /** + * The result of a simdjson operation that could fail. + * + * Gives the option of reading error codes, or throwing an exception by casting to the desired result. + * + * This is a base class for implementations that want to add functions to the result type for + * chaining. + * + * Override like: + * + * struct simdjson_result : public internal::implementation_simdjson_result_base { + * simdjson_result() noexcept : internal::implementation_simdjson_result_base() {} + * simdjson_result(error_code error) noexcept : internal::implementation_simdjson_result_base(error) {} + * simdjson_result(T &&value) noexcept : internal::implementation_simdjson_result_base(std::forward(value)) {} + * simdjson_result(T &&value, error_code error) noexcept : internal::implementation_simdjson_result_base(value, error) {} + * // Your extra methods here + * } + * + * Then any method returning simdjson_result will be chainable with your methods. + */ + template + struct implementation_simdjson_result_base { + + /** + * Create a new empty result with error = UNINITIALIZED. + */ + simdjson_inline implementation_simdjson_result_base() noexcept = default; + + /** + * Create a new error result. + */ + simdjson_inline implementation_simdjson_result_base(error_code error) noexcept; + + /** + * Create a new successful result. + */ + simdjson_inline implementation_simdjson_result_base(T&& value) noexcept; + + /** + * Create a new result with both things (use if you don't want to branch when creating the result). + */ + simdjson_inline implementation_simdjson_result_base(T&& value, error_code error) noexcept; + + /** + * Move the value and the error to the provided variables. + * + * @param value The variable to assign the value to. May not be set if there is an error. + * @param error The variable to assign the error to. Set to SUCCESS if there is no error. + */ + simdjson_inline void tie(T& value, error_code& error) && noexcept; + + /** + * Move the value to the provided variable. + * + * @param value The variable to assign the value to. May not be set if there is an error. + */ + simdjson_inline error_code get(T& value) && noexcept; + + /** + * The error. + */ + simdjson_inline error_code error() const noexcept; + +#if SIMDJSON_EXCEPTIONS + + /** + * Get the result value. + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T& value() & noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& value() && noexcept(false); + + /** + * Take the result value (move it). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline T&& take_value() && noexcept(false); + + /** + * Cast to the value (will throw on error). + * + * @throw simdjson_error if there was an error. + */ + simdjson_inline operator T && () && noexcept(false); +#endif // SIMDJSON_EXCEPTIONS + + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline const T& value_unsafe() const& noexcept; + /** + * Get the result value. This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T& value_unsafe() & noexcept; + /** + * Take the result value (move it). This function is safe if and only + * the error() method returns a value that evaluates to false. + */ + simdjson_inline T&& value_unsafe() && noexcept; + protected: + /** users should never directly access first and second. **/ + T first{}; /** Users should never directly access 'first'. **/ + error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ + }; // struct implementation_simdjson_result_base + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for ppc64 */ +/* including simdjson/generic/numberparsing.h for ppc64: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + +namespace simdjson { + namespace ppc64 { + namespace numberparsing { #ifdef JSON_TEST_NUMBERS #define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) @@ -19375,19 +21648,20 @@ namespace simdjson { #define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) #endif - namespace { - // Convert a mantissa, an exponent and a sign bit into an ieee64 double. - // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). - // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. - simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { - double d; - mantissa &= ~(1ULL << 52); - mantissa |= real_exponent << 52; - mantissa |= ((static_cast(negative)) << 63); - std::memcpy(&d, &mantissa, sizeof(d)); - return d; - } + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; } + // Attempts to compute i * 10^(power) exactly; and if "negative" is // true, negate the result. // This function will only work in some cases, when it does not work, success is @@ -19404,10 +21678,11 @@ namespace simdjson { #endif #if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) // We cannot be certain that x/y is rounded to nearest. - if (0 <= power && power <= 22 && i <= 9007199254740991) { + if (0 <= power && power <= 22 && i <= 9007199254740991) #else - if (-22 <= power && power <= 22 && i <= 9007199254740991) { + if (-22 <= power && power <= 22 && i <= 9007199254740991) #endif + { // convert the integer into a double. This is lossless since // 0 <= i <= 2^53 - 1. d = double(i); @@ -19512,7 +21787,7 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 firstproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index]); + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); // Both i and power_of_five_128[index] have their most significant bit set to 1 which // implies that the either the most or the second most significant bit of the product // is 1. We pack values in this manner for efficiency reasons: it maximizes the use @@ -19533,8 +21808,7 @@ namespace simdjson { // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q // to the desired approximation using one multiplication. Sometimes it does not suffice. // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and - // then we get a better approximation to i * 5^q. In very rare cases, even that - // will not suffice, though it is seemingly very hard to find such a scenario. + // then we get a better approximation to i * 5^q. // // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat // more complicated. @@ -19546,15 +21820,12 @@ namespace simdjson { // with a returned value of type value128 with a "low component" corresponding to the // 64-bit least significant bits of the product and with a "high component" corresponding // to the 64-bit most significant bits of the product. - simdjson::internal::value128 secondproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); firstproduct.low += secondproduct.high; if (secondproduct.high > firstproduct.low) { firstproduct.high++; } - // At this point, we might need to add at most one to firstproduct, but this - // can only change the value of firstproduct.high if firstproduct.low is maximal. - if (simdjson_unlikely(firstproduct.low == 0xFFFFFFFFFFFFFFFF)) { - // This is very unlikely, but if so, we need to do much more work! - return false; - } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. } uint64_t lower = firstproduct.low; uint64_t upper = firstproduct.high; @@ -19637,7 +21908,7 @@ namespace simdjson { } d = to_double(mantissa, real_exponent, negative); return true; - } + } // We call a fallback floating-point parser that might be slow. Note // it will accept JSON numbers, but the JSON spec. is more restrictive so @@ -19646,7 +21917,7 @@ namespace simdjson { // It will return an error (false) if the parsed number is infinite. // The string parsing itself always succeeds. We know that there is at least // one digit. - static bool parse_float_fallback(const uint8_t * ptr, double* outDouble) { + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); // We do not accept infinite values. @@ -19660,7 +21931,8 @@ namespace simdjson { // to handle that max may be a macro on windows). return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); } - static bool parse_float_fallback(const uint8_t * ptr, const uint8_t * end_ptr, double* outDouble) { + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); // We do not accept infinite values. @@ -19678,7 +21950,7 @@ namespace simdjson { // check quickly whether the next 8 chars are made of digits // at a glance, it looks better than Mula's // http://0x80.pl/articles/swar-digits-validate.html - simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t * chars) { + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { uint64_t val; // this can read up to 7 bytes beyond the buffer size, but we require // SIMDJSON_PADDING of padding @@ -19693,19 +21965,9 @@ namespace simdjson { 0x3333333333333333); } - template - error_code slow_float_parsing(simdjson_unused const uint8_t * src, W writer) { - double d; - if (parse_float_fallback(src, &d)) { - writer.append_double(d); - return SUCCESS; - } - return INVALID_NUMBER(src); - } - template SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later - simdjson_inline bool parse_digit(const uint8_t c, I & i) { + simdjson_inline bool parse_digit(const uint8_t c, I& i) { const uint8_t digit = static_cast(c - '0'); if (digit > 9) { return false; @@ -19715,7 +21977,7 @@ namespace simdjson { return true; } - simdjson_inline error_code parse_decimal(simdjson_unused const uint8_t* const src, const uint8_t * &p, uint64_t & i, int64_t & exponent) { + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { // we continue with the fiction that we have an integer. If the // floating point number is representable as x * 10^z for some integer // z that fits in 53 bits, then we will be able to convert back the @@ -19743,7 +22005,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t * &p, int64_t & exponent) { + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { // Exp Sign: -123.456e[-]78 bool neg_exp = ('-' == *p); if (neg_exp || '+' == *p) { p++; } // Skip + as well @@ -19794,7 +22056,7 @@ namespace simdjson { return SUCCESS; } - simdjson_inline size_t significant_digits(const uint8_t * start_digits, size_t digit_count) { + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { // It is possible that the integer had an overflow. // We have to handle the case where we have 0.0000somenumber. const uint8_t* start = start_digits; @@ -19803,79 +22065,93 @@ namespace simdjson { return digit_count - size_t(start - start_digits); } - template - simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t * start_digits, size_t digit_count, int64_t exponent, W & writer) { - // If we frequently had to deal with long strings of digits, - // we could extend our code by using a 128-bit integer instead - // of a 64-bit integer. However, this is uncommon in practice. - // - // 9999999999999999999 < 2**64 so we can accommodate 19 digits. - // If we have a decimal separator, then digit_count - 1 is the number of digits, but we - // may not have a decimal separator! - if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { - // Ok, chances are good that we had an overflow! - // this is almost never going to get called!!! - // we start anew, going slowly!!! - // This will happen in the following examples: - // 10000000000000000000000000000000000000000000e+308 - // 3.1415926535897932384626433832795028841971693993751 - // - // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens - // because slow_float_parsing is a non-inlined function. If we passed our writer reference to - // it, it would force it to be stored in memory, preventing the compiler from picking it apart - // and putting into registers. i.e. if we pass it as reference, it gets slow. - // This is what forces the skip_double, as well. - error_code error = slow_float_parsing(src, writer); - writer.skip_double(); - return error; - } - // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other - // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 - // To future reader: we'd love if someone found a better way, or at least could explain this result! - if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { - // - // Important: smallest_power is such that it leads to a zero value. - // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero - // so something x 10^-343 goes to zero, but not so with something x 10^-342. - static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); - // - if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { - // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero - WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); - return SUCCESS; - } - else { // (exponent > largest_power) and (i != 0) - // We have, for sure, an infinite value and simdjson refuses to parse infinite values. - return INVALID_NUMBER(src); - } - } - double d; - if (!compute_float_64(exponent, i, negative, d)) { - // we are almost never going to get here. - if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } - } - WRITE_DOUBLE(d, src, writer); + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); return SUCCESS; } + return INVALID_NUMBER(src); + } - // for performance analysis, it is sometimes useful to skip parsing + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing #ifdef SIMDJSON_SKIPNUMBERPARSING - template - simdjson_inline error_code parse_number(const uint8_t* const, W & writer) { - writer.append_s64(0); // always write zero - return SUCCESS; // always succeeds - } + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t * src) noexcept { return ondemand::number_type::signed_integer; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } #else // parse the number at src @@ -19887,9 +22163,308 @@ namespace simdjson { // content and append a space before calling this function. // // Our objective is accurate parsing (ULP of 0) at high speed. - template - simdjson_inline error_code parse_number(const uint8_t* const src, W & writer) { + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { // // Check for minus sign // @@ -19907,775 +22482,574 @@ namespace simdjson { // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. // Optimization note: size_t is expected to be unsigned. size_t digit_count = size_t(p - start_digits); - if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } - - // - // Handle floats if there is a . or e (or both) - // - int64_t exponent = 0; - bool is_float = false; - if ('.' == *p) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_decimal(src, p, i, exponent)); - digit_count = int(p - start_digits); // used later to guard against overflows - } - if (('e' == *p) || ('E' == *p)) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_exponent(src, p, exponent)); - } - if (is_float) { - const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); - SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); - if (dirty_end) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // The longest negative 64-bit number is 19 digits. - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - size_t longest_digit_count = negative ? 19 : 20; - if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } - if (digit_count == longest_digit_count) { - if (negative) { - // Anything negative above INT64_MAX+1 is invalid - if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } - WRITE_INTEGER(~i + 1, src, writer); - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - } - else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } - } - - // Write unsigned if it doesn't fit in a signed integer. - if (i > uint64_t(INT64_MAX)) { - WRITE_UNSIGNED(i, src, writer); - } - else { - WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); - } - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; } - // Inlineable functions - namespace { + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); - // This table can be used to characterize the final character of an integer - // string. For JSON structural character and allowable white space characters, - // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise - // we return NUMBER_ERROR. - // Optimization note: we could easily reduce the size of the table by half (to 128) - // at the cost of an extra branch. - // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): - static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } - const uint8_t integer_string_finisher[256] = { - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR }; + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - - return i; + } + else { + overflow = p - src > 19; } + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // Parse any number from 0 to 18,446,744,073,709,551,615 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + exponent += exp_neg ? 0 - exp : exp; } - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { - const uint8_t* p = src + 1; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*p != '"') { return NUMBER_ERROR; } + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - // Note: we use src[1] and not src[0] because src[0] is the quote character in this - // instance. - if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; } + return d; + } - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { - // - // Check for minus sign - // - if (src == src_end) { return NUMBER_ERROR; } - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = src; - uint64_t i = 0; - while (parse_digit(*src, i)) { src++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(src - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*src)) { - // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*src != '"') { return NUMBER_ERROR; } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; } } - else { - overflow = p - src > 19; + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; + } + else { + overflow = p - src > 19; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { - return (*src == '-'); - } - - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } - return false; - } - - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { - // We have an integer. - // If the number is negative and valid, it must be a signed integer. - if (negative) { return ondemand::number_type::signed_integer; } - // We want values larger or equal to 9223372036854775808 to be unsigned - // integers, and the other values to be signed integers. - int digit_count = int(p - src); - if (digit_count >= 19) { - const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); - if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { - return ondemand::number_type::unsigned_integer; - } - } - return ondemand::number_type::signed_integer; - } - // Hopefully, we have 'e' or 'E' or '.'. - return ondemand::number_type::floating_point_number; - } - - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { - if (src == src_end) { return NUMBER_ERROR; } - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; if (p == src_end) { return NUMBER_ERROR; } - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while ((p != src_end) && parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely((p != src_end) && (*p == '.'))) { - p++; - const uint8_t* start_decimal_digits = p; - if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if ((p != src_end) && (*p == 'e' || *p == 'E')) { - p++; - if (p == src_end) { return NUMBER_ERROR; } - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while ((p != src_end) && parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { - return NUMBER_ERROR; - } - return d; + exponent += exp_neg ? 0 - exp : exp; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + exponent = -(p - start_decimal_digits); - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (*p != '"') { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; } - } //namespace {} + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace #endif // SIMDJSON_SKIPNUMBERPARSING - } // namespace numberparsing - } // unnamed namespace - } // namespace ppc64 - } // namespace simdjson - /* end file include/simdjson/generic/numberparsing.h */ + } // namespace numberparsing -#endif // SIMDJSON_PPC64_NUMBERPARSING_H -/* end file include/simdjson/ppc64/numberparsing.h */ -/* begin file include/simdjson/ppc64/end.h */ -/* end file include/simdjson/ppc64/end.h */ + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } -#endif // SIMDJSON_IMPLEMENTATION_PPC64 + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for ppc64 */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for ppc64: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for ppc64 */ +/* end file simdjson/generic/amalgamated.h for ppc64 */ +/* including simdjson/ppc64/end.h: #include "simdjson/ppc64/end.h" */ +/* begin file simdjson/ppc64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "ppc64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/ppc64/end.h */ #endif // SIMDJSON_PPC64_H -/* end file include/simdjson/ppc64.h */ -/* begin file include/simdjson/westmere.h */ +/* end file simdjson/ppc64.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(westmere) +/* including simdjson/westmere.h: #include "simdjson/westmere.h" */ +/* begin file simdjson/westmere.h */ #ifndef SIMDJSON_WESTMERE_H #define SIMDJSON_WESTMERE_H +/* including simdjson/westmere/begin.h: #include "simdjson/westmere/begin.h" */ +/* begin file simdjson/westmere/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "westmere" */ +#define SIMDJSON_IMPLEMENTATION westmere +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H -#if SIMDJSON_IMPLEMENTATION_WESTMERE - -#if SIMDJSON_CAN_ALWAYS_RUN_WESTMERE -#define SIMDJSON_TARGET_WESTMERE -#define SIMDJSON_UNTARGET_WESTMERE -#else -#define SIMDJSON_TARGET_WESTMERE SIMDJSON_TARGET_REGION("sse4.2,pclmul") -#define SIMDJSON_UNTARGET_WESTMERE SIMDJSON_UNTARGET_REGION -#endif +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE namespace simdjson { /** * Implementation for Westmere (Intel SSE4.2). */ namespace westmere { - } // namespace westmere -} // namespace simdjson -// -// These two need to be included outside SIMDJSON_TARGET_WESTMERE -// -/* begin file include/simdjson/westmere/implementation.h */ -#ifndef SIMDJSON_WESTMERE_IMPLEMENTATION_H -#define SIMDJSON_WESTMERE_IMPLEMENTATION_H - - -// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE -namespace simdjson { - namespace westmere { + class implementation; namespace { - using namespace simdjson; - using namespace simdjson::dom; - } + namespace simd { - /** - * @private - */ - class implementation final : public simdjson::implementation { - public: - simdjson_inline implementation() : simdjson::implementation("westmere", "Intel/AMD SSE4.2", internal::instruction_set::SSE42 | internal::instruction_set::PCLMULQDQ) {} - simdjson_warn_unused error_code create_dom_parser_implementation( - size_t capacity, - size_t max_length, - std::unique_ptr& dst - ) const noexcept final; - simdjson_warn_unused error_code minify(const uint8_t* buf, size_t len, uint8_t* dst, size_t& dst_len) const noexcept final; - simdjson_warn_unused bool validate_utf8(const char* buf, size_t len) const noexcept final; - }; + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace } // namespace westmere } // namespace simdjson -#endif // SIMDJSON_WESTMERE_IMPLEMENTATION_H -/* end file include/simdjson/westmere/implementation.h */ -/* begin file include/simdjson/westmere/intrinsics.h */ +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ #ifndef SIMDJSON_WESTMERE_INTRINSICS_H #define SIMDJSON_WESTMERE_INTRINSICS_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + #if SIMDJSON_VISUAL_STUDIO // under clang within visual studio, this will include #include // visual studio or clang @@ -20700,104 +23074,22 @@ namespace simdjson { static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); #endif // SIMDJSON_WESTMERE_INTRINSICS_H -/* end file include/simdjson/westmere/intrinsics.h */ +/* end file simdjson/westmere/intrinsics.h */ -// -// The rest need to be inside the region -// -/* begin file include/simdjson/westmere/begin.h */ -// redefining SIMDJSON_IMPLEMENTATION to "westmere" -// #define SIMDJSON_IMPLEMENTATION westmere -SIMDJSON_TARGET_WESTMERE -/* end file include/simdjson/westmere/begin.h */ +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_TARGET_REGION("sse4.2,pclmul,popcnt") +#endif -// Declarations -/* begin file include/simdjson/generic/dom_parser_implementation.h */ - -namespace simdjson { - namespace westmere { - - // expectation: sizeof(open_container) = 64/8. - struct open_container { - uint32_t tape_index; // where, on the tape, does the scope ([,{) begins - uint32_t count; // how many elements in the scope - }; // struct open_container - - static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); - - class dom_parser_implementation final : public internal::dom_parser_implementation { - public: - /** Tape location of each open { or [ */ - std::unique_ptr open_containers{}; - /** Whether each open container is a [ or { */ - std::unique_ptr is_array{}; - /** Buffer passed to stage 1 */ - const uint8_t* buf{}; - /** Length passed to stage 1 */ - size_t len{ 0 }; - /** Document passed to stage 2 */ - dom::document* doc{}; - - inline dom_parser_implementation() noexcept; - inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; - inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; - dom_parser_implementation(const dom_parser_implementation&) = delete; - dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; - - simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; - simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; - simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; - simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; - simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; - inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; - inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; - private: - simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); - - }; - - } // namespace westmere -} // namespace simdjson - -namespace simdjson { - namespace westmere { - - inline dom_parser_implementation::dom_parser_implementation() noexcept = default; - inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; - inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; - - // Leaving these here so they can be inlined if so desired - inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { - if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } - // Stage 1 index output - size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; - structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); - if (!structural_indexes) { _capacity = 0; return MEMALLOC; } - structural_indexes[0] = 0; - n_structural_indexes = 0; - - _capacity = capacity; - return SUCCESS; - } - - inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { - // Stage 2 stacks - open_containers.reset(new (std::nothrow) open_container[max_depth]); - is_array.reset(new (std::nothrow) bool[max_depth]); - if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } - - _max_depth = max_depth; - return SUCCESS; - } - - } // namespace westmere -} // namespace simdjson -/* end file include/simdjson/generic/dom_parser_implementation.h */ -/* begin file include/simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ #ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H #define SIMDJSON_WESTMERE_BITMANIPULATION_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace westmere { namespace { @@ -20844,7 +23136,7 @@ namespace simdjson { #if SIMDJSON_REGULAR_VISUAL_STUDIO simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { - // note: we do not support legacy 32-bit Windows + // note: we do not support legacy 32-bit Windows in this kernel return __popcnt64(input_num);// Visual Studio wants two underscores } #else @@ -20869,11 +23161,17 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_WESTMERE_BITMANIPULATION_H -/* end file include/simdjson/westmere/bitmanipulation.h */ -/* begin file include/simdjson/westmere/bitmask.h */ +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/bitmask.h: #include "simdjson/westmere/bitmask.h" */ +/* begin file simdjson/westmere/bitmask.h */ #ifndef SIMDJSON_WESTMERE_BITMASK_H #define SIMDJSON_WESTMERE_BITMASK_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { namespace westmere { namespace { @@ -20896,11 +23194,143 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_WESTMERE_BITMASK_H -/* end file include/simdjson/westmere/bitmask.h */ -/* begin file include/simdjson/westmere/simd.h */ +/* end file simdjson/westmere/bitmask.h */ +/* including simdjson/westmere/numberparsing_defs.h: #include "simdjson/westmere/numberparsing_defs.h" */ +/* begin file simdjson/westmere/numberparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +#define SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H + +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + /** + * Implementation for Westmere (Intel SSE4.2). + */ + namespace westmere { + + class implementation; + + namespace { + namespace simd { + + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ +#ifndef SIMDJSON_WESTMERE_INTRINSICS_H +#define SIMDJSON_WESTMERE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + */ +#include // for _mm_alignr_epi8 +#include // for _mm_clmulepi64_si128 +#endif + +static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); + +#endif // SIMDJSON_WESTMERE_INTRINSICS_H +/* end file simdjson/westmere/intrinsics.h */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace westmere +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +/* end file simdjson/westmere/numberparsing_defs.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ #ifndef SIMDJSON_WESTMERE_SIMD_H #define SIMDJSON_WESTMERE_SIMD_H +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace westmere { @@ -20931,10 +23361,6 @@ namespace simdjson { simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } }; - // Forward-declared so they can be used by splat and friends. - template - struct simd8; - template> struct base8 : base> { typedef uint16_t bitmask_t; @@ -21235,8 +23661,544 @@ namespace simdjson { } // namespace simdjson #endif // SIMDJSON_WESTMERE_SIMD_INPUT_H -/* end file include/simdjson/westmere/simd.h */ -/* begin file include/simdjson/generic/jsoncharutils.h */ +/* end file simdjson/westmere/simd.h */ +/* including simdjson/westmere/stringparsing_defs.h: #include "simdjson/westmere/stringparsing_defs.h" */ +/* begin file simdjson/westmere/stringparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +#define SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H + +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ +#ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H +#define SIMDJSON_WESTMERE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMANIPULATION_H +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ +#ifndef SIMDJSON_WESTMERE_SIMD_H +#define SIMDJSON_WESTMERE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace simd { + + template + struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { return this->value; } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm_or_si128(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm_and_si128(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm_xor_si128(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm_andnot_si128(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + template> + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm_alignr_epi8(*this, prev_chunk, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm_testz_si128(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm_setzero_si128(); } + static simdjson_inline simd8 load(const T values[16]) { + return _mm_loadu_si128(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { return _mm_storeu_si128(reinterpret_cast<__m128i*>(dst), *this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m128i shufmask = _mm_set_epi64x(thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask + shufmask = + _mm_add_epi8(shufmask, _mm_set_epi32(0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m128i pruned = _mm_shuffle_epi8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = _mm_shuffle_epi8(pruned, compactmask); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), answer); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epu8(*this, other); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm_testz_si128(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm_testz_si128(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm_movemask_epi8(_mm_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "Westmere kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_SIMD_INPUT_H +/* end file simdjson/westmere/simd.h */ + +namespace simdjson { + namespace westmere { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + 16); + v0.store(dst); + v1.store(dst + 16); + uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +/* end file simdjson/westmere/stringparsing_defs.h */ +/* end file simdjson/westmere/begin.h */ +/* including simdjson/generic/amalgamated.h for westmere: #include "simdjson/generic/amalgamated.h" */ +/* begin file simdjson/generic/amalgamated.h for westmere */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_DEPENDENCIES_H) +#error simdjson/generic/dependencies.h must be included before simdjson/generic/amalgamated.h! +#endif + +/* including simdjson/generic/base.h for westmere: #include "simdjson/generic/base.h" */ +/* begin file simdjson/generic/base.h for westmere */ +#ifndef SIMDJSON_GENERIC_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): // If we haven't got an implementation yet, we're in the editor, editing a generic file! Just */ +/* amalgamation skipped (editor-only): // use the most advanced one we can so the most possible stuff can be tested. */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation_detection.h" */ +/* amalgamation skipped (editor-only): #if SIMDJSON_IMPLEMENTATION_ICELAKE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_HASWELL */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_WESTMERE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_ARM64 */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_PPC64 */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/begin.h" */ +/* amalgamation skipped (editor-only): #elif SIMDJSON_IMPLEMENTATION_FALLBACK */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/begin.h" */ +/* amalgamation skipped (editor-only): #else */ +/* amalgamation skipped (editor-only): #error "All possible implementations (including fallback) have been disabled! simdjson will not run." */ +/* amalgamation skipped (editor-only): #endif */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_IMPLEMENTATION */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + + struct open_container; + class dom_parser_implementation; + + /** + * The type of a JSON number + */ + enum class number_type { + floating_point_number = 1, /// a binary64 number + signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + unsigned_integer /// a positive integer larger or equal to 1<<63 + }; + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_BASE_H +/* end file simdjson/generic/base.h for westmere */ +/* including simdjson/generic/jsoncharutils.h for westmere: #include "simdjson/generic/jsoncharutils.h" */ +/* begin file simdjson/generic/jsoncharutils.h for westmere */ +#ifndef SIMDJSON_GENERIC_JSONCHARUTILS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_JSONCHARUTILS_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/jsoncharutils_tables.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace westmere { @@ -21329,32 +24291,25 @@ namespace simdjson { } #endif - using internal::value128; - - simdjson_inline value128 full_multiplication(uint64_t value1, uint64_t value2) { - value128 answer; -#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS -#ifdef _M_ARM64 - // ARM64 has native support for 64-bit multiplications, no need to emultate - answer.high = __umulh(value1, value2); - answer.low = value1 * value2; -#else - answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 -#endif // _M_ARM64 -#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS - __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; - answer.low = uint64_t(r); - answer.high = uint64_t(r >> 64); -#endif - return answer; - } - } // namespace jsoncharutils } // unnamed namespace } // namespace westmere } // namespace simdjson -/* end file include/simdjson/generic/jsoncharutils.h */ -/* begin file include/simdjson/generic/atomparsing.h */ + +#endif // SIMDJSON_GENERIC_JSONCHARUTILS_H +/* end file simdjson/generic/jsoncharutils.h for westmere */ +/* including simdjson/generic/atomparsing.h for westmere: #include "simdjson/generic/atomparsing.h" */ +/* begin file simdjson/generic/atomparsing.h for westmere */ +#ifndef SIMDJSON_GENERIC_ATOMPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ATOMPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + namespace simdjson { namespace westmere { namespace { @@ -21420,1393 +24375,112 @@ namespace simdjson { } // unnamed namespace } // namespace westmere } // namespace simdjson -/* end file include/simdjson/generic/atomparsing.h */ -/* begin file include/simdjson/westmere/stringparsing.h */ -#ifndef SIMDJSON_WESTMERE_STRINGPARSING_H -#define SIMDJSON_WESTMERE_STRINGPARSING_H + +#endif // SIMDJSON_GENERIC_ATOMPARSING_H +/* end file simdjson/generic/atomparsing.h for westmere */ +/* including simdjson/generic/dom_parser_implementation.h for westmere: #include "simdjson/generic/dom_parser_implementation.h" */ +/* begin file simdjson/generic/dom_parser_implementation.h for westmere */ +#ifndef SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { namespace westmere { - namespace { - using namespace simd; + // expectation: sizeof(open_container) = 64/8. + struct open_container { + uint32_t tape_index; // where, on the tape, does the scope ([,{) begins + uint32_t count; // how many elements in the scope + }; // struct open_container - // Holds backslashes and quotes locations. - struct backslash_and_quote { - public: - static constexpr uint32_t BYTES_PROCESSED = 32; - simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + static_assert(sizeof(open_container) == 64 / 8, "Open container must be 64 bits"); - simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } - simdjson_inline bool has_backslash() { return bs_bits != 0; } - simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } - simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + class dom_parser_implementation final : public internal::dom_parser_implementation { + public: + /** Tape location of each open { or [ */ + std::unique_ptr open_containers{}; + /** Whether each open container is a [ or { */ + std::unique_ptr is_array{}; + /** Buffer passed to stage 1 */ + const uint8_t* buf{}; + /** Length passed to stage 1 */ + size_t len{ 0 }; + /** Document passed to stage 2 */ + dom::document* doc{}; - uint32_t bs_bits; - uint32_t quote_bits; - }; // struct backslash_and_quote + inline dom_parser_implementation() noexcept; + inline dom_parser_implementation(dom_parser_implementation&& other) noexcept; + inline dom_parser_implementation& operator=(dom_parser_implementation&& other) noexcept; + dom_parser_implementation(const dom_parser_implementation&) = delete; + dom_parser_implementation& operator=(const dom_parser_implementation&) = delete; - simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { - // this can read up to 31 bytes beyond the buffer size, but we require - // SIMDJSON_PADDING of padding - static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); - simd8 v0(src); - simd8 v1(src + 16); - v0.store(dst); - v1.store(dst + 16); - uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); - return { - uint32_t(bs_and_quote), // bs_bits - uint32_t(bs_and_quote >> 32) // quote_bits - }; - } + simdjson_warn_unused error_code parse(const uint8_t* buf, size_t len, dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage1(const uint8_t* buf, size_t len, stage1_mode partial) noexcept final; + simdjson_warn_unused error_code stage2(dom::document& doc) noexcept final; + simdjson_warn_unused error_code stage2_next(dom::document& doc) noexcept final; + simdjson_warn_unused uint8_t* parse_string(const uint8_t* src, uint8_t* dst, bool allow_replacement) const noexcept final; + simdjson_warn_unused uint8_t* parse_wobbly_string(const uint8_t* src, uint8_t* dst) const noexcept final; + inline simdjson_warn_unused error_code set_capacity(size_t capacity) noexcept final; + inline simdjson_warn_unused error_code set_max_depth(size_t max_depth) noexcept final; + private: + simdjson_inline simdjson_warn_unused error_code set_capacity_stage1(size_t capacity); + + }; - } // unnamed namespace } // namespace westmere } // namespace simdjson -#endif // SIMDJSON_WESTMERE_STRINGPARSING_H -/* end file include/simdjson/westmere/stringparsing.h */ -/* begin file include/simdjson/westmere/numberparsing.h */ -#ifndef SIMDJSON_WESTMERE_NUMBERPARSING_H -#define SIMDJSON_WESTMERE_NUMBERPARSING_H - -namespace simdjson { - namespace westmere { - namespace { - - static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { - // this actually computes *16* values so we are being wasteful. - const __m128i ascii0 = _mm_set1_epi8('0'); - const __m128i mul_1_10 = - _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); - const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); - const __m128i mul_1_10000 = - _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); - const __m128i input = _mm_sub_epi8( - _mm_loadu_si128(reinterpret_cast(chars)), ascii0); - const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); - const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); - const __m128i t3 = _mm_packus_epi32(t2, t2); - const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); - return _mm_cvtsi128_si32( - t4); // only captures the sum of the first 8 digits, drop the rest - } - - } // unnamed namespace - } // namespace westmere -} // namespace simdjson - -#define SIMDJSON_SWAR_NUMBER_PARSING 1 - -/* begin file include/simdjson/generic/numberparsing.h */ -#include - namespace simdjson { namespace westmere { - namespace ondemand { - /** - * The type of a JSON number - */ - enum class number_type { - floating_point_number = 1, /// a binary64 number - signed_integer, /// a signed integer that fits in a 64-bit word using two's complement - unsigned_integer /// a positive integer larger or equal to 1<<63 - }; + inline dom_parser_implementation::dom_parser_implementation() noexcept = default; + inline dom_parser_implementation::dom_parser_implementation(dom_parser_implementation&& other) noexcept = default; + inline dom_parser_implementation& dom_parser_implementation::operator=(dom_parser_implementation&& other) noexcept = default; + + // Leaving these here so they can be inlined if so desired + inline simdjson_warn_unused error_code dom_parser_implementation::set_capacity(size_t capacity) noexcept { + if (capacity > SIMDJSON_MAXSIZE_BYTES) { return CAPACITY; } + // Stage 1 index output + size_t max_structures = SIMDJSON_ROUNDUP_N(capacity, 64) + 2 + 7; + structural_indexes.reset(new (std::nothrow) uint32_t[max_structures]); + if (!structural_indexes) { _capacity = 0; return MEMALLOC; } + structural_indexes[0] = 0; + n_structural_indexes = 0; + + _capacity = capacity; + return SUCCESS; } - namespace { - /// @private - namespace numberparsing { + inline simdjson_warn_unused error_code dom_parser_implementation::set_max_depth(size_t max_depth) noexcept { + // Stage 2 stacks + open_containers.reset(new (std::nothrow) open_container[max_depth]); + is_array.reset(new (std::nothrow) bool[max_depth]); + if (!is_array || !open_containers) { _max_depth = 0; return MEMALLOC; } + + _max_depth = max_depth; + return SUCCESS; + } + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_DOM_PARSER_IMPLEMENTATION_H +/* end file simdjson/generic/dom_parser_implementation.h for westmere */ +/* including simdjson/generic/implementation_simdjson_result_base.h for westmere: #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base.h for westmere */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ - - -#ifdef JSON_TEST_NUMBERS -#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) -#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) -#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) -#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) -#else -#define INVALID_NUMBER(SRC) (NUMBER_ERROR) -#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) -#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) -#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) -#endif - - namespace { - // Convert a mantissa, an exponent and a sign bit into an ieee64 double. - // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). - // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. - simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { - double d; - mantissa &= ~(1ULL << 52); - mantissa |= real_exponent << 52; - mantissa |= ((static_cast(negative)) << 63); - std::memcpy(&d, &mantissa, sizeof(d)); - return d; - } - } - // Attempts to compute i * 10^(power) exactly; and if "negative" is - // true, negate the result. - // This function will only work in some cases, when it does not work, success is - // set to false. This should work *most of the time* (like 99% of the time). - // We assume that power is in the [smallest_power, - // largest_power] interval: the caller is responsible for this check. - simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { - // we start with a fast path - // It was described in - // Clinger WD. How to read floating point numbers accurately. - // ACM SIGPLAN Notices. 1990 -#ifndef FLT_EVAL_METHOD -#error "FLT_EVAL_METHOD should be defined, please include cfloat." -#endif -#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) - // We cannot be certain that x/y is rounded to nearest. - if (0 <= power && power <= 22 && i <= 9007199254740991) { -#else - if (-22 <= power && power <= 22 && i <= 9007199254740991) { -#endif - // convert the integer into a double. This is lossless since - // 0 <= i <= 2^53 - 1. - d = double(i); - // - // The general idea is as follows. - // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then - // 1) Both s and p can be represented exactly as 64-bit floating-point - // values - // (binary64). - // 2) Because s and p can be represented exactly as floating-point values, - // then s * p - // and s / p will produce correctly rounded values. - // - if (power < 0) { - d = d / simdjson::internal::power_of_ten[-power]; - } - else { - d = d * simdjson::internal::power_of_ten[power]; - } - if (negative) { - d = -d; - } - return true; - } - // When 22 < power && power < 22 + 16, we could - // hope for another, secondary fast path. It was - // described by David M. Gay in "Correctly rounded - // binary-decimal and decimal-binary conversions." (1990) - // If you need to compute i * 10^(22 + x) for x < 16, - // first compute i * 10^x, if you know that result is exact - // (e.g., when i * 10^x < 2^53), - // then you can still proceed and do (i * 10^x) * 10^22. - // Is this worth your time? - // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) - // for this second fast path to work. - // If you you have 22 < power *and* power < 22 + 16, and then you - // optimistically compute "i * 10^(x-22)", there is still a chance that you - // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of - // this optimization maybe less common than we would like. Source: - // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ - // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html - - // The fast path has now failed, so we are failing back on the slower path. - - // In the slow path, we need to adjust i so that it is > 1<<63 which is always - // possible, except if i == 0, so we handle i == 0 separately. - if (i == 0) { - d = negative ? -0.0 : 0.0; - return true; - } - - - // The exponent is 1024 + 63 + power - // + floor(log(5**power)/log(2)). - // The 1024 comes from the ieee64 standard. - // The 63 comes from the fact that we use a 64-bit word. - // - // Computing floor(log(5**power)/log(2)) could be - // slow. Instead we use a fast function. - // - // For power in (-400,350), we have that - // (((152170 + 65536) * power ) >> 16); - // is equal to - // floor(log(5**power)/log(2)) + power when power >= 0 - // and it is equal to - // ceil(log(5**-power)/log(2)) + power when power < 0 - // - // The 65536 is (1<<16) and corresponds to - // (65536 * power) >> 16 ---> power - // - // ((152170 * power ) >> 16) is equal to - // floor(log(5**power)/log(2)) - // - // Note that this is not magic: 152170/(1<<16) is - // approximatively equal to log(5)/log(2). - // The 1<<16 value is a power of two; we could use a - // larger power of 2 if we wanted to. - // - int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; - - - // We want the most significant bit of i to be 1. Shift if needed. - int lz = leading_zeroes(i); - i <<= lz; - - - // We are going to need to do some 64-bit arithmetic to get a precise product. - // We use a table lookup approach. - // It is safe because - // power >= smallest_power - // and power <= largest_power - // We recover the mantissa of the power, it has a leading 1. It is always - // rounded down. - // - // We want the most significant 64 bits of the product. We know - // this will be non-zero because the most significant bit of i is - // 1. - const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); - // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) - // - // The full_multiplication function computes the 128-bit product of two 64-bit words - // with a returned value of type value128 with a "low component" corresponding to the - // 64-bit least significant bits of the product and with a "high component" corresponding - // to the 64-bit most significant bits of the product. - simdjson::internal::value128 firstproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index]); - // Both i and power_of_five_128[index] have their most significant bit set to 1 which - // implies that the either the most or the second most significant bit of the product - // is 1. We pack values in this manner for efficiency reasons: it maximizes the use - // we make of the product. It also makes it easy to reason about the product: there - // is 0 or 1 leading zero in the product. - - // Unless the least significant 9 bits of the high (64-bit) part of the full - // product are all 1s, then we know that the most significant 55 bits are - // exact and no further work is needed. Having 55 bits is necessary because - // we need 53 bits for the mantissa but we have to have one rounding bit and - // we can waste a bit if the most significant bit of the product is zero. - if ((firstproduct.high & 0x1FF) == 0x1FF) { - // We want to compute i * 5^q, but only care about the top 55 bits at most. - // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing - // the full computation is wasteful. So we do what is called a "truncated - // multiplication". - // We take the most significant 64-bits, and we put them in - // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q - // to the desired approximation using one multiplication. Sometimes it does not suffice. - // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and - // then we get a better approximation to i * 5^q. In very rare cases, even that - // will not suffice, though it is seemingly very hard to find such a scenario. - // - // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat - // more complicated. - // - // There is an extra layer of complexity in that we need more than 55 bits of - // accuracy in the round-to-even scenario. - // - // The full_multiplication function computes the 128-bit product of two 64-bit words - // with a returned value of type value128 with a "low component" corresponding to the - // 64-bit least significant bits of the product and with a "high component" corresponding - // to the 64-bit most significant bits of the product. - simdjson::internal::value128 secondproduct = jsoncharutils::full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); - firstproduct.low += secondproduct.high; - if (secondproduct.high > firstproduct.low) { firstproduct.high++; } - // At this point, we might need to add at most one to firstproduct, but this - // can only change the value of firstproduct.high if firstproduct.low is maximal. - if (simdjson_unlikely(firstproduct.low == 0xFFFFFFFFFFFFFFFF)) { - // This is very unlikely, but if so, we need to do much more work! - return false; - } - } - uint64_t lower = firstproduct.low; - uint64_t upper = firstproduct.high; - // The final mantissa should be 53 bits with a leading 1. - // We shift it so that it occupies 54 bits with a leading 1. - /////// - uint64_t upperbit = upper >> 63; - uint64_t mantissa = upper >> (upperbit + 9); - lz += int(1 ^ upperbit); - - // Here we have mantissa < (1<<54). - int64_t real_exponent = exponent - lz; - if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? - // Here have that real_exponent <= 0 so -real_exponent >= 0 - if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. - d = negative ? -0.0 : 0.0; - return true; - } - // next line is safe because -real_exponent + 1 < 0 - mantissa >>= -real_exponent + 1; - // Thankfully, we can't have both "round-to-even" and subnormals because - // "round-to-even" only occurs for powers close to 0. - mantissa += (mantissa & 1); // round up - mantissa >>= 1; - // There is a weird scenario where we don't have a subnormal but just. - // Suppose we start with 2.2250738585072013e-308, we end up - // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal - // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round - // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer - // subnormal, but we can only know this after rounding. - // So we only declare a subnormal if we are smaller than the threshold. - real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; - d = to_double(mantissa, real_exponent, negative); - return true; - } - // We have to round to even. The "to even" part - // is only a problem when we are right in between two floats - // which we guard against. - // If we have lots of trailing zeros, we may fall right between two - // floating-point values. - // - // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] - // times a power of two. That is, it is right between a number with binary significand - // m and another number with binary significand m+1; and it must be the case - // that it cannot be represented by a float itself. - // - // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. - // Recall that 10^q = 5^q * 2^q. - // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that - // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. - // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so - // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have - // 2^{53} x 5^{-q} < 2^{64}. - // Hence we have 5^{-q} < 2^{11}$ or q>= -4. - // - // We require lower <= 1 and not lower == 0 because we could not prove that - // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. - if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { - if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { - mantissa &= ~1; // flip it so that we do not round up - } - } - - mantissa += mantissa & 1; - mantissa >>= 1; - - // Here we have mantissa < (1<<53), unless there was an overflow - if (mantissa >= (1ULL << 53)) { - ////////// - // This will happen when parsing values such as 7.2057594037927933e+16 - //////// - mantissa = (1ULL << 52); - real_exponent++; - } - mantissa &= ~(1ULL << 52); - // we have to check that real_exponent is in range, otherwise we bail out - if (simdjson_unlikely(real_exponent > 2046)) { - // We have an infinite value!!! We could actually throw an error here if we could. - return false; - } - d = to_double(mantissa, real_exponent, negative); - return true; - } - - // We call a fallback floating-point parser that might be slow. Note - // it will accept JSON numbers, but the JSON spec. is more restrictive so - // before you call parse_float_fallback, you need to have validated the input - // string with the JSON grammar. - // It will return an error (false) if the parsed number is infinite. - // The string parsing itself always succeeds. We know that there is at least - // one digit. - static bool parse_float_fallback(const uint8_t * ptr, double* outDouble) { - *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); - // We do not accept infinite values. - - // Detecting finite values in a portable manner is ridiculously hard, ideally - // we would want to do: - // return !std::isfinite(*outDouble); - // but that mysteriously fails under legacy/old libc++ libraries, see - // https://github.com/simdjson/simdjson/issues/1286 - // - // Therefore, fall back to this solution (the extra parens are there - // to handle that max may be a macro on windows). - return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); - } - static bool parse_float_fallback(const uint8_t * ptr, const uint8_t * end_ptr, double* outDouble) { - *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); - // We do not accept infinite values. - - // Detecting finite values in a portable manner is ridiculously hard, ideally - // we would want to do: - // return !std::isfinite(*outDouble); - // but that mysteriously fails under legacy/old libc++ libraries, see - // https://github.com/simdjson/simdjson/issues/1286 - // - // Therefore, fall back to this solution (the extra parens are there - // to handle that max may be a macro on windows). - return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); - } - - // check quickly whether the next 8 chars are made of digits - // at a glance, it looks better than Mula's - // http://0x80.pl/articles/swar-digits-validate.html - simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t * chars) { - uint64_t val; - // this can read up to 7 bytes beyond the buffer size, but we require - // SIMDJSON_PADDING of padding - static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); - std::memcpy(&val, chars, 8); - // a branchy method might be faster: - // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) - // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == - // 0x3030303030303030); - return (((val & 0xF0F0F0F0F0F0F0F0) | - (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == - 0x3333333333333333); - } - - template - error_code slow_float_parsing(simdjson_unused const uint8_t * src, W writer) { - double d; - if (parse_float_fallback(src, &d)) { - writer.append_double(d); - return SUCCESS; - } - return INVALID_NUMBER(src); - } - - template - SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later - simdjson_inline bool parse_digit(const uint8_t c, I & i) { - const uint8_t digit = static_cast(c - '0'); - if (digit > 9) { - return false; - } - // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication - i = 10 * i + digit; // might overflow, we will handle the overflow later - return true; - } - - simdjson_inline error_code parse_decimal(simdjson_unused const uint8_t* const src, const uint8_t * &p, uint64_t & i, int64_t & exponent) { - // we continue with the fiction that we have an integer. If the - // floating point number is representable as x * 10^z for some integer - // z that fits in 53 bits, then we will be able to convert back the - // the integer into a float in a lossless manner. - const uint8_t* const first_after_period = p; - -#ifdef SIMDJSON_SWAR_NUMBER_PARSING -#if SIMDJSON_SWAR_NUMBER_PARSING - // this helps if we have lots of decimals! - // this turns out to be frequent enough. - if (is_made_of_eight_digits_fast(p)) { - i = i * 100000000 + parse_eight_digits_unrolled(p); - p += 8; - } -#endif // SIMDJSON_SWAR_NUMBER_PARSING -#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING - // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) - if (parse_digit(*p, i)) { ++p; } - while (parse_digit(*p, i)) { p++; } - exponent = first_after_period - p; - // Decimal without digits (123.) is illegal - if (exponent == 0) { - return INVALID_NUMBER(src); - } - return SUCCESS; - } - - simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t * &p, int64_t & exponent) { - // Exp Sign: -123.456e[-]78 - bool neg_exp = ('-' == *p); - if (neg_exp || '+' == *p) { p++; } // Skip + as well - - // Exponent: -123.456e-[78] - auto start_exp = p; - int64_t exp_number = 0; - while (parse_digit(*p, exp_number)) { ++p; } - // It is possible for parse_digit to overflow. - // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. - // Thus we *must* check for possible overflow before we negate exp_number. - - // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into - // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may - // not oblige and may, in fact, generate two distinct paths in any case. It might be - // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off - // instructions for a simdjson_likely branch, an unconclusive gain. - - // If there were no digits, it's an error. - if (simdjson_unlikely(p == start_exp)) { - return INVALID_NUMBER(src); - } - // We have a valid positive exponent in exp_number at this point, except that - // it may have overflowed. - - // If there were more than 18 digits, we may have overflowed the integer. We have to do - // something!!!! - if (simdjson_unlikely(p > start_exp + 18)) { - // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow - while (*start_exp == '0') { start_exp++; } - // 19 digits could overflow int64_t and is kind of absurd anyway. We don't - // support exponents smaller than -999,999,999,999,999,999 and bigger - // than 999,999,999,999,999,999. - // We can truncate. - // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before - // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could - // truncate at 324. - // Note that there is no reason to fail per se at this point in time. - // E.g., 0e999999999999999999999 is a fine number. - if (p > start_exp + 18) { exp_number = 999999999999999999; } - } - // At this point, we know that exp_number is a sane, positive, signed integer. - // It is <= 999,999,999,999,999,999. As long as 'exponent' is in - // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' - // is bounded in magnitude by the size of the JSON input, we are fine in this universe. - // To sum it up: the next line should never overflow. - exponent += (neg_exp ? -exp_number : exp_number); - return SUCCESS; - } - - simdjson_inline size_t significant_digits(const uint8_t * start_digits, size_t digit_count) { - // It is possible that the integer had an overflow. - // We have to handle the case where we have 0.0000somenumber. - const uint8_t* start = start_digits; - while ((*start == '0') || (*start == '.')) { ++start; } - // we over-decrement by one when there is a '.' - return digit_count - size_t(start - start_digits); - } - - template - simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t * start_digits, size_t digit_count, int64_t exponent, W & writer) { - // If we frequently had to deal with long strings of digits, - // we could extend our code by using a 128-bit integer instead - // of a 64-bit integer. However, this is uncommon in practice. - // - // 9999999999999999999 < 2**64 so we can accommodate 19 digits. - // If we have a decimal separator, then digit_count - 1 is the number of digits, but we - // may not have a decimal separator! - if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { - // Ok, chances are good that we had an overflow! - // this is almost never going to get called!!! - // we start anew, going slowly!!! - // This will happen in the following examples: - // 10000000000000000000000000000000000000000000e+308 - // 3.1415926535897932384626433832795028841971693993751 - // - // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens - // because slow_float_parsing is a non-inlined function. If we passed our writer reference to - // it, it would force it to be stored in memory, preventing the compiler from picking it apart - // and putting into registers. i.e. if we pass it as reference, it gets slow. - // This is what forces the skip_double, as well. - error_code error = slow_float_parsing(src, writer); - writer.skip_double(); - return error; - } - // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other - // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 - // To future reader: we'd love if someone found a better way, or at least could explain this result! - if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { - // - // Important: smallest_power is such that it leads to a zero value. - // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero - // so something x 10^-343 goes to zero, but not so with something x 10^-342. - static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); - // - if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { - // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero - WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); - return SUCCESS; - } - else { // (exponent > largest_power) and (i != 0) - // We have, for sure, an infinite value and simdjson refuses to parse infinite values. - return INVALID_NUMBER(src); - } - } - double d; - if (!compute_float_64(exponent, i, negative, d)) { - // we are almost never going to get here. - if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } - } - WRITE_DOUBLE(d, src, writer); - return SUCCESS; - } - - // for performance analysis, it is sometimes useful to skip parsing -#ifdef SIMDJSON_SKIPNUMBERPARSING - - template - simdjson_inline error_code parse_number(const uint8_t* const, W & writer) { - writer.append_s64(0); // always write zero - return SUCCESS; // always succeeds - } - - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } - simdjson_unused simdjson_inline bool is_negative(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t * src) noexcept { return false; } - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t * src) noexcept { return ondemand::number_type::signed_integer; } -#else - -// parse the number at src -// define JSON_TEST_NUMBERS for unit testing -// -// It is assumed that the number is followed by a structural ({,},],[) character -// or a white space character. If that is not the case (e.g., when the JSON -// document is made of a single number), then it is necessary to copy the -// content and append a space before calling this function. -// -// Our objective is accurate parsing (ULP of 0) at high speed. - template - simdjson_inline error_code parse_number(const uint8_t* const src, W & writer) { - - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } - - // - // Handle floats if there is a . or e (or both) - // - int64_t exponent = 0; - bool is_float = false; - if ('.' == *p) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_decimal(src, p, i, exponent)); - digit_count = int(p - start_digits); // used later to guard against overflows - } - if (('e' == *p) || ('E' == *p)) { - is_float = true; - ++p; - SIMDJSON_TRY(parse_exponent(src, p, exponent)); - } - if (is_float) { - const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); - SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); - if (dirty_end) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // The longest negative 64-bit number is 19 digits. - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - size_t longest_digit_count = negative ? 19 : 20; - if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } - if (digit_count == longest_digit_count) { - if (negative) { - // Anything negative above INT64_MAX+1 is invalid - if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } - WRITE_INTEGER(~i + 1, src, writer); - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - } - else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } - } - - // Write unsigned if it doesn't fit in a signed integer. - if (i > uint64_t(INT64_MAX)) { - WRITE_UNSIGNED(i, src, writer); - } - else { - WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); - } - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } - return SUCCESS; - } - - // Inlineable functions - namespace { - - // This table can be used to characterize the final character of an integer - // string. For JSON structural character and allowable white space characters, - // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise - // we return NUMBER_ERROR. - // Optimization note: we could easily reduce the size of the table by half (to 128) - // at the cost of an extra branch. - // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): - static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); - static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); - - const uint8_t integer_string_finisher[256] = { - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, - SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, - NUMBER_ERROR }; - - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; - } - - - // Parse any number from 0 to 18,446,744,073,709,551,615 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { - const uint8_t* p = src; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; - } - - // Parse any number from 0 to 18,446,744,073,709,551,615 - simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { - const uint8_t* p = src + 1; - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // The longest positive 64-bit number is 20 digits. - // We do it this way so we don't trigger this branch unless we must. - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > 20)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*p != '"') { return NUMBER_ERROR; } - - if (digit_count == 20) { - // Positive overflow check: - // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the - // biggest uint64_t. - // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. - // If we got here, it's a 20 digit number starting with the digit "1". - // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller - // than 1,553,255,926,290,448,384. - // - That is smaller than the smallest possible 20-digit number the user could write: - // 10,000,000,000,000,000,000. - // - Therefore, if the number is positive and lower than that, it's overflow. - // - The value we are looking at is less than or equal to INT64_MAX. - // - // Note: we use src[1] and not src[0] because src[0] is the quote character in this - // instance. - if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } - } - - return i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while (parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { - // - // Check for minus sign - // - if (src == src_end) { return NUMBER_ERROR; } - bool negative = (*src == '-'); - const uint8_t* p = src + uint8_t(negative); - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = p; - uint64_t i = 0; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(p - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*p)) { - // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare - const uint8_t* const start_digits = src; - uint64_t i = 0; - while (parse_digit(*src, i)) { src++; } - - // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. - // Optimization note: size_t is expected to be unsigned. - size_t digit_count = size_t(src - start_digits); - // We go from - // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 - // so we can never represent numbers that have more than 19 digits. - size_t longest_digit_count = 19; - // Optimization note: the compiler can probably merge - // ((digit_count == 0) || (digit_count > longest_digit_count)) - // into a single branch since digit_count is unsigned. - if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } - // Here digit_count > 0. - if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } - // We can do the following... - // if (!jsoncharutils::is_structural_or_whitespace(*src)) { - // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; - // } - // as a single table lookup: - if (*src != '"') { return NUMBER_ERROR; } - // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. - // Performance note: This check is only needed when digit_count == longest_digit_count but it is - // so cheap that we might as well always make it. - if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } - return negative ? (~i + 1) : i; - } - - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; - } - - simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { - return (*src == '-'); - } - - simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } - return false; - } - - simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { - bool negative = (*src == '-'); - src += uint8_t(negative); - const uint8_t* p = src; - while (static_cast(*p - '0') <= 9) { p++; } - if (p == src) { return NUMBER_ERROR; } - if (jsoncharutils::is_structural_or_whitespace(*p)) { - // We have an integer. - // If the number is negative and valid, it must be a signed integer. - if (negative) { return ondemand::number_type::signed_integer; } - // We want values larger or equal to 9223372036854775808 to be unsigned - // integers, and the other values to be signed integers. - int digit_count = int(p - src); - if (digit_count >= 19) { - const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); - if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { - return ondemand::number_type::unsigned_integer; - } - } - return ondemand::number_type::signed_integer; - } - // Hopefully, we have 'e' or 'E' or '.'. - return ondemand::number_type::floating_point_number; - } - - // Never read at src_end or beyond - simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { - if (src == src_end) { return NUMBER_ERROR; } - // - // Check for minus sign - // - bool negative = (*src == '-'); - src += uint8_t(negative); - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - if (p == src_end) { return NUMBER_ERROR; } - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while ((p != src_end) && parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely((p != src_end) && (*p == '.'))) { - p++; - const uint8_t* start_decimal_digits = p; - if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while ((p != src_end) && parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if ((p != src_end) && (*p == 'e' || *p == 'E')) { - p++; - if (p == src_end) { return NUMBER_ERROR; } - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while ((p != src_end) && parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { - return NUMBER_ERROR; - } - return d; - } - - simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { - // - // Check for minus sign - // - bool negative = (*(src + 1) == '-'); - src += uint8_t(negative) + 1; - - // - // Parse the integer part. - // - uint64_t i = 0; - const uint8_t* p = src; - p += parse_digit(*p, i); - bool leading_zero = (i == 0); - while (parse_digit(*p, i)) { p++; } - // no integer digits, or 0123 (zero must be solo) - if (p == src) { return INCORRECT_TYPE; } - if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } - - // - // Parse the decimal part. - // - int64_t exponent = 0; - bool overflow; - if (simdjson_likely(*p == '.')) { - p++; - const uint8_t* start_decimal_digits = p; - if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits - p++; - while (parse_digit(*p, i)) { p++; } - exponent = -(p - start_decimal_digits); - - // Overflow check. More than 19 digits (minus the decimal) may be overflow. - overflow = p - src - 1 > 19; - if (simdjson_unlikely(overflow && leading_zero)) { - // Skip leading 0.00000 and see if it still overflows - const uint8_t* start_digits = src + 2; - while (*start_digits == '0') { start_digits++; } - overflow = start_digits - src > 19; - } - } - else { - overflow = p - src > 19; - } - - // - // Parse the exponent - // - if (*p == 'e' || *p == 'E') { - p++; - bool exp_neg = *p == '-'; - p += exp_neg || *p == '+'; - - uint64_t exp = 0; - const uint8_t* start_exp_digits = p; - while (parse_digit(*p, exp)) { p++; } - // no exp digits, or 20+ exp digits - if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } - - exponent += exp_neg ? 0 - exp : exp; - } - - if (*p != '"') { return NUMBER_ERROR; } - - overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; - - // - // Assemble (or slow-parse) the float - // - double d; - if (simdjson_likely(!overflow)) { - if (compute_float_64(exponent, i, negative, d)) { return d; } - } - if (!parse_float_fallback(src - uint8_t(negative), &d)) { - return NUMBER_ERROR; - } - return d; - } - } //namespace {} -#endif // SIMDJSON_SKIPNUMBERPARSING - - } // namespace numberparsing - } // unnamed namespace - } // namespace westmere - } // namespace simdjson - /* end file include/simdjson/generic/numberparsing.h */ - -#endif // SIMDJSON_WESTMERE_NUMBERPARSING_H -/* end file include/simdjson/westmere/numberparsing.h */ -/* begin file include/simdjson/westmere/end.h */ -SIMDJSON_UNTARGET_WESTMERE -/* end file include/simdjson/westmere/end.h */ - -#endif // SIMDJSON_IMPLEMENTATION_WESTMERE -#endif // SIMDJSON_WESTMERE_COMMON_H -/* end file include/simdjson/westmere.h */ - -// Builtin implementation - -SIMDJSON_POP_DISABLE_WARNINGS - -#endif // SIMDJSON_IMPLEMENTATIONS_H -/* end file include/simdjson/implementations.h */ - -// Determine the best builtin implementation -#ifndef SIMDJSON_BUILTIN_IMPLEMENTATION -#if SIMDJSON_CAN_ALWAYS_RUN_ICELAKE -#define SIMDJSON_BUILTIN_IMPLEMENTATION icelake -#elif SIMDJSON_CAN_ALWAYS_RUN_HASWELL -#define SIMDJSON_BUILTIN_IMPLEMENTATION haswell -#elif SIMDJSON_CAN_ALWAYS_RUN_WESTMERE -#define SIMDJSON_BUILTIN_IMPLEMENTATION westmere -#elif SIMDJSON_CAN_ALWAYS_RUN_ARM64 -#define SIMDJSON_BUILTIN_IMPLEMENTATION arm64 -#elif SIMDJSON_CAN_ALWAYS_RUN_PPC64 -#define SIMDJSON_BUILTIN_IMPLEMENTATION ppc64 -#elif SIMDJSON_CAN_ALWAYS_RUN_FALLBACK -#define SIMDJSON_BUILTIN_IMPLEMENTATION fallback -#else -#error "All possible implementations (including fallback) have been disabled! simdjson will not run." -#endif -#endif // SIMDJSON_BUILTIN_IMPLEMENTATION - -// redefining SIMDJSON_IMPLEMENTATION to "SIMDJSON_BUILTIN_IMPLEMENTATION" -// #define SIMDJSON_IMPLEMENTATION SIMDJSON_BUILTIN_IMPLEMENTATION - -// ondemand is only compiled as part of the builtin implementation at present - -// Interface declarations -/* begin file include/simdjson/generic/implementation_simdjson_result_base.h */ namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace westmere { // This is a near copy of include/error.h's implementation_simdjson_result_base, except it doesn't use std::pair // so we can avoid inlining errors @@ -22928,12 +24602,2279 @@ namespace simdjson { error_code second{ UNINITIALIZED }; /** Users should never directly access 'second'. **/ }; // struct implementation_simdjson_result_base - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace westmere } // namespace simdjson -/* end file include/simdjson/generic/implementation_simdjson_result_base.h */ -/* begin file include/simdjson/generic/ondemand.h */ + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_H +/* end file simdjson/generic/implementation_simdjson_result_base.h for westmere */ +/* including simdjson/generic/numberparsing.h for westmere: #include "simdjson/generic/numberparsing.h" */ +/* begin file simdjson/generic/numberparsing.h for westmere */ +#ifndef SIMDJSON_GENERIC_NUMBERPARSING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_NUMBERPARSING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/jsoncharutils.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include +#include + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace westmere { + namespace numberparsing { + +#ifdef JSON_TEST_NUMBERS +#define INVALID_NUMBER(SRC) (found_invalid_number((SRC)), NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (found_integer((VALUE), (SRC)), (WRITER).append_s64((VALUE))) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (found_unsigned_integer((VALUE), (SRC)), (WRITER).append_u64((VALUE))) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (found_float((VALUE), (SRC)), (WRITER).append_double((VALUE))) +#else +#define INVALID_NUMBER(SRC) (NUMBER_ERROR) +#define WRITE_INTEGER(VALUE, SRC, WRITER) (WRITER).append_s64((VALUE)) +#define WRITE_UNSIGNED(VALUE, SRC, WRITER) (WRITER).append_u64((VALUE)) +#define WRITE_DOUBLE(VALUE, SRC, WRITER) (WRITER).append_double((VALUE)) +#endif + + namespace { + + // Convert a mantissa, an exponent and a sign bit into an ieee64 double. + // The real_exponent needs to be in [0, 2046] (technically real_exponent = 2047 would be acceptable). + // The mantissa should be in [0,1<<53). The bit at index (1ULL << 52) while be zeroed. + simdjson_inline double to_double(uint64_t mantissa, uint64_t real_exponent, bool negative) { + double d; + mantissa &= ~(1ULL << 52); + mantissa |= real_exponent << 52; + mantissa |= ((static_cast(negative)) << 63); + std::memcpy(&d, &mantissa, sizeof(d)); + return d; + } + + // Attempts to compute i * 10^(power) exactly; and if "negative" is + // true, negate the result. + // This function will only work in some cases, when it does not work, success is + // set to false. This should work *most of the time* (like 99% of the time). + // We assume that power is in the [smallest_power, + // largest_power] interval: the caller is responsible for this check. + simdjson_inline bool compute_float_64(int64_t power, uint64_t i, bool negative, double& d) { + // we start with a fast path + // It was described in + // Clinger WD. How to read floating point numbers accurately. + // ACM SIGPLAN Notices. 1990 +#ifndef FLT_EVAL_METHOD +#error "FLT_EVAL_METHOD should be defined, please include cfloat." +#endif +#if (FLT_EVAL_METHOD != 1) && (FLT_EVAL_METHOD != 0) + // We cannot be certain that x/y is rounded to nearest. + if (0 <= power && power <= 22 && i <= 9007199254740991) +#else + if (-22 <= power && power <= 22 && i <= 9007199254740991) +#endif + { + // convert the integer into a double. This is lossless since + // 0 <= i <= 2^53 - 1. + d = double(i); + // + // The general idea is as follows. + // If 0 <= s < 2^53 and if 10^0 <= p <= 10^22 then + // 1) Both s and p can be represented exactly as 64-bit floating-point + // values + // (binary64). + // 2) Because s and p can be represented exactly as floating-point values, + // then s * p + // and s / p will produce correctly rounded values. + // + if (power < 0) { + d = d / simdjson::internal::power_of_ten[-power]; + } + else { + d = d * simdjson::internal::power_of_ten[power]; + } + if (negative) { + d = -d; + } + return true; + } + // When 22 < power && power < 22 + 16, we could + // hope for another, secondary fast path. It was + // described by David M. Gay in "Correctly rounded + // binary-decimal and decimal-binary conversions." (1990) + // If you need to compute i * 10^(22 + x) for x < 16, + // first compute i * 10^x, if you know that result is exact + // (e.g., when i * 10^x < 2^53), + // then you can still proceed and do (i * 10^x) * 10^22. + // Is this worth your time? + // You need 22 < power *and* power < 22 + 16 *and* (i * 10^(x-22) < 2^53) + // for this second fast path to work. + // If you you have 22 < power *and* power < 22 + 16, and then you + // optimistically compute "i * 10^(x-22)", there is still a chance that you + // have wasted your time if i * 10^(x-22) >= 2^53. It makes the use cases of + // this optimization maybe less common than we would like. Source: + // http://www.exploringbinary.com/fast-path-decimal-to-floating-point-conversion/ + // also used in RapidJSON: https://rapidjson.org/strtod_8h_source.html + + // The fast path has now failed, so we are failing back on the slower path. + + // In the slow path, we need to adjust i so that it is > 1<<63 which is always + // possible, except if i == 0, so we handle i == 0 separately. + if (i == 0) { + d = negative ? -0.0 : 0.0; + return true; + } + + + // The exponent is 1024 + 63 + power + // + floor(log(5**power)/log(2)). + // The 1024 comes from the ieee64 standard. + // The 63 comes from the fact that we use a 64-bit word. + // + // Computing floor(log(5**power)/log(2)) could be + // slow. Instead we use a fast function. + // + // For power in (-400,350), we have that + // (((152170 + 65536) * power ) >> 16); + // is equal to + // floor(log(5**power)/log(2)) + power when power >= 0 + // and it is equal to + // ceil(log(5**-power)/log(2)) + power when power < 0 + // + // The 65536 is (1<<16) and corresponds to + // (65536 * power) >> 16 ---> power + // + // ((152170 * power ) >> 16) is equal to + // floor(log(5**power)/log(2)) + // + // Note that this is not magic: 152170/(1<<16) is + // approximatively equal to log(5)/log(2). + // The 1<<16 value is a power of two; we could use a + // larger power of 2 if we wanted to. + // + int64_t exponent = (((152170 + 65536) * power) >> 16) + 1024 + 63; + + + // We want the most significant bit of i to be 1. Shift if needed. + int lz = leading_zeroes(i); + i <<= lz; + + + // We are going to need to do some 64-bit arithmetic to get a precise product. + // We use a table lookup approach. + // It is safe because + // power >= smallest_power + // and power <= largest_power + // We recover the mantissa of the power, it has a leading 1. It is always + // rounded down. + // + // We want the most significant 64 bits of the product. We know + // this will be non-zero because the most significant bit of i is + // 1. + const uint32_t index = 2 * uint32_t(power - simdjson::internal::smallest_power); + // Optimization: It may be that materializing the index as a variable might confuse some compilers and prevent effective complex-addressing loads. (Done for code clarity.) + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 firstproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index]); + // Both i and power_of_five_128[index] have their most significant bit set to 1 which + // implies that the either the most or the second most significant bit of the product + // is 1. We pack values in this manner for efficiency reasons: it maximizes the use + // we make of the product. It also makes it easy to reason about the product: there + // is 0 or 1 leading zero in the product. + + // Unless the least significant 9 bits of the high (64-bit) part of the full + // product are all 1s, then we know that the most significant 55 bits are + // exact and no further work is needed. Having 55 bits is necessary because + // we need 53 bits for the mantissa but we have to have one rounding bit and + // we can waste a bit if the most significant bit of the product is zero. + if ((firstproduct.high & 0x1FF) == 0x1FF) { + // We want to compute i * 5^q, but only care about the top 55 bits at most. + // Consider the scenario where q>=0. Then 5^q may not fit in 64-bits. Doing + // the full computation is wasteful. So we do what is called a "truncated + // multiplication". + // We take the most significant 64-bits, and we put them in + // power_of_five_128[index]. Usually, that's good enough to approximate i * 5^q + // to the desired approximation using one multiplication. Sometimes it does not suffice. + // Then we store the next most significant 64 bits in power_of_five_128[index + 1], and + // then we get a better approximation to i * 5^q. + // + // That's for when q>=0. The logic for q<0 is somewhat similar but it is somewhat + // more complicated. + // + // There is an extra layer of complexity in that we need more than 55 bits of + // accuracy in the round-to-even scenario. + // + // The full_multiplication function computes the 128-bit product of two 64-bit words + // with a returned value of type value128 with a "low component" corresponding to the + // 64-bit least significant bits of the product and with a "high component" corresponding + // to the 64-bit most significant bits of the product. + simdjson::internal::value128 secondproduct = full_multiplication(i, simdjson::internal::power_of_five_128[index + 1]); + firstproduct.low += secondproduct.high; + if (secondproduct.high > firstproduct.low) { firstproduct.high++; } + // As it has been proven by Noble Mushtak and Daniel Lemire in "Fast Number Parsing Without + // Fallback" (https://arxiv.org/abs/2212.06644), at this point we are sure that the product + // is sufficiently accurate, and more computation is not needed. + } + uint64_t lower = firstproduct.low; + uint64_t upper = firstproduct.high; + // The final mantissa should be 53 bits with a leading 1. + // We shift it so that it occupies 54 bits with a leading 1. + /////// + uint64_t upperbit = upper >> 63; + uint64_t mantissa = upper >> (upperbit + 9); + lz += int(1 ^ upperbit); + + // Here we have mantissa < (1<<54). + int64_t real_exponent = exponent - lz; + if (simdjson_unlikely(real_exponent <= 0)) { // we have a subnormal? + // Here have that real_exponent <= 0 so -real_exponent >= 0 + if (-real_exponent + 1 >= 64) { // if we have more than 64 bits below the minimum exponent, you have a zero for sure. + d = negative ? -0.0 : 0.0; + return true; + } + // next line is safe because -real_exponent + 1 < 0 + mantissa >>= -real_exponent + 1; + // Thankfully, we can't have both "round-to-even" and subnormals because + // "round-to-even" only occurs for powers close to 0. + mantissa += (mantissa & 1); // round up + mantissa >>= 1; + // There is a weird scenario where we don't have a subnormal but just. + // Suppose we start with 2.2250738585072013e-308, we end up + // with 0x3fffffffffffff x 2^-1023-53 which is technically subnormal + // whereas 0x40000000000000 x 2^-1023-53 is normal. Now, we need to round + // up 0x3fffffffffffff x 2^-1023-53 and once we do, we are no longer + // subnormal, but we can only know this after rounding. + // So we only declare a subnormal if we are smaller than the threshold. + real_exponent = (mantissa < (uint64_t(1) << 52)) ? 0 : 1; + d = to_double(mantissa, real_exponent, negative); + return true; + } + // We have to round to even. The "to even" part + // is only a problem when we are right in between two floats + // which we guard against. + // If we have lots of trailing zeros, we may fall right between two + // floating-point values. + // + // The round-to-even cases take the form of a number 2m+1 which is in (2^53,2^54] + // times a power of two. That is, it is right between a number with binary significand + // m and another number with binary significand m+1; and it must be the case + // that it cannot be represented by a float itself. + // + // We must have that w * 10 ^q == (2m+1) * 2^p for some power of two 2^p. + // Recall that 10^q = 5^q * 2^q. + // When q >= 0, we must have that (2m+1) is divible by 5^q, so 5^q <= 2^54. We have that + // 5^23 <= 2^54 and it is the last power of five to qualify, so q <= 23. + // When q<0, we have w >= (2m+1) x 5^{-q}. We must have that w<2^{64} so + // (2m+1) x 5^{-q} < 2^{64}. We have that 2m+1>2^{53}. Hence, we must have + // 2^{53} x 5^{-q} < 2^{64}. + // Hence we have 5^{-q} < 2^{11}$ or q>= -4. + // + // We require lower <= 1 and not lower == 0 because we could not prove that + // that lower == 0 is implied; but we could prove that lower <= 1 is a necessary and sufficient test. + if (simdjson_unlikely((lower <= 1) && (power >= -4) && (power <= 23) && ((mantissa & 3) == 1))) { + if ((mantissa << (upperbit + 64 - 53 - 2)) == upper) { + mantissa &= ~1; // flip it so that we do not round up + } + } + + mantissa += mantissa & 1; + mantissa >>= 1; + + // Here we have mantissa < (1<<53), unless there was an overflow + if (mantissa >= (1ULL << 53)) { + ////////// + // This will happen when parsing values such as 7.2057594037927933e+16 + //////// + mantissa = (1ULL << 52); + real_exponent++; + } + mantissa &= ~(1ULL << 52); + // we have to check that real_exponent is in range, otherwise we bail out + if (simdjson_unlikely(real_exponent > 2046)) { + // We have an infinite value!!! We could actually throw an error here if we could. + return false; + } + d = to_double(mantissa, real_exponent, negative); + return true; + } + + // We call a fallback floating-point parser that might be slow. Note + // it will accept JSON numbers, but the JSON spec. is more restrictive so + // before you call parse_float_fallback, you need to have validated the input + // string with the JSON grammar. + // It will return an error (false) if the parsed number is infinite. + // The string parsing itself always succeeds. We know that there is at least + // one digit. + static bool parse_float_fallback(const uint8_t* ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + static bool parse_float_fallback(const uint8_t* ptr, const uint8_t* end_ptr, double* outDouble) { + *outDouble = simdjson::internal::from_chars(reinterpret_cast(ptr), reinterpret_cast(end_ptr)); + // We do not accept infinite values. + + // Detecting finite values in a portable manner is ridiculously hard, ideally + // we would want to do: + // return !std::isfinite(*outDouble); + // but that mysteriously fails under legacy/old libc++ libraries, see + // https://github.com/simdjson/simdjson/issues/1286 + // + // Therefore, fall back to this solution (the extra parens are there + // to handle that max may be a macro on windows). + return !(*outDouble > (std::numeric_limits::max)() || *outDouble < std::numeric_limits::lowest()); + } + + // check quickly whether the next 8 chars are made of digits + // at a glance, it looks better than Mula's + // http://0x80.pl/articles/swar-digits-validate.html + simdjson_inline bool is_made_of_eight_digits_fast(const uint8_t* chars) { + uint64_t val; + // this can read up to 7 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(7 <= SIMDJSON_PADDING, "SIMDJSON_PADDING must be bigger than 7"); + std::memcpy(&val, chars, 8); + // a branchy method might be faster: + // return (( val & 0xF0F0F0F0F0F0F0F0 ) == 0x3030303030303030) + // && (( (val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0 ) == + // 0x3030303030303030); + return (((val & 0xF0F0F0F0F0F0F0F0) | + (((val + 0x0606060606060606) & 0xF0F0F0F0F0F0F0F0) >> 4)) == + 0x3333333333333333); + } + + template + SIMDJSON_NO_SANITIZE_UNDEFINED // We deliberately allow overflow here and check later + simdjson_inline bool parse_digit(const uint8_t c, I& i) { + const uint8_t digit = static_cast(c - '0'); + if (digit > 9) { + return false; + } + // PERF NOTE: multiplication by 10 is cheaper than arbitrary integer multiplication + i = 10 * i + digit; // might overflow, we will handle the overflow later + return true; + } + + simdjson_inline error_code parse_decimal_after_separator(simdjson_unused const uint8_t* const src, const uint8_t*& p, uint64_t& i, int64_t& exponent) { + // we continue with the fiction that we have an integer. If the + // floating point number is representable as x * 10^z for some integer + // z that fits in 53 bits, then we will be able to convert back the + // the integer into a float in a lossless manner. + const uint8_t* const first_after_period = p; + +#ifdef SIMDJSON_SWAR_NUMBER_PARSING +#if SIMDJSON_SWAR_NUMBER_PARSING + // this helps if we have lots of decimals! + // this turns out to be frequent enough. + if (is_made_of_eight_digits_fast(p)) { + i = i * 100000000 + parse_eight_digits_unrolled(p); + p += 8; + } +#endif // SIMDJSON_SWAR_NUMBER_PARSING +#endif // #ifdef SIMDJSON_SWAR_NUMBER_PARSING + // Unrolling the first digit makes a small difference on some implementations (e.g. westmere) + if (parse_digit(*p, i)) { ++p; } + while (parse_digit(*p, i)) { p++; } + exponent = first_after_period - p; + // Decimal without digits (123.) is illegal + if (exponent == 0) { + return INVALID_NUMBER(src); + } + return SUCCESS; + } + + simdjson_inline error_code parse_exponent(simdjson_unused const uint8_t* const src, const uint8_t*& p, int64_t& exponent) { + // Exp Sign: -123.456e[-]78 + bool neg_exp = ('-' == *p); + if (neg_exp || '+' == *p) { p++; } // Skip + as well + + // Exponent: -123.456e-[78] + auto start_exp = p; + int64_t exp_number = 0; + while (parse_digit(*p, exp_number)) { ++p; } + // It is possible for parse_digit to overflow. + // In particular, it could overflow to INT64_MIN, and we cannot do - INT64_MIN. + // Thus we *must* check for possible overflow before we negate exp_number. + + // Performance notes: it may seem like combining the two "simdjson_unlikely checks" below into + // a single simdjson_unlikely path would be faster. The reasoning is sound, but the compiler may + // not oblige and may, in fact, generate two distinct paths in any case. It might be + // possible to do uint64_t(p - start_exp - 1) >= 18 but it could end up trading off + // instructions for a simdjson_likely branch, an unconclusive gain. + + // If there were no digits, it's an error. + if (simdjson_unlikely(p == start_exp)) { + return INVALID_NUMBER(src); + } + // We have a valid positive exponent in exp_number at this point, except that + // it may have overflowed. + + // If there were more than 18 digits, we may have overflowed the integer. We have to do + // something!!!! + if (simdjson_unlikely(p > start_exp + 18)) { + // Skip leading zeroes: 1e000000000000000000001 is technically valid and doesn't overflow + while (*start_exp == '0') { start_exp++; } + // 19 digits could overflow int64_t and is kind of absurd anyway. We don't + // support exponents smaller than -999,999,999,999,999,999 and bigger + // than 999,999,999,999,999,999. + // We can truncate. + // Note that 999999999999999999 is assuredly too large. The maximal ieee64 value before + // infinity is ~1.8e308. The smallest subnormal is ~5e-324. So, actually, we could + // truncate at 324. + // Note that there is no reason to fail per se at this point in time. + // E.g., 0e999999999999999999999 is a fine number. + if (p > start_exp + 18) { exp_number = 999999999999999999; } + } + // At this point, we know that exp_number is a sane, positive, signed integer. + // It is <= 999,999,999,999,999,999. As long as 'exponent' is in + // [-8223372036854775808, 8223372036854775808], we won't overflow. Because 'exponent' + // is bounded in magnitude by the size of the JSON input, we are fine in this universe. + // To sum it up: the next line should never overflow. + exponent += (neg_exp ? -exp_number : exp_number); + return SUCCESS; + } + + simdjson_inline size_t significant_digits(const uint8_t* start_digits, size_t digit_count) { + // It is possible that the integer had an overflow. + // We have to handle the case where we have 0.0000somenumber. + const uint8_t* start = start_digits; + while ((*start == '0') || (*start == '.')) { ++start; } + // we over-decrement by one when there is a '.' + return digit_count - size_t(start - start_digits); + } + + } // unnamed namespace + + /** @private */ + template + error_code slow_float_parsing(simdjson_unused const uint8_t* src, W writer) { + double d; + if (parse_float_fallback(src, &d)) { + writer.append_double(d); + return SUCCESS; + } + return INVALID_NUMBER(src); + } + + /** @private */ + template + simdjson_inline error_code write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer) { + // If we frequently had to deal with long strings of digits, + // we could extend our code by using a 128-bit integer instead + // of a 64-bit integer. However, this is uncommon in practice. + // + // 9999999999999999999 < 2**64 so we can accommodate 19 digits. + // If we have a decimal separator, then digit_count - 1 is the number of digits, but we + // may not have a decimal separator! + if (simdjson_unlikely(digit_count > 19 && significant_digits(start_digits, digit_count) > 19)) { + // Ok, chances are good that we had an overflow! + // this is almost never going to get called!!! + // we start anew, going slowly!!! + // This will happen in the following examples: + // 10000000000000000000000000000000000000000000e+308 + // 3.1415926535897932384626433832795028841971693993751 + // + // NOTE: This makes a *copy* of the writer and passes it to slow_float_parsing. This happens + // because slow_float_parsing is a non-inlined function. If we passed our writer reference to + // it, it would force it to be stored in memory, preventing the compiler from picking it apart + // and putting into registers. i.e. if we pass it as reference, it gets slow. + // This is what forces the skip_double, as well. + error_code error = slow_float_parsing(src, writer); + writer.skip_double(); + return error; + } + // NOTE: it's weird that the simdjson_unlikely() only wraps half the if, but it seems to get slower any other + // way we've tried: https://github.com/simdjson/simdjson/pull/990#discussion_r448497331 + // To future reader: we'd love if someone found a better way, or at least could explain this result! + if (simdjson_unlikely(exponent < simdjson::internal::smallest_power) || (exponent > simdjson::internal::largest_power)) { + // + // Important: smallest_power is such that it leads to a zero value. + // Observe that 18446744073709551615e-343 == 0, i.e. (2**64 - 1) e -343 is zero + // so something x 10^-343 goes to zero, but not so with something x 10^-342. + static_assert(simdjson::internal::smallest_power <= -342, "smallest_power is not small enough"); + // + if ((exponent < simdjson::internal::smallest_power) || (i == 0)) { + // E.g. Parse "-0.0e-999" into the same value as "-0.0". See https://en.wikipedia.org/wiki/Signed_zero + WRITE_DOUBLE(negative ? -0.0 : 0.0, src, writer); + return SUCCESS; + } + else { // (exponent > largest_power) and (i != 0) + // We have, for sure, an infinite value and simdjson refuses to parse infinite values. + return INVALID_NUMBER(src); + } + } + double d; + if (!compute_float_64(exponent, i, negative, d)) { + // we are almost never going to get here. + if (!parse_float_fallback(src, &d)) { return INVALID_NUMBER(src); } + } + WRITE_DOUBLE(d, src, writer); + return SUCCESS; + } + + // for performance analysis, it is sometimes useful to skip parsing +#ifdef SIMDJSON_SKIPNUMBERPARSING + + template + simdjson_inline error_code parse_number(const uint8_t* const, W& writer) { + writer.append_s64(0); // always write zero + return SUCCESS; // always succeeds + } + + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* const src) noexcept { return 0; } + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { return false; } + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { return number_type::signed_integer; } +#else + +// parse the number at src +// define JSON_TEST_NUMBERS for unit testing +// +// It is assumed that the number is followed by a structural ({,},],[) character +// or a white space character. If that is not the case (e.g., when the JSON +// document is made of a single number), then it is necessary to copy the +// content and append a space before calling this function. +// +// Our objective is accurate parsing (ULP of 0) at high speed. + template + simdjson_inline error_code parse_number(const uint8_t* const src, W& writer) { + + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + if (digit_count == 0 || ('0' == *start_digits && digit_count > 1)) { return INVALID_NUMBER(src); } + + // + // Handle floats if there is a . or e (or both) + // + int64_t exponent = 0; + bool is_float = false; + if ('.' == *p) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_decimal_after_separator(src, p, i, exponent)); + digit_count = int(p - start_digits); // used later to guard against overflows + } + if (('e' == *p) || ('E' == *p)) { + is_float = true; + ++p; + SIMDJSON_TRY(parse_exponent(src, p, exponent)); + } + if (is_float) { + const bool dirty_end = jsoncharutils::is_not_structural_or_whitespace(*p); + SIMDJSON_TRY(write_float(src, negative, i, start_digits, digit_count, exponent, writer)); + if (dirty_end) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // The longest negative 64-bit number is 19 digits. + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + size_t longest_digit_count = negative ? 19 : 20; + if (digit_count > longest_digit_count) { return INVALID_NUMBER(src); } + if (digit_count == longest_digit_count) { + if (negative) { + // Anything negative above INT64_MAX+1 is invalid + if (i > uint64_t(INT64_MAX) + 1) { return INVALID_NUMBER(src); } + WRITE_INTEGER(~i + 1, src, writer); + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + } + else if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INVALID_NUMBER(src); } + } + + // Write unsigned if it doesn't fit in a signed integer. + if (i > uint64_t(INT64_MAX)) { + WRITE_UNSIGNED(i, src, writer); + } + else { + WRITE_INTEGER(negative ? (~i + 1) : i, src, writer); + } + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return INVALID_NUMBER(src); } + return SUCCESS; + } + + // Inlineable functions + namespace { + + // This table can be used to characterize the final character of an integer + // string. For JSON structural character and allowable white space characters, + // we return SUCCESS. For 'e', '.' and 'E', we return INCORRECT_TYPE. Otherwise + // we return NUMBER_ERROR. + // Optimization note: we could easily reduce the size of the table by half (to 128) + // at the cost of an extra branch. + // Optimization note: we want the values to use at most 8 bits (not, e.g., 32 bits): + static_assert(error_code(uint8_t(NUMBER_ERROR)) == NUMBER_ERROR, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(SUCCESS)) == SUCCESS, "bad NUMBER_ERROR cast"); + static_assert(error_code(uint8_t(INCORRECT_TYPE)) == INCORRECT_TYPE, "bad NUMBER_ERROR cast"); + + const uint8_t integer_string_finisher[256] = { + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, INCORRECT_TYPE, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, SUCCESS, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, INCORRECT_TYPE, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, SUCCESS, NUMBER_ERROR, + SUCCESS, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, NUMBER_ERROR, + NUMBER_ERROR }; + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + + // Parse any number from 0 to 18,446,744,073,709,551,615 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_unsigned(const uint8_t* const src, const uint8_t* const src_end) noexcept { + const uint8_t* p = src; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + if (src[0] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from 0 to 18,446,744,073,709,551,615 + simdjson_unused simdjson_inline simdjson_result parse_unsigned_in_string(const uint8_t* const src) noexcept { + const uint8_t* p = src + 1; + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // The longest positive 64-bit number is 20 digits. + // We do it this way so we don't trigger this branch unless we must. + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > 20)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > 20)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*p != '"') { return NUMBER_ERROR; } + + if (digit_count == 20) { + // Positive overflow check: + // - A 20 digit number starting with 2-9 is overflow, because 18,446,744,073,709,551,615 is the + // biggest uint64_t. + // - A 20 digit number starting with 1 is overflow if it is less than INT64_MAX. + // If we got here, it's a 20 digit number starting with the digit "1". + // - If a 20 digit number starting with 1 overflowed (i*10+digit), the result will be smaller + // than 1,553,255,926,290,448,384. + // - That is smaller than the smallest possible 20-digit number the user could write: + // 10,000,000,000,000,000,000. + // - Therefore, if the number is positive and lower than that, it's overflow. + // - The value we are looking at is less than or equal to INT64_MAX. + // + // Note: we use src[1] and not src[0] because src[0] is the quote character in this + // instance. + if (src[1] != uint8_t('1') || i <= uint64_t(INT64_MAX)) { return INCORRECT_TYPE; } + } + + return i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while (parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_integer(const uint8_t* const src, const uint8_t* const src_end) noexcept { + // + // Check for minus sign + // + if (src == src_end) { return NUMBER_ERROR; } + bool negative = (*src == '-'); + const uint8_t* p = src + uint8_t(negative); + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = p; + uint64_t i = 0; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(p - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*p)) { + // return (*p == '.' || *p == 'e' || *p == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if ((p != src_end) && integer_string_finisher[*p] != SUCCESS) { return error_code(integer_string_finisher[*p]); } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + // Parse any number from -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + simdjson_unused simdjson_inline simdjson_result parse_integer_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + // PERF NOTE: we don't use is_made_of_eight_digits_fast because large integers like 123456789 are rare + const uint8_t* const start_digits = src; + uint64_t i = 0; + while (parse_digit(*src, i)) { src++; } + + // If there were no digits, or if the integer starts with 0 and has more than one digit, it's an error. + // Optimization note: size_t is expected to be unsigned. + size_t digit_count = size_t(src - start_digits); + // We go from + // -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 + // so we can never represent numbers that have more than 19 digits. + size_t longest_digit_count = 19; + // Optimization note: the compiler can probably merge + // ((digit_count == 0) || (digit_count > longest_digit_count)) + // into a single branch since digit_count is unsigned. + if ((digit_count == 0) || (digit_count > longest_digit_count)) { return INCORRECT_TYPE; } + // Here digit_count > 0. + if (('0' == *start_digits) && (digit_count > 1)) { return NUMBER_ERROR; } + // We can do the following... + // if (!jsoncharutils::is_structural_or_whitespace(*src)) { + // return (*src == '.' || *src == 'e' || *src == 'E') ? INCORRECT_TYPE : NUMBER_ERROR; + // } + // as a single table lookup: + if (*src != '"') { return NUMBER_ERROR; } + // Negative numbers have can go down to - INT64_MAX - 1 whereas positive numbers are limited to INT64_MAX. + // Performance note: This check is only needed when digit_count == longest_digit_count but it is + // so cheap that we might as well always make it. + if (i > uint64_t(INT64_MAX) + uint64_t(negative)) { return INCORRECT_TYPE; } + return negative ? (~i + 1) : i; + } + + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline bool is_negative(const uint8_t* src) noexcept { + return (*src == '-'); + } + + simdjson_unused simdjson_inline simdjson_result is_integer(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { return true; } + return false; + } + + simdjson_unused simdjson_inline simdjson_result get_number_type(const uint8_t* src) noexcept { + bool negative = (*src == '-'); + src += uint8_t(negative); + const uint8_t* p = src; + while (static_cast(*p - '0') <= 9) { p++; } + if (p == src) { return NUMBER_ERROR; } + if (jsoncharutils::is_structural_or_whitespace(*p)) { + // We have an integer. + // If the number is negative and valid, it must be a signed integer. + if (negative) { return number_type::signed_integer; } + // We want values larger or equal to 9223372036854775808 to be unsigned + // integers, and the other values to be signed integers. + int digit_count = int(p - src); + if (digit_count >= 19) { + const uint8_t* smaller_big_integer = reinterpret_cast("9223372036854775808"); + if ((digit_count >= 20) || (memcmp(src, smaller_big_integer, 19) >= 0)) { + return number_type::unsigned_integer; + } + } + return number_type::signed_integer; + } + // Hopefully, we have 'e' or 'E' or '.'. + return number_type::floating_point_number; + } + + // Never read at src_end or beyond + simdjson_unused simdjson_inline simdjson_result parse_double(const uint8_t* src, const uint8_t* const src_end) noexcept { + if (src == src_end) { return NUMBER_ERROR; } + // + // Check for minus sign + // + bool negative = (*src == '-'); + src += uint8_t(negative); + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + if (p == src_end) { return NUMBER_ERROR; } + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while ((p != src_end) && parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely((p != src_end) && (*p == '.'))) { + p++; + const uint8_t* start_decimal_digits = p; + if ((p == src_end) || !parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while ((p != src_end) && parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = start_digits - src > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if ((p != src_end) && (*p == 'e' || *p == 'E')) { + p++; + if (p == src_end) { return NUMBER_ERROR; } + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while ((p != src_end) && parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if ((p != src_end) && jsoncharutils::is_not_structural_or_whitespace(*p)) { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), src_end, &d)) { + return NUMBER_ERROR; + } + return d; + } + + simdjson_unused simdjson_inline simdjson_result parse_double_in_string(const uint8_t* src) noexcept { + // + // Check for minus sign + // + bool negative = (*(src + 1) == '-'); + src += uint8_t(negative) + 1; + + // + // Parse the integer part. + // + uint64_t i = 0; + const uint8_t* p = src; + p += parse_digit(*p, i); + bool leading_zero = (i == 0); + while (parse_digit(*p, i)) { p++; } + // no integer digits, or 0123 (zero must be solo) + if (p == src) { return INCORRECT_TYPE; } + if ((leading_zero && p != src + 1)) { return NUMBER_ERROR; } + + // + // Parse the decimal part. + // + int64_t exponent = 0; + bool overflow; + if (simdjson_likely(*p == '.')) { + p++; + const uint8_t* start_decimal_digits = p; + if (!parse_digit(*p, i)) { return NUMBER_ERROR; } // no decimal digits + p++; + while (parse_digit(*p, i)) { p++; } + exponent = -(p - start_decimal_digits); + + // Overflow check. More than 19 digits (minus the decimal) may be overflow. + overflow = p - src - 1 > 19; + if (simdjson_unlikely(overflow && leading_zero)) { + // Skip leading 0.00000 and see if it still overflows + const uint8_t* start_digits = src + 2; + while (*start_digits == '0') { start_digits++; } + overflow = p - start_digits > 19; + } + } + else { + overflow = p - src > 19; + } + + // + // Parse the exponent + // + if (*p == 'e' || *p == 'E') { + p++; + bool exp_neg = *p == '-'; + p += exp_neg || *p == '+'; + + uint64_t exp = 0; + const uint8_t* start_exp_digits = p; + while (parse_digit(*p, exp)) { p++; } + // no exp digits, or 20+ exp digits + if (p - start_exp_digits == 0 || p - start_exp_digits > 19) { return NUMBER_ERROR; } + + exponent += exp_neg ? 0 - exp : exp; + } + + if (*p != '"') { return NUMBER_ERROR; } + + overflow = overflow || exponent < simdjson::internal::smallest_power || exponent > simdjson::internal::largest_power; + + // + // Assemble (or slow-parse) the float + // + double d; + if (simdjson_likely(!overflow)) { + if (compute_float_64(exponent, i, negative, d)) { return d; } + } + if (!parse_float_fallback(src - uint8_t(negative), &d)) { + return NUMBER_ERROR; + } + return d; + } + + } // unnamed namespace +#endif // SIMDJSON_SKIPNUMBERPARSING + + } // namespace numberparsing + + inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { + switch (type) { + case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; + case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; + case number_type::floating_point_number: out << "floating-point number (binary64)"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_NUMBERPARSING_H +/* end file simdjson/generic/numberparsing.h for westmere */ + +/* including simdjson/generic/implementation_simdjson_result_base-inl.h for westmere: #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* begin file simdjson/generic/implementation_simdjson_result_base-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + + // + // internal::implementation_simdjson_result_base inline implementation + // + + template + simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { + error = this->second; + if (!error) { + value = std::forward>(*this).first; + } + } + + template + simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { + error_code error; + std::forward>(*this).tie(value, error); + return error; + } + + template + simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { + return this->second; + } + +#if SIMDJSON_EXCEPTIONS + + template + simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { + return std::forward>(*this).take_value(); + } + + template + simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { + return std::forward>(*this).take_value(); + } + +#endif // SIMDJSON_EXCEPTIONS + + template + simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { + return this->first; + } + + template + simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { + return this->first; + } + + template + simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { + return std::forward(this->first); + } + + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept + : first{ std::forward(value) }, second{ error } {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept + : implementation_simdjson_result_base(T{}, error) {} + template + simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept + : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_IMPLEMENTATION_SIMDJSON_RESULT_BASE_INL_H +/* end file simdjson/generic/implementation_simdjson_result_base-inl.h for westmere */ +/* end file simdjson/generic/amalgamated.h for westmere */ +/* including simdjson/westmere/end.h: #include "simdjson/westmere/end.h" */ +/* begin file simdjson/westmere/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "westmere" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/westmere/end.h */ + +#endif // SIMDJSON_WESTMERE_H +/* end file simdjson/westmere.h */ +#else +#error Unknown SIMDJSON_BUILTIN_IMPLEMENTATION +#endif + +/* undefining SIMDJSON_CONDITIONAL_INCLUDE */ +#undef SIMDJSON_CONDITIONAL_INCLUDE + +#endif // SIMDJSON_BUILTIN_H +/* end file simdjson/builtin.h */ +/* skipped duplicate #include "simdjson/builtin/base.h" */ + +/* including simdjson/generic/ondemand/dependencies.h: #include "simdjson/generic/ondemand/dependencies.h" */ +/* begin file simdjson/generic/ondemand/dependencies.h */ +#ifdef SIMDJSON_CONDITIONAL_INCLUDE +#error simdjson/generic/ondemand/dependencies.h must be included before defining SIMDJSON_CONDITIONAL_INCLUDE! +#endif + +#ifndef SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H +#define SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H + +// Internal headers needed for ondemand generics. +// All includes not under simdjson/generic/ondemand must be here! +// Otherwise, amalgamation will fail. +/* skipped duplicate #include "simdjson/dom/base.h" // for MINIMAL_DOCUMENT_CAPACITY */ +/* skipped duplicate #include "simdjson/implementation.h" */ +/* skipped duplicate #include "simdjson/padded_string.h" */ +/* skipped duplicate #include "simdjson/padded_string_view.h" */ +/* skipped duplicate #include "simdjson/internal/dom_parser_implementation.h" */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H +/* end file simdjson/generic/ondemand/dependencies.h */ + +/* defining SIMDJSON_CONDITIONAL_INCLUDE */ +#define SIMDJSON_CONDITIONAL_INCLUDE + +#if SIMDJSON_BUILTIN_IMPLEMENTATION_IS(arm64) +/* including simdjson/arm64/ondemand.h: #include "simdjson/arm64/ondemand.h" */ +/* begin file simdjson/arm64/ondemand.h */ +#ifndef SIMDJSON_ARM64_ONDEMAND_H +#define SIMDJSON_ARM64_ONDEMAND_H + +/* including simdjson/arm64/begin.h: #include "simdjson/arm64/begin.h" */ +/* begin file simdjson/arm64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "arm64" */ +#define SIMDJSON_IMPLEMENTATION arm64 +/* including simdjson/arm64/base.h: #include "simdjson/arm64/base.h" */ +/* begin file simdjson/arm64/base.h */ +#ifndef SIMDJSON_ARM64_BASE_H +#define SIMDJSON_ARM64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for NEON (ARMv8). + */ + namespace arm64 { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_BASE_H +/* end file simdjson/arm64/base.h */ +/* including simdjson/arm64/intrinsics.h: #include "simdjson/arm64/intrinsics.h" */ +/* begin file simdjson/arm64/intrinsics.h */ +#ifndef SIMDJSON_ARM64_INTRINSICS_H +#define SIMDJSON_ARM64_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This should be the correct header whether +// you use visual studio or other compilers. +#include + +static_assert(sizeof(uint8x16_t) <= simdjson::SIMDJSON_PADDING, "insufficient padding for arm64"); + +#endif // SIMDJSON_ARM64_INTRINSICS_H +/* end file simdjson/arm64/intrinsics.h */ +/* including simdjson/arm64/bitmanipulation.h: #include "simdjson/arm64/bitmanipulation.h" */ +/* begin file simdjson/arm64/bitmanipulation.h */ +#ifndef SIMDJSON_ARM64_BITMANIPULATION_H +#define SIMDJSON_ARM64_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int count_ones(uint64_t input_num) { + return vaddv_u8(vcnt_u8(vcreate_u8(input_num))); + } + + +#if defined(__GNUC__) // catches clang and gcc + /** + * ARM has a fast 64-bit "bit reversal function" that is handy. However, + * it is not generally available as an intrinsic function under Visual + * Studio (though this might be changing). Even under clang/gcc, we + * apparently need to invoke inline assembly. + */ + /* + * We use SIMDJSON_PREFER_REVERSE_BITS as a hint that algorithms that + * work well with bit reversal may use it. + */ +#define SIMDJSON_PREFER_REVERSE_BITS 1 + + /* reverse the bits */ + simdjson_inline uint64_t reverse_bits(uint64_t input_num) { + uint64_t rev_bits; + __asm("rbit %0, %1" : "=r"(rev_bits) : "r"(input_num)); + return rev_bits; + } + + /** + * Flips bit at index 63 - lz. Thus if you have 'leading_zeroes' leading zeroes, + * then this will set to zero the leading bit. It is possible for leading_zeroes to be + * greating or equal to 63 in which case we trigger undefined behavior, but the output + * of such undefined behavior is never used. + **/ + SIMDJSON_NO_SANITIZE_UNDEFINED + simdjson_inline uint64_t zero_leading_bit(uint64_t rev_bits, int leading_zeroes) { + return rev_bits ^ (uint64_t(0x8000000000000000) >> leading_zeroes); + } + +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, uint64_t* result) { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + * result = value1 + value2; + return *result < value1; +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_BITMANIPULATION_H +/* end file simdjson/arm64/bitmanipulation.h */ +/* including simdjson/arm64/bitmask.h: #include "simdjson/arm64/bitmask.h" */ +/* begin file simdjson/arm64/bitmask.h */ +#ifndef SIMDJSON_ARM64_BITMASK_H +#define SIMDJSON_ARM64_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(uint64_t bitmask) { + ///////////// + // We could do this with PMULL, but it is apparently slow. + // + //#ifdef __ARM_FEATURE_CRYPTO // some ARM processors lack this extension + //return vmull_p64(-1ULL, bitmask); + //#else + // Analysis by @sebpop: + // When diffing the assembly for src/stage1_find_marks.cpp I see that the eors are all spread out + // in between other vector code, so effectively the extra cycles of the sequence do not matter + // because the GPR units are idle otherwise and the critical path is on the FP side. + // Also the PMULL requires two extra fmovs: GPR->FP (3 cycles in N1, 5 cycles in A72 ) + // and FP->GPR (2 cycles on N1 and 5 cycles on A72.) + /////////// + bitmask ^= bitmask << 1; + bitmask ^= bitmask << 2; + bitmask ^= bitmask << 4; + bitmask ^= bitmask << 8; + bitmask ^= bitmask << 16; + bitmask ^= bitmask << 32; + return bitmask; + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif +/* end file simdjson/arm64/bitmask.h */ +/* including simdjson/arm64/numberparsing_defs.h: #include "simdjson/arm64/numberparsing_defs.h" */ +/* begin file simdjson/arm64/numberparsing_defs.h */ +#ifndef SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +#define SIMDJSON_ARM64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if _M_ARM64 +// __umulh requires intrin.h +#include +#endif // _M_ARM64 + +namespace simdjson { + namespace arm64 { + namespace numberparsing { + + // we don't have SSE, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace arm64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ARM64_NUMBERPARSING_DEFS_H +/* end file simdjson/arm64/numberparsing_defs.h */ +/* including simdjson/arm64/simd.h: #include "simdjson/arm64/simd.h" */ +/* begin file simdjson/arm64/simd.h */ +#ifndef SIMDJSON_ARM64_SIMD_H +#define SIMDJSON_ARM64_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + namespace simd { + +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + namespace { + // Start of private section with Visual Studio workaround + + +#ifndef simdjson_make_uint8x16_t +#define simdjson_make_uint8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + uint8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x16_t +#define simdjson_make_int8x16_t(x1, x2, x3, x4, x5, x6, x7, x8, x9, x10, x11, x12, \ + x13, x14, x15, x16) \ + ([=]() { \ + int8_t array[16] = {x1, x2, x3, x4, x5, x6, x7, x8, \ + x9, x10, x11, x12, x13, x14, x15, x16}; \ + return vld1q_s8(array); \ + }()) +#endif + +#ifndef simdjson_make_uint8x8_t +#define simdjson_make_uint8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_u8(array); \ + }()) +#endif +#ifndef simdjson_make_int8x8_t +#define simdjson_make_int8x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int8_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1_s8(array); \ + }()) +#endif +#ifndef simdjson_make_uint16x8_t +#define simdjson_make_uint16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + uint16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_u16(array); \ + }()) +#endif +#ifndef simdjson_make_int16x8_t +#define simdjson_make_int16x8_t(x1, x2, x3, x4, x5, x6, x7, x8) \ + ([=]() { \ + int16_t array[8] = {x1, x2, x3, x4, x5, x6, x7, x8}; \ + return vld1q_s16(array); \ + }()) +#endif + +// End of private section with Visual Studio workaround + } // namespace +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + + + template + struct simd8; + + // + // Base class of simd8 and simd8, both of which use uint8x16_t internally. + // + template> + struct base_u8 { + uint8x16_t value; + static const int SIZE = sizeof(value); + + // Conversion from/to SIMD register + simdjson_inline base_u8(const uint8x16_t _value) : value(_value) {} + simdjson_inline operator const uint8x16_t& () const { return this->value; } + simdjson_inline operator uint8x16_t& () { return this->value; } + + // Bit operations + simdjson_inline simd8 operator|(const simd8 other) const { return vorrq_u8(*this, other); } + simdjson_inline simd8 operator&(const simd8 other) const { return vandq_u8(*this, other); } + simdjson_inline simd8 operator^(const simd8 other) const { return veorq_u8(*this, other); } + simdjson_inline simd8 bit_andnot(const simd8 other) const { return vbicq_u8(*this, other); } + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + simdjson_inline simd8& operator|=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline simd8& operator&=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline simd8& operator^=(const simd8 other) { auto this_cast = static_cast*>(this); *this_cast = *this_cast ^ other; return *this_cast; } + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return vceqq_u8(lhs, rhs); } + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return vextq_u8(prev_chunk, *this, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base_u8 { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + static simdjson_inline simd8 splat(bool _value) { return vmovq_n_u8(uint8_t(-(!!_value))); } + + simdjson_inline simd8(const uint8x16_t _value) : base_u8(_value) {} + // False constructor + simdjson_inline simd8() : simd8(vdupq_n_u8(0)) {} + // Splat constructor + simdjson_inline simd8(bool _value) : simd8(splat(_value)) {} + + // We return uint32_t instead of uint16_t because that seems to be more efficient for most + // purposes (cutting it down to uint16_t costs performance in some compilers). + simdjson_inline uint32_t to_bitmask() const { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + const uint8x16_t bit_mask = simdjson_make_uint8x16_t(0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80); +#else + const uint8x16_t bit_mask = { 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 }; +#endif + auto minput = *this & bit_mask; + uint8x16_t tmp = vpaddq_u8(minput, minput); + tmp = vpaddq_u8(tmp, tmp); + tmp = vpaddq_u8(tmp, tmp); + return vgetq_lane_u16(vreinterpretq_u16_u8(tmp), 0); + } + simdjson_inline bool any() const { return vmaxvq_u8(*this) != 0; } + }; + + // Unsigned bytes + template<> + struct simd8 : base_u8 { + static simdjson_inline uint8x16_t splat(uint8_t _value) { return vmovq_n_u8(_value); } + static simdjson_inline uint8x16_t zero() { return vdupq_n_u8(0); } + static simdjson_inline uint8x16_t load(const uint8_t* values) { return vld1q_u8(values); } + + simdjson_inline simd8(const uint8x16_t _value) : base_u8(_value) {} + // Zero constructor + simdjson_inline simd8() : simd8(zero()) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[16]) : simd8(load(values)) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Member-by-member initialization +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(simdjson_make_uint8x16_t( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} +#else + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(uint8x16_t{ + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10,v11,v12,v13,v14,v15 + }) {} +#endif + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Store to array + simdjson_inline void store(uint8_t dst[16]) const { return vst1q_u8(dst, *this); } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return vqaddq_u8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return vqsubq_u8(*this, other); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return vaddq_u8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return vsubq_u8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *this; } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *this; } + + // Order-specific operations + simdjson_inline uint8_t max_val() const { return vmaxvq_u8(*this); } + simdjson_inline uint8_t min_val() const { return vminvq_u8(*this); } + simdjson_inline simd8 max_val(const simd8 other) const { return vmaxq_u8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return vminq_u8(*this, other); } + simdjson_inline simd8 operator<=(const simd8 other) const { return vcleq_u8(*this, other); } + simdjson_inline simd8 operator>=(const simd8 other) const { return vcgeq_u8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return vcltq_u8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return vcgtq_u8(*this, other); } + // Same as >, but instead of guaranteeing all 1's == true, false = 0 and true = nonzero. For ARM, returns all 1's. + simdjson_inline simd8 gt_bits(const simd8 other) const { return simd8(*this > other); } + // Same as <, but instead of guaranteeing all 1's == true, false = 0 and true = nonzero. For ARM, returns all 1's. + simdjson_inline simd8 lt_bits(const simd8 other) const { return simd8(*this < other); } + + // Bit-specific operations + simdjson_inline simd8 any_bits_set(simd8 bits) const { return vtstq_u8(*this, bits); } + simdjson_inline bool any_bits_set_anywhere() const { return this->max_val() != 0; } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return (*this & bits).any_bits_set_anywhere(); } + template + simdjson_inline simd8 shr() const { return vshrq_n_u8(*this, N); } + template + simdjson_inline simd8 shl() const { return vshlq_n_u8(*this, N); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return lookup_table.apply_lookup_16_to(*this); + } + + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint16_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + uint64x2_t shufmask64 = { thintable_epi8[mask1], thintable_epi8[mask2] }; + uint8x16_t shufmask = vreinterpretq_u8_u64(shufmask64); + // we increment by 0x08 the second half of the mask +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + uint8x16_t inc = simdjson_make_uint8x16_t(0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); +#else + uint8x16_t inc = { 0, 0, 0, 0, 0, 0, 0, 0, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; +#endif + shufmask = vaddq_u8(shufmask, inc); + // this is the version "nearly pruned" + uint8x16_t pruned = vqtbl1q_u8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + uint8x16_t compactmask = vld1q_u8(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + uint8x16_t answer = vqtbl1q_u8(pruned, compactmask); + vst1q_u8(reinterpret_cast(output), answer); + } + + // Copies all bytes corresponding to a 0 in the low half of the mask (interpreted as a + // bitset) to output1, then those corresponding to a 0 in the high half to output2. + template + simdjson_inline void compress_halves(uint16_t mask, L* output1, L* output2) const { + using internal::thintable_epi8; + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + uint8x8_t compactmask1 = vcreate_u8(thintable_epi8[mask1]); + uint8x8_t compactmask2 = vcreate_u8(thintable_epi8[mask2]); + // we increment by 0x08 the second half of the mask +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + uint8x8_t inc = simdjson_make_uint8x8_t(0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08); +#else + uint8x8_t inc = { 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08, 0x08 }; +#endif + compactmask2 = vadd_u8(compactmask2, inc); + // store each result (with the second store possibly overlapping the first) + vst1_u8((uint8_t*)output1, vqtbl1_u8(*this, compactmask1)); + vst1_u8((uint8_t*)output2, vqtbl1_u8(*this, compactmask2)); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + + template + simdjson_inline simd8 apply_lookup_16_to(const simd8 original) { + return vqtbl1q_u8(*this, simd8(original)); + } + }; + + // Signed bytes + template<> + struct simd8 { + int8x16_t value; + + static simdjson_inline simd8 splat(int8_t _value) { return vmovq_n_s8(_value); } + static simdjson_inline simd8 zero() { return vdupq_n_s8(0); } + static simdjson_inline simd8 load(const int8_t values[16]) { return vld1q_s8(values); } + + // Conversion from/to SIMD register + simdjson_inline simd8(const int8x16_t _value) : value{ _value } {} + simdjson_inline operator const int8x16_t& () const { return this->value; } + simdjson_inline operator int8x16_t& () { return this->value; } + + // Zero constructor + simdjson_inline simd8() : simd8(zero()) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(simdjson_make_int8x16_t( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} +#else + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(int8x16_t{ + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10,v11,v12,v13,v14,v15 + }) {} +#endif + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Store to array + simdjson_inline void store(int8_t dst[16]) const { return vst1q_s8(dst, *this); } + + // Explicit conversion to/from unsigned + // + // Under Visual Studio/ARM64 uint8x16_t and int8x16_t are apparently the same type. + // In theory, we could check this occurrence with std::same_as and std::enabled_if but it is C++14 + // and relatively ugly and hard to read. +#ifndef SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline explicit simd8(const uint8x16_t other) : simd8(vreinterpretq_s8_u8(other)) {} +#endif + simdjson_inline explicit operator simd8() const { return vreinterpretq_u8_s8(this->value); } + + // Math + simdjson_inline simd8 operator+(const simd8 other) const { return vaddq_s8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return vsubq_s8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *this; } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *this; } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return vmaxq_s8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return vminq_s8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return vcgtq_s8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return vcltq_s8(*this, other); } + simdjson_inline simd8 operator==(const simd8 other) const { return vceqq_s8(*this, other); } + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return vextq_s8(prev_chunk, *this, 16 - N); + } + + // Perform a lookup assuming no value is larger than 16 + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return lookup_table.apply_lookup_16_to(*this); + } + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + + template + simdjson_inline simd8 apply_lookup_16_to(const simd8 original) { + return vqtbl1q_s8(*this, simd8(original)); + } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "ARM kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + uint64_t popcounts = vget_lane_u64(vreinterpret_u64_u8(vcnt_u8(vcreate_u8(~mask))), 0); + // compute the prefix sum of the popcounts of each byte + uint64_t offsets = popcounts * 0x0101010101010101; + this->chunks[0].compress_halves(uint16_t(mask), output, &output[popcounts & 0xFF]); + this->chunks[1].compress_halves(uint16_t(mask >> 16), &output[(offsets >> 8) & 0xFF], &output[(offsets >> 16) & 0xFF]); + this->chunks[2].compress_halves(uint16_t(mask >> 32), &output[(offsets >> 24) & 0xFF], &output[(offsets >> 32) & 0xFF]); + this->chunks[3].compress_halves(uint16_t(mask >> 48), &output[(offsets >> 40) & 0xFF], &output[(offsets >> 48) & 0xFF]); + return offsets >> 56; + } + + simdjson_inline uint64_t to_bitmask() const { +#ifdef SIMDJSON_REGULAR_VISUAL_STUDIO + const uint8x16_t bit_mask = simdjson_make_uint8x16_t( + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 + ); +#else + const uint8x16_t bit_mask = { + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80, + 0x01, 0x02, 0x4, 0x8, 0x10, 0x20, 0x40, 0x80 + }; +#endif + // Add each of the elements next to each other, successively, to stuff each 8 byte mask into one. + uint8x16_t sum0 = vpaddq_u8(this->chunks[0] & bit_mask, this->chunks[1] & bit_mask); + uint8x16_t sum1 = vpaddq_u8(this->chunks[2] & bit_mask, this->chunks[3] & bit_mask); + sum0 = vpaddq_u8(sum0, sum1); + sum0 = vpaddq_u8(sum0, sum0); + return vgetq_lane_u64(vreinterpretq_u64_u8(sum0), 0); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_SIMD_H +/* end file simdjson/arm64/simd.h */ +/* including simdjson/arm64/stringparsing_defs.h: #include "simdjson/arm64/stringparsing_defs.h" */ +/* begin file simdjson/arm64/stringparsing_defs.h */ +#ifndef SIMDJSON_ARM64_STRINGPARSING_DEFS_H +#define SIMDJSON_ARM64_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + sizeof(v0)); + v0.store(dst); + v1.store(dst + sizeof(v0)); + + // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on ARM; therefore, we + // smash them together into a 64-byte mask and get the bitmask from there. + uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_ARM64_STRINGPARSING_DEFS_H +/* end file simdjson/arm64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/arm64/begin.h */ +/* including simdjson/generic/ondemand/amalgamated.h for arm64: #include "simdjson/generic/ondemand/amalgamated.h" */ +/* begin file simdjson/generic/ondemand/amalgamated.h for arm64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H) +#error simdjson/generic/ondemand/dependencies.h must be included before simdjson/generic/ondemand/amalgamated.h! +#endif + +// Stuff other things depend on +/* including simdjson/generic/ondemand/base.h for arm64: #include "simdjson/generic/ondemand/base.h" */ +/* begin file simdjson/generic/ondemand/base.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { /** * A fast, simple, DOM-like interface that parses JSON as you use it. * @@ -22944,890 +26885,49 @@ namespace simdjson { /** Represents the depth of a JSON value (number of nested arrays/objects). */ using depth_t = int32_t; - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -/* begin file include/simdjson/generic/ondemand/json_type.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - /** - * The type of a JSON value. - */ - enum class json_type { - // Start at 1 to catch uninitialized / default values more easily - array = 1, ///< A JSON array ( [ 1, 2, 3 ... ] ) - object, ///< A JSON object ( { "a": 1, "b" 2, ... } ) - number, ///< A JSON number ( 1 or -2.3 or 4.5e6 ...) - string, ///< A JSON string ( "a" or "hello world\n" ...) - boolean, ///< A JSON boolean (true or false) - null ///< A JSON null (null) - }; - - class value_iterator; - - /** - * A type representing a JSON number. - * The design of the struct is deliberately straight-forward. All - * functions return standard values with no error check. - */ - struct number { - - /** - * return the automatically determined type of - * the number: number_type::floating_point_number, - * number_type::signed_integer or number_type::unsigned_integer. - * - * enum class number_type { - * floating_point_number=1, /// a binary64 number - * signed_integer, /// a signed integer that fits in a 64-bit word using two's complement - * unsigned_integer /// a positive integer larger or equal to 1<<63 - * }; - */ - simdjson_inline number_type get_number_type() const noexcept; - /** - * return true if the automatically determined type of - * the number is number_type::unsigned_integer. - */ - simdjson_inline bool is_uint64() const noexcept; - /** - * return the value as a uint64_t, only valid if is_uint64() is true. - */ - simdjson_inline uint64_t get_uint64() const noexcept; - simdjson_inline operator uint64_t() const noexcept; - - /** - * return true if the automatically determined type of - * the number is number_type::signed_integer. - */ - simdjson_inline bool is_int64() const noexcept; - /** - * return the value as a int64_t, only valid if is_int64() is true. - */ - simdjson_inline int64_t get_int64() const noexcept; - simdjson_inline operator int64_t() const noexcept; - - - /** - * return true if the automatically determined type of - * the number is number_type::floating_point_number. - */ - simdjson_inline bool is_double() const noexcept; - /** - * return the value as a double, only valid if is_double() is true. - */ - simdjson_inline double get_double() const noexcept; - simdjson_inline operator double() const noexcept; - - /** - * Convert the number to a double. Though it always succeed, the conversion - * may be lossy if the number cannot be represented exactly. - */ - simdjson_inline double as_double() const noexcept; - - - protected: - /** - * The next block of declaration is designed so that we can call the number parsing - * functions on a number type. They are protected and should never be used outside - * of the core simdjson library. - */ - friend class value_iterator; - template - friend error_code numberparsing::write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer); - template - friend error_code numberparsing::parse_number(const uint8_t* const src, W& writer); - template - friend error_code numberparsing::slow_float_parsing(simdjson_unused const uint8_t* src, W writer); - /** Store a signed 64-bit value to the number. */ - simdjson_inline void append_s64(int64_t value) noexcept; - /** Store an unsigned 64-bit value to the number. */ - simdjson_inline void append_u64(uint64_t value) noexcept; - /** Store a double value to the number. */ - simdjson_inline void append_double(double value) noexcept; - /** Specifies that the value is a double, but leave it undefined. */ - simdjson_inline void skip_double() noexcept; - /** - * End of friend declarations. - */ - - /** - * Our attributes are a union type (size = 64 bits) - * followed by a type indicator. - */ - union { - double floating_point_number; - int64_t signed_integer; - uint64_t unsigned_integer; - } payload{ 0 }; - number_type type{ number_type::signed_integer }; - }; - - /** - * Write the JSON type to the output stream - * - * @param out The output stream. - * @param type The json_type. - */ - inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept; - inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept; - -#if SIMDJSON_EXCEPTIONS - /** - * Send JSON type to an output stream. - * - * @param out The output stream. - * @param type The json_type. - * @throw simdjson_error if the result being printed has an error. If there is an error with the - * underlying output stream, that error will be propagated (simdjson_error will not be - * thrown). - */ - inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false); -#endif - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_type&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - simdjson_inline simdjson_result() noexcept = default; - simdjson_inline ~simdjson_result() noexcept = default; ///< @private - }; - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/json_type.h */ -/* begin file include/simdjson/generic/ondemand/token_position.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { + /** @copydoc simdjson::arm64::number_type */ + using number_type = simdjson::arm64::number_type; /** @private Position in the JSON buffer indexes */ using token_position = const uint32_t*; - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/token_position.h */ -/* begin file include/simdjson/generic/ondemand/logger.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - + class array; + class array_iterator; + class document; + class document_reference; + class document_stream; + class field; class json_iterator; + enum class json_type; + struct number; + class object; + class object_iterator; + class parser; + class raw_json_string; + class token_iterator; + class value; class value_iterator; - namespace logger { - -#if SIMDJSON_VERBOSE_LOGGING - static constexpr const bool LOG_ENABLED = true; -#else - static constexpr const bool LOG_ENABLED = false; -#endif - - // We do not want these functions to be 'really inlined' since real inlining is - // for performance purposes and if you are using the loggers, you do not care about - // performance (or should not). - static inline void log_headers() noexcept; - static inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail) noexcept; - static inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta) noexcept; - static inline void log_event(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; - static inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; - static inline void log_value(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; - static inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; - static inline void log_start_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; - static inline void log_end_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; - static inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail = "") noexcept; - static inline void log_error(const json_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; - - static inline void log_event(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; - static inline void log_value(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; - static inline void log_start_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; - static inline void log_end_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; - static inline void log_error(const value_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; - - } // namespace logger } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson -/* end file include/simdjson/generic/ondemand/logger.h */ -/* begin file include/simdjson/generic/ondemand/raw_json_string.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_BASE_H +/* end file simdjson/generic/ondemand/base.h for arm64 */ +/* including simdjson/generic/ondemand/value_iterator.h for arm64: #include "simdjson/generic/ondemand/value_iterator.h" */ +/* begin file simdjson/generic/ondemand/value_iterator.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { namespace ondemand { - class object; - class parser; - class json_iterator; - - /** - * A string escaped per JSON rules, terminated with quote ("). They are used to represent - * unescaped keys inside JSON documents. - * - * (In other words, a pointer to the beginning of a string, just after the start quote, inside a - * JSON file.) - * - * This class is deliberately simplistic and has little functionality. You can - * compare a raw_json_string instance with an unescaped C string, but - * that is nearly all you can do. - * - * The raw_json_string is unescaped. If you wish to write an unescaped version of it to your own - * buffer, you may do so using the parser.unescape(string, buff) method, using an ondemand::parser - * instance. Doing so requires you to have a sufficiently large buffer. - * - * The raw_json_string instances originate typically from field instance which in turn represent - * key-value pairs from object instances. From a field instance, you get the raw_json_string - * instance by calling key(). You can, if you want a more usable string_view instance, call - * the unescaped_key() method on the field instance. You may also create a raw_json_string from - * any other string value, with the value.get_raw_json_string() method. Again, you can get - * a more usable string_view instance by calling get_string(). - * - */ - class raw_json_string { - public: - /** - * Create a new invalid raw_json_string. - * - * Exists so you can declare a variable and later assign to it before use. - */ - simdjson_inline raw_json_string() noexcept = default; - - /** - * Create a new invalid raw_json_string pointed at the given location in the JSON. - * - * The given location must be just *after* the beginning quote (") in the JSON file. - * - * It *must* be terminated by a ", and be a valid JSON string. - */ - simdjson_inline raw_json_string(const uint8_t* _buf) noexcept; - /** - * Get the raw pointer to the beginning of the string in the JSON (just after the "). - * - * It is possible for this function to return a null pointer if the instance - * has outlived its existence. - */ - simdjson_inline const char* raw() const noexcept; - - /** - * This compares the current instance to the std::string_view target: returns true if - * they are byte-by-byte equal (no escaping is done) on target.size() characters, - * and if the raw_json_string instance has a quote character at byte index target.size(). - * We never read more than length + 1 bytes in the raw_json_string instance. - * If length is smaller than target.size(), this will return false. - * - * The std::string_view instance may contain any characters. However, the caller - * is responsible for setting length so that length bytes may be read in the - * raw_json_string. - * - * Performance: the comparison may be done using memcmp which may be efficient - * for long strings. - */ - simdjson_inline bool unsafe_is_equal(size_t length, std::string_view target) const noexcept; - - /** - * This compares the current instance to the std::string_view target: returns true if - * they are byte-by-byte equal (no escaping is done). - * The std::string_view instance should not contain unescaped quote characters: - * the caller is responsible for this check. See is_free_from_unescaped_quote. - * - * Performance: the comparison is done byte-by-byte which might be inefficient for - * long strings. - * - * If target is a compile-time constant, and your compiler likes you, - * you should be able to do the following without performance penalty... - * - * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); - * s.unsafe_is_equal(target); - */ - simdjson_inline bool unsafe_is_equal(std::string_view target) const noexcept; - - /** - * This compares the current instance to the C string target: returns true if - * they are byte-by-byte equal (no escaping is done). - * The provided C string should not contain an unescaped quote character: - * the caller is responsible for this check. See is_free_from_unescaped_quote. - * - * If target is a compile-time constant, and your compiler likes you, - * you should be able to do the following without performance penalty... - * - * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); - * s.unsafe_is_equal(target); - */ - simdjson_inline bool unsafe_is_equal(const char* target) const noexcept; - - /** - * This compares the current instance to the std::string_view target: returns true if - * they are byte-by-byte equal (no escaping is done). - */ - simdjson_inline bool is_equal(std::string_view target) const noexcept; - - /** - * This compares the current instance to the C string target: returns true if - * they are byte-by-byte equal (no escaping is done). - */ - simdjson_inline bool is_equal(const char* target) const noexcept; - - /** - * Returns true if target is free from unescaped quote. If target is known at - * compile-time, we might expect the computation to happen at compile time with - * many compilers (not all!). - */ - static simdjson_inline bool is_free_from_unescaped_quote(std::string_view target) noexcept; - static simdjson_inline bool is_free_from_unescaped_quote(const char* target) noexcept; - - private: - - - /** - * This will set the inner pointer to zero, effectively making - * this instance unusable. - */ - simdjson_inline void consume() noexcept { buf = nullptr; } - - /** - * Checks whether the inner pointer is non-null and thus usable. - */ - simdjson_inline simdjson_warn_unused bool alive() const noexcept { return buf != nullptr; } - - /** - * Unescape this JSON string, replacing \\ with \, \n with newline, etc. - * The result will be a valid UTF-8. - * - * ## IMPORTANT: string_view lifetime - * - * The string_view is only valid until the next parse() call on the parser. - * - * @param iter A json_iterator, which contains a buffer where the string will be written. - * @param allow_replacement Whether we allow replacement of invalid surrogate pairs. - */ - simdjson_inline simdjson_warn_unused simdjson_result unescape(json_iterator& iter, bool allow_replacement) const noexcept; - - /** - * Unescape this JSON string, replacing \\ with \, \n with newline, etc. - * The result may not be a valid UTF-8. https://simonsapin.github.io/wtf-8/ - * - * ## IMPORTANT: string_view lifetime - * - * The string_view is only valid until the next parse() call on the parser. - * - * @param iter A json_iterator, which contains a buffer where the string will be written. - */ - simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(json_iterator& iter) const noexcept; - const uint8_t* buf{}; - friend class object; - friend class field; - friend class parser; - friend struct simdjson_result; - }; - - simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream&, const raw_json_string&) noexcept; - - /** - * Comparisons between raw_json_string and std::string_view instances are potentially unsafe: the user is responsible - * for providing a string with no unescaped quote. Note that unescaped quotes cannot be present in valid JSON strings. - */ - simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept; - simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept; - simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept; - simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept; - - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - simdjson_inline simdjson_result() noexcept = default; - simdjson_inline ~simdjson_result() noexcept = default; ///< @private - - simdjson_inline simdjson_result raw() const noexcept; - simdjson_inline simdjson_warn_unused simdjson_result unescape(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_iterator& iter, bool allow_replacement) const noexcept; - simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_iterator& iter) const noexcept; - }; - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/raw_json_string.h */ -/* begin file include/simdjson/generic/ondemand/token_iterator.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - /** - * Iterates through JSON tokens (`{` `}` `[` `]` `,` `:` `""` `123` `true` `false` `null`) - * detected by stage 1. - * - * @private This is not intended for external use. - */ - class token_iterator { - public: - /** - * Create a new invalid token_iterator. - * - * Exists so you can declare a variable and later assign to it before use. - */ - simdjson_inline token_iterator() noexcept = default; - simdjson_inline token_iterator(token_iterator&& other) noexcept = default; - simdjson_inline token_iterator& operator=(token_iterator&& other) noexcept = default; - simdjson_inline token_iterator(const token_iterator& other) noexcept = default; - simdjson_inline token_iterator& operator=(const token_iterator& other) noexcept = default; - - /** - * Advance to the next token (returning the current one). - */ - simdjson_inline const uint8_t* return_current_and_advance() noexcept; - /** - * Reports the current offset in bytes from the start of the underlying buffer. - */ - simdjson_inline uint32_t current_offset() const noexcept; - /** - * Get the JSON text for a given token (relative). - * - * This is not null-terminated; it is a view into the JSON. - * - * @param delta The relative position of the token to retrieve. e.g. 0 = current token, - * 1 = next token, -1 = prev token. - * - * TODO consider a string_view, assuming the length will get stripped out by the optimizer when - * it isn't used ... - */ - simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; - /** - * Get the maximum length of the JSON text for a given token. - * - * The length will include any whitespace at the end of the token. - * - * @param delta The relative position of the token to retrieve. e.g. 0 = current token, - * 1 = next token, -1 = prev token. - */ - simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; - - /** - * Get the JSON text for a given token. - * - * This is not null-terminated; it is a view into the JSON. - * - * @param position The position of the token. - * - */ - simdjson_inline const uint8_t* peek(token_position position) const noexcept; - /** - * Get the maximum length of the JSON text for a given token. - * - * The length will include any whitespace at the end of the token. - * - * @param position The position of the token. - */ - simdjson_inline uint32_t peek_length(token_position position) const noexcept; - - /** - * Return the current index. - */ - simdjson_inline token_position position() const noexcept; - /** - * Reset to a previously saved index. - */ - simdjson_inline void set_position(token_position target_position) noexcept; - - // NOTE: we don't support a full C++ iterator interface, because we expect people to make - // different calls to advance the iterator based on *their own* state. - - simdjson_inline bool operator==(const token_iterator& other) const noexcept; - simdjson_inline bool operator!=(const token_iterator& other) const noexcept; - simdjson_inline bool operator>(const token_iterator& other) const noexcept; - simdjson_inline bool operator>=(const token_iterator& other) const noexcept; - simdjson_inline bool operator<(const token_iterator& other) const noexcept; - simdjson_inline bool operator<=(const token_iterator& other) const noexcept; - - protected: - simdjson_inline token_iterator(const uint8_t* buf, token_position position) noexcept; - - /** - * Get the index of the JSON text for a given token (relative). - * - * This is not null-terminated; it is a view into the JSON. - * - * @param delta The relative position of the token to retrieve. e.g. 0 = current token, - * 1 = next token, -1 = prev token. - */ - simdjson_inline uint32_t peek_index(int32_t delta = 0) const noexcept; - /** - * Get the index of the JSON text for a given token. - * - * This is not null-terminated; it is a view into the JSON. - * - * @param position The position of the token. - * - */ - simdjson_inline uint32_t peek_index(token_position position) const noexcept; - - const uint8_t* buf{}; - token_position _position{}; - - friend class json_iterator; - friend class value_iterator; - friend class object; - friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta) noexcept; - friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail) noexcept; - }; - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::token_iterator&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - simdjson_inline simdjson_result() noexcept = default; - simdjson_inline ~simdjson_result() noexcept = default; ///< @private - }; - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/token_iterator.h */ -/* begin file include/simdjson/generic/ondemand/json_iterator.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - class document; - class document_stream; - class object; - class array; - class value; - class raw_json_string; - class parser; - - /** - * Iterates through JSON tokens, keeping track of depth and string buffer. - * - * @private This is not intended for external use. - */ - class json_iterator { - protected: - token_iterator token{}; - ondemand::parser* parser{}; - /** - * Next free location in the string buffer. - * - * Used by raw_json_string::unescape() to have a place to unescape strings to. - */ - uint8_t* _string_buf_loc{}; - /** - * JSON error, if there is one. - * - * INCORRECT_TYPE and NO_SUCH_FIELD are *not* stored here, ever. - * - * PERF NOTE: we *hope* this will be elided into control flow, as it is only used (a) in the first - * iteration of the loop, or (b) for the final iteration after a missing comma is found in ++. If - * this is not elided, we should make sure it's at least not using up a register. Failing that, - * we should store it in document so there's only one of them. - */ - error_code error{ SUCCESS }; - /** - * Depth of the current token in the JSON. - * - * - 0 = finished with document - * - 1 = document root value (could be [ or {, not yet known) - * - 2 = , or } inside root array/object - * - 3 = key or value inside root array/object. - */ - depth_t _depth{}; - /** - * Beginning of the document indexes. - * Normally we have root == parser->implementation->structural_indexes.get() - * but this may differ, especially in streaming mode (where we have several - * documents); - */ - token_position _root{}; - /** - * Normally, a json_iterator operates over a single document, but in - * some cases, we may have a stream of documents. This attribute is meant - * as meta-data: the json_iterator works the same irrespective of the - * value of this attribute. - */ - bool _streaming{ false }; - - public: - simdjson_inline json_iterator() noexcept = default; - simdjson_inline json_iterator(json_iterator&& other) noexcept; - simdjson_inline json_iterator& operator=(json_iterator&& other) noexcept; - simdjson_inline explicit json_iterator(const json_iterator& other) noexcept = default; - simdjson_inline json_iterator& operator=(const json_iterator& other) noexcept = default; - /** - * Skips a JSON value, whether it is a scalar, array or object. - */ - simdjson_warn_unused simdjson_inline error_code skip_child(depth_t parent_depth) noexcept; - - /** - * Tell whether the iterator is still at the start - */ - simdjson_inline bool at_root() const noexcept; - - /** - * Tell whether we should be expected to run in streaming - * mode (iterating over many documents). It is pure metadata - * that does not affect how the iterator works. It is used by - * start_root_array() and start_root_object(). - */ - simdjson_inline bool streaming() const noexcept; - - /** - * Get the root value iterator - */ - simdjson_inline token_position root_position() const noexcept; - /** - * Assert that we are at the document depth (== 1) - */ - simdjson_inline void assert_at_document_depth() const noexcept; - /** - * Assert that we are at the root of the document - */ - simdjson_inline void assert_at_root() const noexcept; - - /** - * Tell whether the iterator is at the EOF mark - */ - simdjson_inline bool at_end() const noexcept; - - /** - * Tell whether the iterator is live (has not been moved). - */ - simdjson_inline bool is_alive() const noexcept; - - /** - * Abandon this iterator, setting depth to 0 (as if the document is finished). - */ - simdjson_inline void abandon() noexcept; - - /** - * Advance the current token without modifying depth. - */ - simdjson_inline const uint8_t* return_current_and_advance() noexcept; - - /** - * Returns true if there is a single token in the index (i.e., it is - * a JSON with a scalar value such as a single number). - * - * @return whether there is a single token - */ - simdjson_inline bool is_single_token() const noexcept; - - /** - * Assert that there are at least the given number of tokens left. - * - * Has no effect in release builds. - */ - simdjson_inline void assert_more_tokens(uint32_t required_tokens = 1) const noexcept; - /** - * Assert that the given position addresses an actual token (is within bounds). - * - * Has no effect in release builds. - */ - simdjson_inline void assert_valid_position(token_position position) const noexcept; - /** - * Get the JSON text for a given token (relative). - * - * This is not null-terminated; it is a view into the JSON. - * - * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. - * - * TODO consider a string_view, assuming the length will get stripped out by the optimizer when - * it isn't used ... - */ - simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; - /** - * Get the maximum length of the JSON text for the current token (or relative). - * - * The length will include any whitespace at the end of the token. - * - * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. - */ - simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; - /** - * Get a pointer to the current location in the input buffer. - * - * This is not null-terminated; it is a view into the JSON. - * - * You may be pointing outside of the input buffer: it is not generally - * safe to dereference this pointer. - */ - simdjson_inline const uint8_t* unsafe_pointer() const noexcept; - /** - * Get the JSON text for a given token. - * - * This is not null-terminated; it is a view into the JSON. - * - * @param position The position of the token to retrieve. - * - * TODO consider a string_view, assuming the length will get stripped out by the optimizer when - * it isn't used ... - */ - simdjson_inline const uint8_t* peek(token_position position) const noexcept; - /** - * Get the maximum length of the JSON text for the current token (or relative). - * - * The length will include any whitespace at the end of the token. - * - * @param position The position of the token to retrieve. - */ - simdjson_inline uint32_t peek_length(token_position position) const noexcept; - /** - * Get the JSON text for the last token in the document. - * - * This is not null-terminated; it is a view into the JSON. - * - * TODO consider a string_view, assuming the length will get stripped out by the optimizer when - * it isn't used ... - */ - simdjson_inline const uint8_t* peek_last() const noexcept; - - /** - * Ascend one level. - * - * Validates that the depth - 1 == parent_depth. - * - * @param parent_depth the expected parent depth. - */ - simdjson_inline void ascend_to(depth_t parent_depth) noexcept; - - /** - * Descend one level. - * - * Validates that the new depth == child_depth. - * - * @param child_depth the expected child depth. - */ - simdjson_inline void descend_to(depth_t child_depth) noexcept; - simdjson_inline void descend_to(depth_t child_depth, int32_t delta) noexcept; - - /** - * Get current depth. - */ - simdjson_inline depth_t depth() const noexcept; - - /** - * Get current (writeable) location in the string buffer. - */ - simdjson_inline uint8_t*& string_buf_loc() noexcept; - - /** - * Report an unrecoverable error, preventing further iteration. - * - * @param error The error to report. Must not be SUCCESS, UNINITIALIZED, INCORRECT_TYPE, or NO_SUCH_FIELD. - * @param message An error message to report with the error. - */ - simdjson_inline error_code report_error(error_code error, const char* message) noexcept; - - /** - * Log error, but don't stop iteration. - * @param error The error to report. Must be INCORRECT_TYPE, or NO_SUCH_FIELD. - * @param message An error message to report with the error. - */ - simdjson_inline error_code optional_error(error_code error, const char* message) noexcept; - - template simdjson_warn_unused simdjson_inline bool copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t(&tmpbuf)[N]) noexcept; - - simdjson_inline token_position position() const noexcept; - /** - * Write the raw_json_string to the string buffer and return a string_view. - * Each raw_json_string should be unescaped once, or else the string buffer might - * overflow. - */ - simdjson_inline simdjson_result unescape(raw_json_string in, bool allow_replacement) noexcept; - simdjson_inline simdjson_result unescape_wobbly(raw_json_string in) noexcept; - simdjson_inline void reenter_child(token_position position, depth_t child_depth) noexcept; - -#if SIMDJSON_DEVELOPMENT_CHECKS - simdjson_inline token_position start_position(depth_t depth) const noexcept; - simdjson_inline void set_start_position(depth_t depth, token_position position) noexcept; -#endif - - /* Useful for debugging and logging purposes. */ - inline std::string to_string() const noexcept; - - /** - * Returns the current location in the document if in bounds. - */ - inline simdjson_result current_location() noexcept; - - /** - * Updates this json iterator so that it is back at the beginning of the document, - * as if it had just been created. - */ - inline void rewind() noexcept; - /** - * This checks whether the {,},[,] are balanced so that the document - * ends with proper zero depth. This requires scanning the whole document - * and it may be expensive. It is expected that it will be rarely called. - * It does not attempt to match { with } and [ with ]. - */ - inline bool balanced() const noexcept; - protected: - simdjson_inline json_iterator(const uint8_t* buf, ondemand::parser* parser) noexcept; - /// The last token before the end - simdjson_inline token_position last_position() const noexcept; - /// The token *at* the end. This points at gibberish and should only be used for comparison. - simdjson_inline token_position end_position() const noexcept; - /// The end of the buffer. - simdjson_inline token_position end() const noexcept; - - friend class document; - friend class document_stream; - friend class object; - friend class array; - friend class value; - friend class raw_json_string; - friend class parser; - friend class value_iterator; - friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta) noexcept; - friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail) noexcept; - }; // json_iterator - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_iterator&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - - simdjson_inline simdjson_result() noexcept = default; - }; - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/json_iterator.h */ -/* begin file include/simdjson/generic/ondemand/value_iterator.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - class document; - class object; - class array; - class value; - class raw_json_string; - class parser; - /** * Iterates through a single JSON value at a particular depth. * @@ -23928,7 +27028,14 @@ namespace simdjson { * @error TAPE_ERROR if there is no matching } at end of document */ simdjson_warn_unused simdjson_inline simdjson_result start_root_object() noexcept; - + /** + * Checks whether an object could be started from the root. May be called by start_root_object. + * + * @returns SUCCESS if it is possible to safely start an object from the root (document level). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_object() noexcept; /** * Start an object iteration after the user has already checked and moved past the {. * @@ -24053,7 +27160,14 @@ namespace simdjson { * @error TAPE_ERROR if there is no matching ] at end of document */ simdjson_warn_unused simdjson_inline simdjson_result start_root_array() noexcept; - + /** + * Checks whether an array could be started from the root. May be called by start_root_array. + * + * @returns SUCCESS if it is possible to safely start an array from the root (document level). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_array() noexcept; /** * Start an array iteration, after the user has already checked and moved past the [. * @@ -24100,6 +27214,8 @@ namespace simdjson { */ simdjson_warn_unused simdjson_inline simdjson_result get_string(bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement) noexcept; simdjson_warn_unused simdjson_inline simdjson_result get_wobbly_string() noexcept; simdjson_warn_unused simdjson_inline simdjson_result get_raw_json_string() noexcept; simdjson_warn_unused simdjson_inline simdjson_result get_uint64() noexcept; @@ -24116,6 +27232,8 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; simdjson_warn_unused simdjson_inline simdjson_result get_root_string(bool check_trailing, bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept; simdjson_warn_unused simdjson_inline simdjson_result get_root_wobbly_string(bool check_trailing) noexcept; simdjson_warn_unused simdjson_inline simdjson_result get_root_raw_json_string(bool check_trailing) noexcept; simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64(bool check_trailing) noexcept; @@ -24272,1190 +27390,38 @@ namespace simdjson { }; // value_iterator } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { + struct simdjson_result : public arm64::implementation_simdjson_result_base { public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(arm64::ondemand::value_iterator&& value) noexcept; ///< @private simdjson_inline simdjson_result(error_code error) noexcept; ///< @private simdjson_inline simdjson_result() noexcept = default; }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/value_iterator.h */ -/* begin file include/simdjson/generic/ondemand/array_iterator.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H +/* end file simdjson/generic/ondemand/value_iterator.h for arm64 */ +/* including simdjson/generic/ondemand/value.h for arm64: #include "simdjson/generic/ondemand/value.h" */ +/* begin file simdjson/generic/ondemand/value.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { namespace ondemand { - class array; - class value; - class document; - - /** - * A forward-only JSON array. - * - * This is an input_iterator, meaning: - * - It is forward-only - * - * must be called exactly once per element. - * - ++ must be called exactly once in between each * (*, ++, *, ++, * ...) - */ - class array_iterator { - public: - /** Create a new, invalid array iterator. */ - simdjson_inline array_iterator() noexcept = default; - - // - // Iterator interface - // - - /** - * Get the current element. - * - * Part of the std::iterator interface. - */ - simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. - /** - * Check if we are at the end of the JSON. - * - * Part of the std::iterator interface. - * - * @return true if there are no more elements in the JSON array. - */ - simdjson_inline bool operator==(const array_iterator&) const noexcept; - /** - * Check if there are more elements in the JSON array. - * - * Part of the std::iterator interface. - * - * @return true if there are more elements in the JSON array. - */ - simdjson_inline bool operator!=(const array_iterator&) const noexcept; - /** - * Move to the next element. - * - * Part of the std::iterator interface. - */ - simdjson_inline array_iterator& operator++() noexcept; - - private: - value_iterator iter{}; - - simdjson_inline array_iterator(const value_iterator& iter) noexcept; - - friend class array; - friend class value; - friend struct simdjson_result; - }; - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array_iterator&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - simdjson_inline simdjson_result() noexcept = default; - - // - // Iterator interface - // - - simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. - simdjson_inline bool operator==(const simdjson_result&) const noexcept; - simdjson_inline bool operator!=(const simdjson_result&) const noexcept; - simdjson_inline simdjson_result& operator++() noexcept; - }; - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/array_iterator.h */ -/* begin file include/simdjson/generic/ondemand/object_iterator.h */ - -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - class field; - - class object_iterator { - public: - /** - * Create a new invalid object_iterator. - * - * Exists so you can declare a variable and later assign to it before use. - */ - simdjson_inline object_iterator() noexcept = default; - - // - // Iterator interface - // - - // Reads key and value, yielding them to the user. - // MUST ONLY BE CALLED ONCE PER ITERATION. - simdjson_inline simdjson_result operator*() noexcept; - // Assumes it's being compared with the end. true if depth < iter->depth. - simdjson_inline bool operator==(const object_iterator&) const noexcept; - // Assumes it's being compared with the end. true if depth >= iter->depth. - simdjson_inline bool operator!=(const object_iterator&) const noexcept; - // Checks for ']' and ',' - simdjson_inline object_iterator& operator++() noexcept; - - private: - /** - * The underlying JSON iterator. - * - * PERF NOTE: expected to be elided in favor of the parent document: this is set when the object - * is first used, and never changes afterwards. - */ - value_iterator iter{}; - - simdjson_inline object_iterator(const value_iterator& iter) noexcept; - friend struct simdjson_result; - friend class object; - }; - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object_iterator&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - simdjson_inline simdjson_result() noexcept = default; - - // - // Iterator interface - // - - // Reads key and value, yielding them to the user. - simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. - // Assumes it's being compared with the end. true if depth < iter->depth. - simdjson_inline bool operator==(const simdjson_result&) const noexcept; - // Assumes it's being compared with the end. true if depth >= iter->depth. - simdjson_inline bool operator!=(const simdjson_result&) const noexcept; - // Checks for ']' and ',' - simdjson_inline simdjson_result& operator++() noexcept; - }; - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/object_iterator.h */ -/* begin file include/simdjson/generic/ondemand/array.h */ - -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - class value; - class document; - - /** - * A forward-only JSON array. - */ - class array { - public: - /** - * Create a new invalid array. - * - * Exists so you can declare a variable and later assign to it before use. - */ - simdjson_inline array() noexcept = default; - - /** - * Begin array iteration. - * - * Part of the std::iterable interface. - */ - simdjson_inline simdjson_result begin() noexcept; - /** - * Sentinel representing the end of the array. - * - * Part of the std::iterable interface. - */ - simdjson_inline simdjson_result end() noexcept; - /** - * This method scans the array and counts the number of elements. - * The count_elements method should always be called before you have begun - * iterating through the array: it is expected that you are pointing at - * the beginning of the array. - * The runtime complexity is linear in the size of the array. After - * calling this function, if successful, the array is 'rewinded' at its - * beginning as if it had never been accessed. If the JSON is malformed (e.g., - * there is a missing comma), then an error is returned and it is no longer - * safe to continue. - * - * To check that an array is empty, it is more performant to use - * the is_empty() method. - */ - simdjson_inline simdjson_result count_elements() & noexcept; - /** - * This method scans the beginning of the array and checks whether the - * array is empty. - * The runtime complexity is constant time. After - * calling this function, if successful, the array is 'rewinded' at its - * beginning as if it had never been accessed. If the JSON is malformed (e.g., - * there is a missing comma), then an error is returned and it is no longer - * safe to continue. - */ - simdjson_inline simdjson_result is_empty() & noexcept; - /** - * Reset the iterator so that we are pointing back at the - * beginning of the array. You should still consume values only once even if you - * can iterate through the array more than once. If you unescape a string - * within the array more than once, you have unsafe code. Note that rewinding - * an array means that you may need to reparse it anew: it is not a free - * operation. - * - * @returns true if the array contains some elements (not empty) - */ - inline simdjson_result reset() & noexcept; - /** - * Get the value associated with the given JSON pointer. We use the RFC 6901 - * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node - * as the root of its own JSON document. - * - * ondemand::parser parser; - * auto json = R"([ { "foo": { "a": [ 10, 20, 30 ] }} ])"_padded; - * auto doc = parser.iterate(json); - * doc.at_pointer("/0/foo/a/1") == 20 - * - * Note that at_pointer() called on the document automatically calls the document's rewind - * method between each call. It invalidates all previously accessed arrays, objects and values - * that have not been consumed. Yet it is not the case when calling at_pointer on an array - * instance: there is no rewind and no invalidation. - * - * You may only call at_pointer on an array after it has been created, but before it has - * been first accessed. When calling at_pointer on an array, the pointer is advanced to - * the location indicated by the JSON pointer (in case of success). It is no longer possible - * to call at_pointer on the same array. - * - * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. - * - * @return The value associated with the given JSON pointer, or: - * - NO_SUCH_FIELD if a field does not exist in an object - * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length - * - INCORRECT_TYPE if a non-integer is used to access an array - * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed - */ - inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - /** - * Consumes the array and returns a string_view instance corresponding to the - * array as represented in JSON. It points inside the original document. - */ - simdjson_inline simdjson_result raw_json() noexcept; - - /** - * Get the value at the given index. This function has linear-time complexity. - * This function should only be called once on an array instance since the array iterator is not reset between each call. - * - * @return The value at the given index, or: - * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length - */ - simdjson_inline simdjson_result at(size_t index) noexcept; - protected: - /** - * Go to the end of the array, no matter where you are right now. - */ - simdjson_inline error_code consume() noexcept; - - /** - * Begin array iteration. - * - * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the - * resulting array. - * @error INCORRECT_TYPE if the iterator is not at [. - */ - static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; - /** - * Begin array iteration from the root. - * - * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the - * resulting array. - * @error INCORRECT_TYPE if the iterator is not at [. - * @error TAPE_ERROR if there is no closing ] at the end of the document. - */ - static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; - /** - * Begin array iteration. - * - * This version of the method should be called after the initial [ has been verified, and is - * intended for use by switch statements that check the type of a value. - * - * @param iter The iterator. Must be after the initial [. Will be *moved* into the resulting array. - */ - static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; - - /** - * Create an array at the given Internal array creation. Call array::start() or array::started() instead of this. - * - * @param iter The iterator. Must either be at the start of the first element with iter.is_alive() - * == true, or past the [] with is_alive() == false if the array is empty. Will be *moved* - * into the resulting array. - */ - simdjson_inline array(const value_iterator& iter) noexcept; - - /** - * Iterator marking current position. - * - * iter.is_alive() == false indicates iteration is complete. - */ - value_iterator iter{}; - - friend class value; - friend class document; - friend struct simdjson_result; - friend struct simdjson_result; - friend class array_iterator; - }; - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - simdjson_inline simdjson_result() noexcept = default; - - simdjson_inline simdjson_result begin() noexcept; - simdjson_inline simdjson_result end() noexcept; - inline simdjson_result count_elements() & noexcept; - inline simdjson_result is_empty() & noexcept; - inline simdjson_result reset() & noexcept; - simdjson_inline simdjson_result at(size_t index) noexcept; - simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - }; - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/array.h */ -/* begin file include/simdjson/generic/ondemand/document.h */ - -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - class parser; - class array; - class object; - class value; - class raw_json_string; - class array_iterator; - class document_stream; - - /** - * A JSON document. It holds a json_iterator instance. - * - * Used by tokens to get text, and string buffer location. - * - * You must keep the document around during iteration. - */ - class document { - public: - /** - * Create a new invalid document. - * - * Exists so you can declare a variable and later assign to it before use. - */ - simdjson_inline document() noexcept = default; - simdjson_inline document(const document& other) noexcept = delete; // pass your documents by reference, not by copy - simdjson_inline document(document&& other) noexcept = default; - simdjson_inline document& operator=(const document& other) noexcept = delete; - simdjson_inline document& operator=(document&& other) noexcept = default; - - /** - * Cast this JSON value to an array. - * - * @returns An object that can be used to iterate the array. - * @returns INCORRECT_TYPE If the JSON value is not an array. - */ - simdjson_inline simdjson_result get_array() & noexcept; - /** - * Cast this JSON value to an object. - * - * @returns An object that can be used to look up or iterate fields. - * @returns INCORRECT_TYPE If the JSON value is not an object. - */ - simdjson_inline simdjson_result get_object() & noexcept; - /** - * Cast this JSON value to an unsigned integer. - * - * @returns A signed 64-bit integer. - * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. - */ - simdjson_inline simdjson_result get_uint64() noexcept; - /** - * Cast this JSON value (inside string) to an unsigned integer. - * - * @returns A signed 64-bit integer. - * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. - */ - simdjson_inline simdjson_result get_uint64_in_string() noexcept; - /** - * Cast this JSON value to a signed integer. - * - * @returns A signed 64-bit integer. - * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. - */ - simdjson_inline simdjson_result get_int64() noexcept; - /** - * Cast this JSON value (inside string) to a signed integer. - * - * @returns A signed 64-bit integer. - * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. - */ - simdjson_inline simdjson_result get_int64_in_string() noexcept; - /** - * Cast this JSON value to a double. - * - * @returns A double. - * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. - */ - simdjson_inline simdjson_result get_double() noexcept; - - /** - * Cast this JSON value (inside string) to a double. - * - * @returns A double. - * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. - */ - simdjson_inline simdjson_result get_double_in_string() noexcept; - /** - * Cast this JSON value to a string. - * - * The string is guaranteed to be valid UTF-8. - * - * Important: Calling get_string() twice on the same document is an error. - * - * @param Whether to allow a replacement character for unmatched surrogate pairs. - * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next - * time it parses a document or when it is destroyed. - * @returns INCORRECT_TYPE if the JSON value is not a string. - */ - simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; - /** - * Cast this JSON value to a string. - * - * The string is not guaranteed to be valid UTF-8. See https://simonsapin.github.io/wtf-8/ - * - * Important: Calling get_wobbly_string() twice on the same document is an error. - * - * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next - * time it parses a document or when it is destroyed. - * @returns INCORRECT_TYPE if the JSON value is not a string. - */ - simdjson_inline simdjson_result get_wobbly_string() noexcept; - /** - * Cast this JSON value to a raw_json_string. - * - * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). - * - * @returns A pointer to the raw JSON for the given string. - * @returns INCORRECT_TYPE if the JSON value is not a string. - */ - simdjson_inline simdjson_result get_raw_json_string() noexcept; - /** - * Cast this JSON value to a bool. - * - * @returns A bool value. - * @returns INCORRECT_TYPE if the JSON value is not true or false. - */ - simdjson_inline simdjson_result get_bool() noexcept; - /** - * Cast this JSON value to a value when the document is an object or an array. - * - * @returns A value if a JSON array or object cannot be found. - * @returns SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). - */ - simdjson_inline simdjson_result get_value() noexcept; - - /** - * Checks if this JSON value is null. If and only if the value is - * null, then it is consumed (we advance). If we find a token that - * begins with 'n' but is not 'null', then an error is returned. - * - * @returns Whether the value is null. - * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. - */ - simdjson_inline simdjson_result is_null() noexcept; - - /** - * Get this value as the given type. - * - * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool - * - * You may use get_double(), get_bool(), get_uint64(), get_int64(), - * get_object(), get_array(), get_raw_json_string(), or get_string() instead. - * - * @returns A value of the given type, parsed from the JSON. - * @returns INCORRECT_TYPE If the JSON value is not the given type. - */ - template simdjson_inline simdjson_result get() & noexcept { - // Unless the simdjson library provides an inline implementation, calling this method should - // immediately fail. - static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library."); - } - /** @overload template simdjson_result get() & noexcept */ - template simdjson_inline simdjson_result get() && noexcept { - // Unless the simdjson library provides an inline implementation, calling this method should - // immediately fail. - static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library."); - } - - /** - * Get this value as the given type. - * - * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool, value - * - * Be mindful that the document instance must remain in scope while you are accessing object, array and value instances. - * - * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. - * @returns INCORRECT_TYPE If the JSON value is not an object. - * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. - */ - template simdjson_inline error_code get(T& out) & noexcept; - /** @overload template error_code get(T &out) & noexcept */ - template simdjson_inline error_code get(T& out) && noexcept; - -#if SIMDJSON_EXCEPTIONS - /** - * Cast this JSON value to an array. - * - * @returns An object that can be used to iterate the array. - * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. - */ - simdjson_inline operator array() & noexcept(false); - /** - * Cast this JSON value to an object. - * - * @returns An object that can be used to look up or iterate fields. - * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. - */ - simdjson_inline operator object() & noexcept(false); - /** - * Cast this JSON value to an unsigned integer. - * - * @returns A signed 64-bit integer. - * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. - */ - simdjson_inline operator uint64_t() noexcept(false); - /** - * Cast this JSON value to a signed integer. - * - * @returns A signed 64-bit integer. - * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. - */ - simdjson_inline operator int64_t() noexcept(false); - /** - * Cast this JSON value to a double. - * - * @returns A double. - * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. - */ - simdjson_inline operator double() noexcept(false); - /** - * Cast this JSON value to a string. - * - * The string is guaranteed to be valid UTF-8. - * - * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next - * time it parses a document or when it is destroyed. - * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. - */ - simdjson_inline operator std::string_view() noexcept(false); - /** - * Cast this JSON value to a raw_json_string. - * - * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). - * - * @returns A pointer to the raw JSON for the given string. - * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. - */ - simdjson_inline operator raw_json_string() noexcept(false); - /** - * Cast this JSON value to a bool. - * - * @returns A bool value. - * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. - */ - simdjson_inline operator bool() noexcept(false); - /** - * Cast this JSON value to a value. - * - * @returns A value value. - * @exception if a JSON value cannot be found - */ - simdjson_inline operator value() noexcept(false); -#endif - /** - * This method scans the array and counts the number of elements. - * The count_elements method should always be called before you have begun - * iterating through the array: it is expected that you are pointing at - * the beginning of the array. - * The runtime complexity is linear in the size of the array. After - * calling this function, if successful, the array is 'rewinded' at its - * beginning as if it had never been accessed. If the JSON is malformed (e.g., - * there is a missing comma), then an error is returned and it is no longer - * safe to continue. - */ - simdjson_inline simdjson_result count_elements() & noexcept; - /** - * This method scans the object and counts the number of key-value pairs. - * The count_fields method should always be called before you have begun - * iterating through the object: it is expected that you are pointing at - * the beginning of the object. - * The runtime complexity is linear in the size of the object. After - * calling this function, if successful, the object is 'rewinded' at its - * beginning as if it had never been accessed. If the JSON is malformed (e.g., - * there is a missing comma), then an error is returned and it is no longer - * safe to continue. - * - * To check that an object is empty, it is more performant to use - * the is_empty() method. - */ - simdjson_inline simdjson_result count_fields() & noexcept; - /** - * Get the value at the given index in the array. This function has linear-time complexity. - * This function should only be called once on an array instance since the array iterator is not reset between each call. - * - * @return The value at the given index, or: - * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length - */ - simdjson_inline simdjson_result at(size_t index) & noexcept; - /** - * Begin array iteration. - * - * Part of the std::iterable interface. - */ - simdjson_inline simdjson_result begin() & noexcept; - /** - * Sentinel representing the end of the array. - * - * Part of the std::iterable interface. - */ - simdjson_inline simdjson_result end() & noexcept; - - /** - * Look up a field by name on an object (order-sensitive). - * - * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the - * JSON `{ "x": 1, "y": 2, "z": 3 }`: - * - * ```c++ - * simdjson::ondemand::parser parser; - * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); - * double z = obj.find_field("z"); - * double y = obj.find_field("y"); - * double x = obj.find_field("x"); - * ``` - * - * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. - * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. - * - * - * You must consume the fields on an object one at a time. A request for a new key - * invalidates previous field values: it makes them unsafe. E.g., the array - * given by content["bids"].get_array() should not be accessed after you have called - * content["asks"].get_array(). You can detect such mistakes by first compiling and running - * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an - * OUT_OF_ORDER_ITERATION error is generated. - * - * You are expected to access keys only once. You should access the value corresponding to - * a key a single time. Doing object["mykey"].to_string()and then again object["mykey"].to_string() - * is an error. - * - * @param key The key to look up. - * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. - */ - simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; - /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result find_field(const char* key) & noexcept; - - /** - * Look up a field by name on an object, without regard to key order. - * - * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies - * and often appears negligible. It starts out normally, starting out at the last field; but if - * the field is not found, it scans from the beginning of the object to see if it missed it. That - * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object - * in question is large. The fact that the extra code is there also bumps the executable size. - * - * It is the default, however, because it would be highly surprising (and hard to debug) if the - * default behavior failed to look up a field just because it was in the wrong order--and many - * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. - * - * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the - * field wasn't there when they aren't). - * - * You must consume the fields on an object one at a time. A request for a new key - * invalidates previous field values: it makes them unsafe. E.g., the array - * given by content["bids"].get_array() should not be accessed after you have called - * content["asks"].get_array(). You can detect such mistakes by first compiling and running - * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an - * OUT_OF_ORDER_ITERATION error is generated. - * - * You are expected to access keys only once. You should access the value corresponding to a key - * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() - * is an error. - * - * @param key The key to look up. - * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. - */ - simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result operator[](const char* key) & noexcept; - - /** - * Get the type of this JSON value. It does not validate or consume the value. - * E.g., you must still call "is_null()" to check that a value is null even if - * "type()" returns json_type::null. - * - * NOTE: If you're only expecting a value to be one type (a typical case), it's generally - * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just - * let it throw an exception). - * - * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". - */ - simdjson_inline simdjson_result type() noexcept; - - /** - * Checks whether the document is a scalar (string, number, null, Boolean). - * Returns false when there it is an array or object. - * - * @returns true if the type is string, number, null, Boolean - * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". - */ - simdjson_inline simdjson_result is_scalar() noexcept; - - /** - * Checks whether the document is a negative number. - * - * @returns true if the number if negative. - */ - simdjson_inline bool is_negative() noexcept; - /** - * Checks whether the document is an integer number. Note that - * this requires to partially parse the number string. If - * the value is determined to be an integer, it may still - * not parse properly as an integer in subsequent steps - * (e.g., it might overflow). - * - * @returns true if the number if negative. - */ - simdjson_inline simdjson_result is_integer() noexcept; - /** - * Determine the number type (integer or floating-point number) as quickly - * as possible. This function does not fully validate the input. It is - * useful when you only need to classify the numbers, without parsing them. - * - * If you are planning to retrieve the value or you need full validation, - * consider using the get_number() method instead: it will fully parse - * and validate the input, and give you access to the type: - * get_number().get_number_type(). - * - * get_number_type() is number_type::unsigned_integer if we have - * an integer greater or equal to 9223372036854775808 - * get_number_type() is number_type::signed_integer if we have an - * integer that is less than 9223372036854775808 - * Otherwise, get_number_type() has value number_type::floating_point_number - * - * This function requires processing the number string, but it is expected - * to be faster than get_number().get_number_type() because it is does not - * parse the number value. - * - * @returns the type of the number - */ - simdjson_inline simdjson_result get_number_type() noexcept; - - /** - * Attempt to parse an ondemand::number. An ondemand::number may - * contain an integer value or a floating-point value, the simdjson - * library will autodetect the type. Thus it is a dynamically typed - * number. Before accessing the value, you must determine the detected - * type. - * - * number.get_number_type() is number_type::signed_integer if we have - * an integer in [-9223372036854775808,9223372036854775808) - * You can recover the value by calling number.get_int64() and you - * have that number.is_int64() is true. - * - * number.get_number_type() is number_type::unsigned_integer if we have - * an integer in [9223372036854775808,18446744073709551616) - * You can recover the value by calling number.get_uint64() and you - * have that number.is_uint64() is true. - * - * Otherwise, number.get_number_type() has value number_type::floating_point_number - * and we have a binary64 number. - * You can recover the value by calling number.get_double() and you - * have that number.is_double() is true. - * - * You must check the type before accessing the value: it is an error - * to call "get_int64()" when number.get_number_type() is not - * number_type::signed_integer and when number.is_int64() is false. - */ - simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; - - /** - * Get the raw JSON for this token. - * - * The string_view will always point into the input buffer. - * - * The string_view will start at the beginning of the token, and include the entire token - * *as well as all spaces until the next token (or EOF).* This means, for example, that a - * string token always begins with a " and is always terminated by the final ", possibly - * followed by a number of spaces. - * - * The string_view is *not* null-terminated. If this is a scalar (string, number, - * boolean, or null), the character after the end of the string_view may be the padded buffer. - * - * Tokens include: - * - { - * - [ - * - "a string (possibly with UTF-8 or backslashed characters like \\\")". - * - -1.2e-100 - * - true - * - false - * - null - */ - simdjson_inline simdjson_result raw_json_token() noexcept; - - /** - * Reset the iterator inside the document instance so we are pointing back at the - * beginning of the document, as if it had just been created. It invalidates all - * values, objects and arrays that you have created so far (including unescaped strings). - */ - inline void rewind() noexcept; - /** - * Returns debugging information. - */ - inline std::string to_debug_string() noexcept; - /** - * Some unrecoverable error conditions may render the document instance unusable. - * The is_alive() method returns true when the document is still suitable. - */ - inline bool is_alive() noexcept; - - /** - * Returns the current location in the document if in bounds. - */ - inline simdjson_result current_location() noexcept; - - /** - * Returns the current depth in the document if in bounds. - * - * E.g., - * 0 = finished with document - * 1 = document root value (could be [ or {, not yet known) - * 2 = , or } inside root array/object - * 3 = key or value inside root array/object. - */ - simdjson_inline int32_t current_depth() const noexcept; - - /** - * Get the value associated with the given JSON pointer. We use the RFC 6901 - * https://tools.ietf.org/html/rfc6901 standard. - * - * ondemand::parser parser; - * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; - * auto doc = parser.iterate(json); - * doc.at_pointer("/foo/a/1") == 20 - * - * It is allowed for a key to be the empty string: - * - * ondemand::parser parser; - * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; - * auto doc = parser.iterate(json); - * doc.at_pointer("//a/1") == 20 - * - * Note that at_pointer() automatically calls rewind between each call. Thus - * all values, objects and arrays that you have created so far (including unescaped strings) - * are invalidated. After calling at_pointer, you need to consume the result: string values - * should be stored in your own variables, arrays should be decoded and stored in your own array-like - * structures and so forth. - * - * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching - * - * @return The value associated with the given JSON pointer, or: - * - NO_SUCH_FIELD if a field does not exist in an object - * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length - * - INCORRECT_TYPE if a non-integer is used to access an array - * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed - * - SCALAR_DOCUMENT_AS_VALUE if the json_pointer is empty and the document is not a scalar (see is_scalar() function). - */ - simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - /** - * Consumes the document and returns a string_view instance corresponding to the - * document as represented in JSON. It points inside the original byte array containing - * the JSON document. - */ - simdjson_inline simdjson_result raw_json() noexcept; - protected: - /** - * Consumes the document. - */ - simdjson_inline error_code consume() noexcept; - - simdjson_inline document(ondemand::json_iterator&& iter) noexcept; - simdjson_inline const uint8_t* text(uint32_t idx) const noexcept; - - simdjson_inline value_iterator resume_value_iterator() noexcept; - simdjson_inline value_iterator get_root_value_iterator() noexcept; - simdjson_inline simdjson_result start_or_resume_object() noexcept; - static simdjson_inline document start(ondemand::json_iterator&& iter) noexcept; - - // - // Fields - // - json_iterator iter{}; ///< Current position in the document - static constexpr depth_t DOCUMENT_DEPTH = 0; ///< document depth is always 0 - - friend class array_iterator; - friend class value; - friend class ondemand::parser; - friend class object; - friend class array; - friend class field; - friend class token; - friend class document_stream; - friend class document_reference; - }; - - - /** - * A document_reference is a thin wrapper around a document reference instance. - */ - class document_reference { - public: - simdjson_inline document_reference() noexcept; - simdjson_inline document_reference(document& d) noexcept; - simdjson_inline document_reference(const document_reference& other) noexcept = default; - simdjson_inline document_reference& operator=(const document_reference& other) noexcept = default; - simdjson_inline void rewind() noexcept; - simdjson_inline simdjson_result get_array() & noexcept; - simdjson_inline simdjson_result get_object() & noexcept; - simdjson_inline simdjson_result get_uint64() noexcept; - simdjson_inline simdjson_result get_uint64_in_string() noexcept; - simdjson_inline simdjson_result get_int64() noexcept; - simdjson_inline simdjson_result get_int64_in_string() noexcept; - simdjson_inline simdjson_result get_double() noexcept; - simdjson_inline simdjson_result get_double_in_string() noexcept; - simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; - simdjson_inline simdjson_result get_wobbly_string() noexcept; - simdjson_inline simdjson_result get_raw_json_string() noexcept; - simdjson_inline simdjson_result get_bool() noexcept; - simdjson_inline simdjson_result get_value() noexcept; - - simdjson_inline simdjson_result is_null() noexcept; - simdjson_inline simdjson_result raw_json() noexcept; - simdjson_inline operator document& () const noexcept; - -#if SIMDJSON_EXCEPTIONS - simdjson_inline operator array() & noexcept(false); - simdjson_inline operator object() & noexcept(false); - simdjson_inline operator uint64_t() noexcept(false); - simdjson_inline operator int64_t() noexcept(false); - simdjson_inline operator double() noexcept(false); - simdjson_inline operator std::string_view() noexcept(false); - simdjson_inline operator raw_json_string() noexcept(false); - simdjson_inline operator bool() noexcept(false); - simdjson_inline operator value() noexcept(false); -#endif - simdjson_inline simdjson_result count_elements() & noexcept; - simdjson_inline simdjson_result count_fields() & noexcept; - simdjson_inline simdjson_result at(size_t index) & noexcept; - simdjson_inline simdjson_result begin() & noexcept; - simdjson_inline simdjson_result end() & noexcept; - simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field(const char* key) & noexcept; - simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; - simdjson_inline simdjson_result operator[](const char* key) & noexcept; - simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; - - simdjson_inline simdjson_result type() noexcept; - simdjson_inline simdjson_result is_scalar() noexcept; - - simdjson_inline simdjson_result current_location() noexcept; - simdjson_inline int32_t current_depth() const noexcept; - simdjson_inline bool is_negative() noexcept; - simdjson_inline simdjson_result is_integer() noexcept; - simdjson_inline simdjson_result get_number_type() noexcept; - simdjson_inline simdjson_result get_number() noexcept; - simdjson_inline simdjson_result raw_json_token() noexcept; - simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - private: - document* doc{ nullptr }; - }; - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document&& value) noexcept; ///< @private - simdjson_inline simdjson_result(error_code error) noexcept; ///< @private - simdjson_inline simdjson_result() noexcept = default; - simdjson_inline error_code rewind() noexcept; - - simdjson_inline simdjson_result get_array() & noexcept; - simdjson_inline simdjson_result get_object() & noexcept; - simdjson_inline simdjson_result get_uint64() noexcept; - simdjson_inline simdjson_result get_uint64_in_string() noexcept; - simdjson_inline simdjson_result get_int64() noexcept; - simdjson_inline simdjson_result get_int64_in_string() noexcept; - simdjson_inline simdjson_result get_double() noexcept; - simdjson_inline simdjson_result get_double_in_string() noexcept; - simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; - simdjson_inline simdjson_result get_wobbly_string() noexcept; - simdjson_inline simdjson_result get_raw_json_string() noexcept; - simdjson_inline simdjson_result get_bool() noexcept; - simdjson_inline simdjson_result get_value() noexcept; - simdjson_inline simdjson_result is_null() noexcept; - - template simdjson_inline simdjson_result get() & noexcept; - template simdjson_inline simdjson_result get() && noexcept; - - template simdjson_inline error_code get(T& out) & noexcept; - template simdjson_inline error_code get(T& out) && noexcept; - -#if SIMDJSON_EXCEPTIONS - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array() & noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object() & noexcept(false); - simdjson_inline operator uint64_t() noexcept(false); - simdjson_inline operator int64_t() noexcept(false); - simdjson_inline operator double() noexcept(false); - simdjson_inline operator std::string_view() noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string() noexcept(false); - simdjson_inline operator bool() noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value() noexcept(false); -#endif - simdjson_inline simdjson_result count_elements() & noexcept; - simdjson_inline simdjson_result count_fields() & noexcept; - simdjson_inline simdjson_result at(size_t index) & noexcept; - simdjson_inline simdjson_result begin() & noexcept; - simdjson_inline simdjson_result end() & noexcept; - simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field(const char* key) & noexcept; - simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; - simdjson_inline simdjson_result operator[](const char* key) & noexcept; - simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; - simdjson_inline simdjson_result type() noexcept; - simdjson_inline simdjson_result is_scalar() noexcept; - simdjson_inline simdjson_result current_location() noexcept; - simdjson_inline int32_t current_depth() const noexcept; - simdjson_inline bool is_negative() noexcept; - simdjson_inline simdjson_result is_integer() noexcept; - simdjson_inline simdjson_result get_number_type() noexcept; - simdjson_inline simdjson_result get_number() noexcept; - /** @copydoc simdjson_inline std::string_view document::raw_json_token() const noexcept */ - simdjson_inline simdjson_result raw_json_token() noexcept; - - simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - }; - - -} // namespace simdjson - - - -namespace simdjson { - - template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { - public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document_reference value, error_code error) noexcept; - simdjson_inline simdjson_result() noexcept = default; - simdjson_inline error_code rewind() noexcept; - - simdjson_inline simdjson_result get_array() & noexcept; - simdjson_inline simdjson_result get_object() & noexcept; - simdjson_inline simdjson_result get_uint64() noexcept; - simdjson_inline simdjson_result get_uint64_in_string() noexcept; - simdjson_inline simdjson_result get_int64() noexcept; - simdjson_inline simdjson_result get_int64_in_string() noexcept; - simdjson_inline simdjson_result get_double() noexcept; - simdjson_inline simdjson_result get_double_in_string() noexcept; - simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; - simdjson_inline simdjson_result get_wobbly_string() noexcept; - simdjson_inline simdjson_result get_raw_json_string() noexcept; - simdjson_inline simdjson_result get_bool() noexcept; - simdjson_inline simdjson_result get_value() noexcept; - simdjson_inline simdjson_result is_null() noexcept; - -#if SIMDJSON_EXCEPTIONS - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array() & noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object() & noexcept(false); - simdjson_inline operator uint64_t() noexcept(false); - simdjson_inline operator int64_t() noexcept(false); - simdjson_inline operator double() noexcept(false); - simdjson_inline operator std::string_view() noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string() noexcept(false); - simdjson_inline operator bool() noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value() noexcept(false); -#endif - simdjson_inline simdjson_result count_elements() & noexcept; - simdjson_inline simdjson_result count_fields() & noexcept; - simdjson_inline simdjson_result at(size_t index) & noexcept; - simdjson_inline simdjson_result begin() & noexcept; - simdjson_inline simdjson_result end() & noexcept; - simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field(const char* key) & noexcept; - simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; - simdjson_inline simdjson_result operator[](const char* key) & noexcept; - simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; - simdjson_inline simdjson_result type() noexcept; - simdjson_inline simdjson_result is_scalar() noexcept; - simdjson_inline simdjson_result current_location() noexcept; - simdjson_inline simdjson_result current_depth() const noexcept; - simdjson_inline simdjson_result is_negative() noexcept; - simdjson_inline simdjson_result is_integer() noexcept; - simdjson_inline simdjson_result get_number_type() noexcept; - simdjson_inline simdjson_result get_number() noexcept; - /** @copydoc simdjson_inline std::string_view document_reference::raw_json_token() const noexcept */ - simdjson_inline simdjson_result raw_json_token() noexcept; - - simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - }; - - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/document.h */ -/* begin file include/simdjson/generic/ondemand/value.h */ - -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - class array; - class document; - class field; - class object; - class raw_json_string; - /** * An ephemeral JSON value returned during iteration. It is only valid for as long as you do * not access more data in the JSON document. @@ -25483,7 +27449,10 @@ namespace simdjson { template simdjson_inline simdjson_result get() noexcept { // Unless the simdjson library provides an inline implementation, calling this method should // immediately fail. - static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library."); + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); } /** @@ -25577,6 +27546,21 @@ namespace simdjson { */ simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; /** * Cast this JSON value to a "wobbly" string. @@ -25920,9 +27904,21 @@ namespace simdjson { * - true * - false * - null + * + * See also value::raw_json(). */ simdjson_inline std::string_view raw_json_token() noexcept; + /** + * Get a string_view pointing at this value in the JSON document. + * If this element is an array or an object, it consumes the array or the object + * and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + * If this element is a scalar (string, number, Boolean, null), it returns what + * raw_json_token() would return. + */ + simdjson_inline simdjson_result raw_json() noexcept; + /** * Returns the current location in the document if in bounds. */ @@ -26025,20 +28021,20 @@ namespace simdjson { }; } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { + struct simdjson_result : public arm64::implementation_simdjson_result_base { public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value&& value) noexcept; ///< @private + simdjson_inline simdjson_result(arm64::ondemand::value&& value) noexcept; ///< @private simdjson_inline simdjson_result(error_code error) noexcept; ///< @private simdjson_inline simdjson_result() noexcept = default; - simdjson_inline simdjson_result get_array() noexcept; - simdjson_inline simdjson_result get_object() noexcept; + simdjson_inline simdjson_result get_array() noexcept; + simdjson_inline simdjson_result get_object() noexcept; simdjson_inline simdjson_result get_uint64() noexcept; simdjson_inline simdjson_result get_uint64_in_string() noexcept; @@ -26047,8 +28043,10 @@ namespace simdjson { simdjson_inline simdjson_result get_double() noexcept; simdjson_inline simdjson_result get_double_in_string() noexcept; simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; simdjson_inline simdjson_result get_wobbly_string() noexcept; - simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; simdjson_inline simdjson_result get_bool() noexcept; simdjson_inline simdjson_result is_null() noexcept; @@ -26057,20 +28055,20 @@ namespace simdjson { template simdjson_inline error_code get(T& out) noexcept; #if SIMDJSON_EXCEPTIONS - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array() noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object() noexcept(false); + simdjson_inline operator arm64::ondemand::array() noexcept(false); + simdjson_inline operator arm64::ondemand::object() noexcept(false); simdjson_inline operator uint64_t() noexcept(false); simdjson_inline operator int64_t() noexcept(false); simdjson_inline operator double() noexcept(false); simdjson_inline operator std::string_view() noexcept(false); - simdjson_inline operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator arm64::ondemand::raw_json_string() noexcept(false); simdjson_inline operator bool() noexcept(false); #endif simdjson_inline simdjson_result count_elements() & noexcept; simdjson_inline simdjson_result count_fields() & noexcept; - simdjson_inline simdjson_result at(size_t index) noexcept; - simdjson_inline simdjson_result begin() & noexcept; - simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; /** * Look up a field by name on an object (order-sensitive). @@ -26092,9 +28090,9 @@ namespace simdjson { * @param key The key to look up. * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. */ - simdjson_inline simdjson_result find_field(std::string_view key) noexcept; - /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ - simdjson_inline simdjson_result find_field(const char* key) noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; /** * Look up a field by name on an object, without regard to key order. @@ -26115,13 +28113,13 @@ namespace simdjson { * @param key The key to look up. * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. */ - simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ - simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ - simdjson_inline simdjson_result operator[](std::string_view key) noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ - simdjson_inline simdjson_result operator[](const char* key) noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; /** * Get the type of this JSON value. @@ -26130,339 +28128,961 @@ namespace simdjson { * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just * let it throw an exception). */ - simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result type() noexcept; simdjson_inline simdjson_result is_scalar() noexcept; simdjson_inline simdjson_result is_negative() noexcept; simdjson_inline simdjson_result is_integer() noexcept; - simdjson_inline simdjson_result get_number_type() noexcept; - simdjson_inline simdjson_result get_number() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; /** @copydoc simdjson_inline std::string_view value::raw_json_token() const noexcept */ simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; /** @copydoc simdjson_inline simdjson_result current_location() noexcept */ simdjson_inline simdjson_result current_location() noexcept; /** @copydoc simdjson_inline int32_t current_depth() const noexcept */ simdjson_inline simdjson_result current_depth() const noexcept; - simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/value.h */ -/* begin file include/simdjson/generic/ondemand/field.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_H +/* end file simdjson/generic/ondemand/value.h for arm64 */ +/* including simdjson/generic/ondemand/logger.h for arm64: #include "simdjson/generic/ondemand/logger.h" */ +/* begin file simdjson/generic/ondemand/logger.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { + namespace ondemand { + + // Logging should be free unless SIMDJSON_VERBOSE_LOGGING is set. Importantly, it is critical + // that the call to the log functions be side-effect free. Thus, for example, you should not + // create temporary std::string instances. + namespace logger { + + enum class log_level : int32_t { + info = 0, + error = 1 + }; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + + // We do not want these functions to be 'really inlined' since real inlining is + // for performance purposes and if you are using the loggers, you do not care about + // performance (or should not). + static inline void log_headers() noexcept; + // If args are provided, title will be treated as format string + template + static inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + template + static inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + static inline void log_event(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_value(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_start_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail = "") noexcept; + static inline void log_error(const json_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_event(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_error(const value_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + } // namespace logger + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_H +/* end file simdjson/generic/ondemand/logger.h for arm64 */ +/* including simdjson/generic/ondemand/token_iterator.h for arm64: #include "simdjson/generic/ondemand/token_iterator.h" */ +/* begin file simdjson/generic/ondemand/token_iterator.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { namespace ondemand { /** - * A JSON field (key/value pair) in an object. + * Iterates through JSON tokens (`{` `}` `[` `]` `,` `:` `""` `123` `true` `false` `null`) + * detected by stage 1. * - * Returned from object iteration. - * - * Extends from std::pair so you can use C++ algorithms that rely on pairs. + * @private This is not intended for external use. */ - class field : public std::pair { + class token_iterator { public: /** - * Create a new invalid field. + * Create a new invalid token_iterator. * * Exists so you can declare a variable and later assign to it before use. */ - simdjson_inline field() noexcept; + simdjson_inline token_iterator() noexcept = default; + simdjson_inline token_iterator(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator& operator=(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator(const token_iterator& other) noexcept = default; + simdjson_inline token_iterator& operator=(const token_iterator& other) noexcept = default; /** - * Get the key as a string_view (for higher speed, consider raw_key). - * We deliberately use a more cumbersome name (unescaped_key) to force users - * to think twice about using it. + * Advance to the next token (returning the current one). + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + /** + * Reports the current offset in bytes from the start of the underlying buffer. + */ + simdjson_inline uint32_t current_offset() const noexcept; + /** + * Get the JSON text for a given token (relative). * - * This consumes the key: once you have called unescaped_key(), you cannot - * call it again nor can you call key(). + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... */ - simdjson_inline simdjson_warn_unused simdjson_result unescaped_key(bool allow_replacement) noexcept; + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; /** - * Get the key as a raw_json_string. Can be used for direct comparison with - * an unescaped C string: e.g., key() == "test". + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. */ - simdjson_inline raw_json_string key() const noexcept; + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + /** - * Get the field value. + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * */ - simdjson_inline ondemand::value& value() & noexcept; + simdjson_inline const uint8_t* peek(token_position position) const noexcept; /** - * @overload ondemand::value &ondemand::value() & noexcept + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token. */ - simdjson_inline ondemand::value value() && noexcept; + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + + /** + * Return the current index. + */ + simdjson_inline token_position position() const noexcept; + /** + * Reset to a previously saved index. + */ + simdjson_inline void set_position(token_position target_position) noexcept; + + // NOTE: we don't support a full C++ iterator interface, because we expect people to make + // different calls to advance the iterator based on *their own* state. + + simdjson_inline bool operator==(const token_iterator& other) const noexcept; + simdjson_inline bool operator!=(const token_iterator& other) const noexcept; + simdjson_inline bool operator>(const token_iterator& other) const noexcept; + simdjson_inline bool operator>=(const token_iterator& other) const noexcept; + simdjson_inline bool operator<(const token_iterator& other) const noexcept; + simdjson_inline bool operator<=(const token_iterator& other) const noexcept; protected: - simdjson_inline field(raw_json_string key, ondemand::value&& value) noexcept; - static simdjson_inline simdjson_result start(value_iterator& parent_iter) noexcept; - static simdjson_inline simdjson_result start(const value_iterator& parent_iter, raw_json_string key) noexcept; - friend struct simdjson_result; - friend class object_iterator; + simdjson_inline token_iterator(const uint8_t* buf, token_position position) noexcept; + + /** + * Get the index of the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_index(int32_t delta = 0) const noexcept; + /** + * Get the index of the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline uint32_t peek_index(token_position position) const noexcept; + + const uint8_t* buf{}; + token_position _position{}; + + friend class json_iterator; + friend class value_iterator; + friend class object; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; }; } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { + struct simdjson_result : public arm64::implementation_simdjson_result_base { public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::field&& value) noexcept; ///< @private + simdjson_inline simdjson_result(arm64::ondemand::token_iterator&& value) noexcept; ///< @private simdjson_inline simdjson_result(error_code error) noexcept; ///< @private simdjson_inline simdjson_result() noexcept = default; - - simdjson_inline simdjson_result unescaped_key(bool allow_replacement = false) noexcept; - simdjson_inline simdjson_result key() noexcept; - simdjson_inline simdjson_result value() noexcept; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/field.h */ -/* begin file include/simdjson/generic/ondemand/object.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H +/* end file simdjson/generic/ondemand/token_iterator.h for arm64 */ +/* including simdjson/generic/ondemand/json_iterator.h for arm64: #include "simdjson/generic/ondemand/json_iterator.h" */ +/* begin file simdjson/generic/ondemand/json_iterator.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { namespace ondemand { /** - * A forward-only JSON object field iterator. + * Iterates through JSON tokens, keeping track of depth and string buffer. + * + * @private This is not intended for external use. */ - class object { - public: - /** - * Create a new invalid object. - * - * Exists so you can declare a variable and later assign to it before use. - */ - simdjson_inline object() noexcept = default; - - simdjson_inline simdjson_result begin() noexcept; - simdjson_inline simdjson_result end() noexcept; - /** - * Look up a field by name on an object (order-sensitive). - * - * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the - * JSON `{ "x": 1, "y": 2, "z": 3 }`: - * - * ```c++ - * simdjson::ondemand::parser parser; - * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); - * double z = obj.find_field("z"); - * double y = obj.find_field("y"); - * double x = obj.find_field("x"); - * ``` - * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful - * that only one field is returned. - * - * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. - * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. - * - * You must consume the fields on an object one at a time. A request for a new key - * invalidates previous field values: it makes them unsafe. The value instance you get - * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array - * given by content["bids"].get_array() should not be accessed after you have called - * content["asks"].get_array(). You can detect such mistakes by first compiling and running - * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an - * OUT_OF_ORDER_ITERATION error is generated. - * - * You are expected to access keys only once. You should access the value corresponding to a - * key a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() - * is an error. - * - * @param key The key to look up. - * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. - */ - simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; - /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; - - /** - * Look up a field by name on an object, without regard to key order. - * - * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies - * and often appears negligible. It starts out normally, starting out at the last field; but if - * the field is not found, it scans from the beginning of the object to see if it missed it. That - * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object - * in question is large. The fact that the extra code is there also bumps the executable size. - * - * It is the default, however, because it would be highly surprising (and hard to debug) if the - * default behavior failed to look up a field just because it was in the wrong order--and many - * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. - * - * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the - * field wasn't there when they aren't). - * - * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful - * that only one field is returned. - * - * You must consume the fields on an object one at a time. A request for a new key - * invalidates previous field values: it makes them unsafe. The value instance you get - * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array - * given by content["bids"].get_array() should not be accessed after you have called - * content["asks"].get_array(). You can detect such mistakes by first compiling and running - * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an - * OUT_OF_ORDER_ITERATION error is generated. - * - * You are expected to access keys only once. You should access the value corresponding to a key - * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() is an error. - * - * @param key The key to look up. - * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. - */ - simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; - /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ - simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; - - /** - * Get the value associated with the given JSON pointer. We use the RFC 6901 - * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node - * as the root of its own JSON document. - * - * ondemand::parser parser; - * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; - * auto doc = parser.iterate(json); - * doc.at_pointer("/foo/a/1") == 20 - * - * It is allowed for a key to be the empty string: - * - * ondemand::parser parser; - * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; - * auto doc = parser.iterate(json); - * doc.at_pointer("//a/1") == 20 - * - * Note that at_pointer() called on the document automatically calls the document's rewind - * method between each call. It invalidates all previously accessed arrays, objects and values - * that have not been consumed. Yet it is not the case when calling at_pointer on an object - * instance: there is no rewind and no invalidation. - * - * You may call at_pointer more than once on an object, but each time the pointer is advanced - * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding - * key (as well as the current key) can no longer be used with following JSON pointer calls. - * - * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. - * - * @return The value associated with the given JSON pointer, or: - * - NO_SUCH_FIELD if a field does not exist in an object - * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length - * - INCORRECT_TYPE if a non-integer is used to access an array - * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed - */ - inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - - /** - * Reset the iterator so that we are pointing back at the - * beginning of the object. You should still consume values only once even if you - * can iterate through the object more than once. If you unescape a string within - * the object more than once, you have unsafe code. Note that rewinding an object - * means that you may need to reparse it anew: it is not a free operation. - * - * @returns true if the object contains some elements (not empty) - */ - inline simdjson_result reset() & noexcept; - /** - * This method scans the beginning of the object and checks whether the - * object is empty. - * The runtime complexity is constant time. After - * calling this function, if successful, the object is 'rewinded' at its - * beginning as if it had never been accessed. If the JSON is malformed (e.g., - * there is a missing comma), then an error is returned and it is no longer - * safe to continue. - */ - inline simdjson_result is_empty() & noexcept; - /** - * This method scans the object and counts the number of key-value pairs. - * The count_fields method should always be called before you have begun - * iterating through the object: it is expected that you are pointing at - * the beginning of the object. - * The runtime complexity is linear in the size of the object. After - * calling this function, if successful, the object is 'rewinded' at its - * beginning as if it had never been accessed. If the JSON is malformed (e.g., - * there is a missing comma), then an error is returned and it is no longer - * safe to continue. - * - * To check that an object is empty, it is more performant to use - * the is_empty() method. - * - * Performance hint: You should only call count_fields() as a last - * resort as it may require scanning the document twice or more. - */ - simdjson_inline simdjson_result count_fields() & noexcept; - /** - * Consumes the object and returns a string_view instance corresponding to the - * object as represented in JSON. It points inside the original byte array containing - * the JSON document. - */ - simdjson_inline simdjson_result raw_json() noexcept; - + class json_iterator { protected: + token_iterator token{}; + ondemand::parser* parser{}; /** - * Go to the end of the object, no matter where you are right now. + * Next free location in the string buffer. + * + * Used by raw_json_string::unescape() to have a place to unescape strings to. */ - simdjson_inline error_code consume() noexcept; - static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; - static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; - static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; - static simdjson_inline object resume(const value_iterator& iter) noexcept; - simdjson_inline object(const value_iterator& iter) noexcept; + uint8_t* _string_buf_loc{}; + /** + * JSON error, if there is one. + * + * INCORRECT_TYPE and NO_SUCH_FIELD are *not* stored here, ever. + * + * PERF NOTE: we *hope* this will be elided into control flow, as it is only used (a) in the first + * iteration of the loop, or (b) for the final iteration after a missing comma is found in ++. If + * this is not elided, we should make sure it's at least not using up a register. Failing that, + * we should store it in document so there's only one of them. + */ + error_code error{ SUCCESS }; + /** + * Depth of the current token in the JSON. + * + * - 0 = finished with document + * - 1 = document root value (could be [ or {, not yet known) + * - 2 = , or } inside root array/object + * - 3 = key or value inside root array/object. + */ + depth_t _depth{}; + /** + * Beginning of the document indexes. + * Normally we have root == parser->implementation->structural_indexes.get() + * but this may differ, especially in streaming mode (where we have several + * documents); + */ + token_position _root{}; + /** + * Normally, a json_iterator operates over a single document, but in + * some cases, we may have a stream of documents. This attribute is meant + * as meta-data: the json_iterator works the same irrespective of the + * value of this attribute. + */ + bool _streaming{ false }; - simdjson_warn_unused simdjson_inline error_code find_field_raw(const std::string_view key) noexcept; + public: + simdjson_inline json_iterator() noexcept = default; + simdjson_inline json_iterator(json_iterator&& other) noexcept; + simdjson_inline json_iterator& operator=(json_iterator&& other) noexcept; + simdjson_inline explicit json_iterator(const json_iterator& other) noexcept = default; + simdjson_inline json_iterator& operator=(const json_iterator& other) noexcept = default; + /** + * Skips a JSON value, whether it is a scalar, array or object. + */ + simdjson_warn_unused simdjson_inline error_code skip_child(depth_t parent_depth) noexcept; - value_iterator iter{}; + /** + * Tell whether the iterator is still at the start + */ + simdjson_inline bool at_root() const noexcept; + + /** + * Tell whether we should be expected to run in streaming + * mode (iterating over many documents). It is pure metadata + * that does not affect how the iterator works. It is used by + * start_root_array() and start_root_object(). + */ + simdjson_inline bool streaming() const noexcept; + + /** + * Get the root value iterator + */ + simdjson_inline token_position root_position() const noexcept; + /** + * Assert that we are at the document depth (== 1) + */ + simdjson_inline void assert_at_document_depth() const noexcept; + /** + * Assert that we are at the root of the document + */ + simdjson_inline void assert_at_root() const noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is live (has not been moved). + */ + simdjson_inline bool is_alive() const noexcept; + + /** + * Abandon this iterator, setting depth to 0 (as if the document is finished). + */ + simdjson_inline void abandon() noexcept; + + /** + * Advance the current token without modifying depth. + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + + /** + * Returns true if there is a single token in the index (i.e., it is + * a JSON with a scalar value such as a single number). + * + * @return whether there is a single token + */ + simdjson_inline bool is_single_token() const noexcept; + + /** + * Assert that there are at least the given number of tokens left. + * + * Has no effect in release builds. + */ + simdjson_inline void assert_more_tokens(uint32_t required_tokens = 1) const noexcept; + /** + * Assert that the given position addresses an actual token (is within bounds). + * + * Has no effect in release builds. + */ + simdjson_inline void assert_valid_position(token_position position) const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + /** + * Get a pointer to the current location in the input buffer. + * + * This is not null-terminated; it is a view into the JSON. + * + * You may be pointing outside of the input buffer: it is not generally + * safe to dereference this pointer. + */ + simdjson_inline const uint8_t* unsafe_pointer() const noexcept; + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token to retrieve. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token to retrieve. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + /** + * Get the JSON text for the last token in the document. + * + * This is not null-terminated; it is a view into the JSON. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek_last() const noexcept; + + /** + * Ascend one level. + * + * Validates that the depth - 1 == parent_depth. + * + * @param parent_depth the expected parent depth. + */ + simdjson_inline void ascend_to(depth_t parent_depth) noexcept; + + /** + * Descend one level. + * + * Validates that the new depth == child_depth. + * + * @param child_depth the expected child depth. + */ + simdjson_inline void descend_to(depth_t child_depth) noexcept; + simdjson_inline void descend_to(depth_t child_depth, int32_t delta) noexcept; + + /** + * Get current depth. + */ + simdjson_inline depth_t depth() const noexcept; + + /** + * Get current (writeable) location in the string buffer. + */ + simdjson_inline uint8_t*& string_buf_loc() noexcept; + + /** + * Report an unrecoverable error, preventing further iteration. + * + * @param error The error to report. Must not be SUCCESS, UNINITIALIZED, INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + /** + * Log error, but don't stop iteration. + * @param error The error to report. Must be INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code optional_error(error_code error, const char* message) noexcept; + + /** + * Take an input in json containing max_len characters and attempt to copy it over to tmpbuf, a buffer with + * N bytes of capacity. It will return false if N is too small (smaller than max_len) of if it is zero. + * The buffer (tmpbuf) is padded with space characters. + */ + simdjson_warn_unused simdjson_inline bool copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept; + + simdjson_inline token_position position() const noexcept; + /** + * Write the raw_json_string to the string buffer and return a string_view. + * Each raw_json_string should be unescaped once, or else the string buffer might + * overflow. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, bool allow_replacement) noexcept; + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in) noexcept; + + simdjson_inline void reenter_child(token_position position, depth_t child_depth) noexcept; + + simdjson_inline error_code consume_character(char c) noexcept; +#if SIMDJSON_DEVELOPMENT_CHECKS + simdjson_inline token_position start_position(depth_t depth) const noexcept; + simdjson_inline void set_start_position(depth_t depth, token_position position) noexcept; +#endif + + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Updates this json iterator so that it is back at the beginning of the document, + * as if it had just been created. + */ + inline void rewind() noexcept; + /** + * This checks whether the {,},[,] are balanced so that the document + * ends with proper zero depth. This requires scanning the whole document + * and it may be expensive. It is expected that it will be rarely called. + * It does not attempt to match { with } and [ with ]. + */ + inline bool balanced() const noexcept; + protected: + simdjson_inline json_iterator(const uint8_t* buf, ondemand::parser* parser) noexcept; + /// The last token before the end + simdjson_inline token_position last_position() const noexcept; + /// The token *at* the end. This points at gibberish and should only be used for comparison. + simdjson_inline token_position end_position() const noexcept; + /// The end of the buffer. + simdjson_inline token_position end() const noexcept; - friend class value; friend class document; - friend struct simdjson_result; - }; + friend class document_stream; + friend class object; + friend class array; + friend class value; + friend class raw_json_string; + friend class parser; + friend class value_iterator; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; // json_iterator } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { + struct simdjson_result : public arm64::implementation_simdjson_result_base { public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object&& value) noexcept; ///< @private + simdjson_inline simdjson_result(arm64::ondemand::json_iterator&& value) noexcept; ///< @private simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; - - simdjson_inline simdjson_result begin() noexcept; - simdjson_inline simdjson_result end() noexcept; - simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; - simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; - simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; - simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; - simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; - simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; - inline simdjson_result reset() noexcept; - inline simdjson_result is_empty() noexcept; - inline simdjson_result count_fields() & noexcept; - }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/object.h */ -/* begin file include/simdjson/generic/ondemand/parser.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H +/* end file simdjson/generic/ondemand/json_iterator.h for arm64 */ +/* including simdjson/generic/ondemand/json_type.h for arm64: #include "simdjson/generic/ondemand/json_type.h" */ +/* begin file simdjson/generic/ondemand/json_type.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { namespace ondemand { - class array; - class object; - class value; - class raw_json_string; - class document_stream; + /** + * The type of a JSON value. + */ + enum class json_type { + // Start at 1 to catch uninitialized / default values more easily + array = 1, ///< A JSON array ( [ 1, 2, 3 ... ] ) + object, ///< A JSON object ( { "a": 1, "b" 2, ... } ) + number, ///< A JSON number ( 1 or -2.3 or 4.5e6 ...) + string, ///< A JSON string ( "a" or "hello world\n" ...) + boolean, ///< A JSON boolean (true or false) + null ///< A JSON null (null) + }; + + /** + * A type representing a JSON number. + * The design of the struct is deliberately straight-forward. All + * functions return standard values with no error check. + */ + struct number { + + /** + * return the automatically determined type of + * the number: number_type::floating_point_number, + * number_type::signed_integer or number_type::unsigned_integer. + * + * enum class number_type { + * floating_point_number=1, /// a binary64 number + * signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + * unsigned_integer /// a positive integer larger or equal to 1<<63 + * }; + */ + simdjson_inline ondemand::number_type get_number_type() const noexcept; + /** + * return true if the automatically determined type of + * the number is number_type::unsigned_integer. + */ + simdjson_inline bool is_uint64() const noexcept; + /** + * return the value as a uint64_t, only valid if is_uint64() is true. + */ + simdjson_inline uint64_t get_uint64() const noexcept; + simdjson_inline operator uint64_t() const noexcept; + + /** + * return true if the automatically determined type of + * the number is number_type::signed_integer. + */ + simdjson_inline bool is_int64() const noexcept; + /** + * return the value as a int64_t, only valid if is_int64() is true. + */ + simdjson_inline int64_t get_int64() const noexcept; + simdjson_inline operator int64_t() const noexcept; + + + /** + * return true if the automatically determined type of + * the number is number_type::floating_point_number. + */ + simdjson_inline bool is_double() const noexcept; + /** + * return the value as a double, only valid if is_double() is true. + */ + simdjson_inline double get_double() const noexcept; + simdjson_inline operator double() const noexcept; + + /** + * Convert the number to a double. Though it always succeed, the conversion + * may be lossy if the number cannot be represented exactly. + */ + simdjson_inline double as_double() const noexcept; + + + protected: + /** + * The next block of declaration is designed so that we can call the number parsing + * functions on a number type. They are protected and should never be used outside + * of the core simdjson library. + */ + friend class value_iterator; + template + friend error_code numberparsing::slow_float_parsing(simdjson_unused const uint8_t* src, W writer); + template + friend error_code numberparsing::write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer); + template + friend error_code numberparsing::parse_number(const uint8_t* const src, W& writer); + /** Store a signed 64-bit value to the number. */ + simdjson_inline void append_s64(int64_t value) noexcept; + /** Store an unsigned 64-bit value to the number. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + /** Store a double value to the number. */ + simdjson_inline void append_double(double value) noexcept; + /** Specifies that the value is a double, but leave it undefined. */ + simdjson_inline void skip_double() noexcept; + /** + * End of friend declarations. + */ + + /** + * Our attributes are a union type (size = 64 bits) + * followed by a type indicator. + */ + union { + double floating_point_number; + int64_t signed_integer; + uint64_t unsigned_integer; + } payload{ 0 }; + number_type type{ number_type::signed_integer }; + }; + + /** + * Write the JSON type to the output stream + * + * @param out The output stream. + * @param type The json_type. + */ + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Send JSON type to an output stream. + * + * @param out The output stream. + * @param type The json_type. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false); +#endif + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::json_type&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H +/* end file simdjson/generic/ondemand/json_type.h for arm64 */ +/* including simdjson/generic/ondemand/raw_json_string.h for arm64: #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + /** + * A string escaped per JSON rules, terminated with quote ("). They are used to represent + * unescaped keys inside JSON documents. + * + * (In other words, a pointer to the beginning of a string, just after the start quote, inside a + * JSON file.) + * + * This class is deliberately simplistic and has little functionality. You can + * compare a raw_json_string instance with an unescaped C string, but + * that is nearly all you can do. + * + * The raw_json_string is unescaped. If you wish to write an unescaped version of it to your own + * buffer, you may do so using the parser.unescape(string, buff) method, using an ondemand::parser + * instance. Doing so requires you to have a sufficiently large buffer. + * + * The raw_json_string instances originate typically from field instance which in turn represent + * key-value pairs from object instances. From a field instance, you get the raw_json_string + * instance by calling key(). You can, if you want a more usable string_view instance, call + * the unescaped_key() method on the field instance. You may also create a raw_json_string from + * any other string value, with the value.get_raw_json_string() method. Again, you can get + * a more usable string_view instance by calling get_string(). + * + */ + class raw_json_string { + public: + /** + * Create a new invalid raw_json_string. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline raw_json_string() noexcept = default; + + /** + * Create a new invalid raw_json_string pointed at the given location in the JSON. + * + * The given location must be just *after* the beginning quote (") in the JSON file. + * + * It *must* be terminated by a ", and be a valid JSON string. + */ + simdjson_inline raw_json_string(const uint8_t* _buf) noexcept; + /** + * Get the raw pointer to the beginning of the string in the JSON (just after the "). + * + * It is possible for this function to return a null pointer if the instance + * has outlived its existence. + */ + simdjson_inline const char* raw() const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done) on target.size() characters, + * and if the raw_json_string instance has a quote character at byte index target.size(). + * We never read more than length + 1 bytes in the raw_json_string instance. + * If length is smaller than target.size(), this will return false. + * + * The std::string_view instance may contain any characters. However, the caller + * is responsible for setting length so that length bytes may be read in the + * raw_json_string. + * + * Performance: the comparison may be done using memcmp which may be efficient + * for long strings. + */ + simdjson_inline bool unsafe_is_equal(size_t length, std::string_view target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The std::string_view instance should not contain unescaped quote characters: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * Performance: the comparison is done byte-by-byte which might be inefficient for + * long strings. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The provided C string should not contain an unescaped quote character: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(const char* target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(const char* target) const noexcept; + + /** + * Returns true if target is free from unescaped quote. If target is known at + * compile-time, we might expect the computation to happen at compile time with + * many compilers (not all!). + */ + static simdjson_inline bool is_free_from_unescaped_quote(std::string_view target) noexcept; + static simdjson_inline bool is_free_from_unescaped_quote(const char* target) noexcept; + + private: + + + /** + * This will set the inner pointer to zero, effectively making + * this instance unusable. + */ + simdjson_inline void consume() noexcept { buf = nullptr; } + + /** + * Checks whether the inner pointer is non-null and thus usable. + */ + simdjson_inline simdjson_warn_unused bool alive() const noexcept { return buf != nullptr; } + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result will be a valid UTF-8. + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + * @param allow_replacement Whether we allow replacement of invalid surrogate pairs. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape(json_iterator& iter, bool allow_replacement) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result may not be a valid UTF-8. https://simonsapin.github.io/wtf-8/ + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(json_iterator& iter) const noexcept; + const uint8_t* buf{}; + friend class object; + friend class field; + friend class parser; + friend struct simdjson_result; + }; + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream&, const raw_json_string&) noexcept; + + /** + * Comparisons between raw_json_string and std::string_view instances are potentially unsafe: the user is responsible + * for providing a string with no unescaped quote. Note that unescaped quotes cannot be present in valid JSON strings. + */ + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept; + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept; + + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::raw_json_string&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + + simdjson_inline simdjson_result raw() const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape(arm64::ondemand::json_iterator& iter, bool allow_replacement) const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(arm64::ondemand::json_iterator& iter) const noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H +/* end file simdjson/generic/ondemand/raw_json_string.h for arm64 */ +/* including simdjson/generic/ondemand/parser.h for arm64: #include "simdjson/generic/ondemand/parser.h" */ +/* begin file simdjson/generic/ondemand/parser.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace arm64 { + namespace ondemand { /** * The default batch size for document_stream instances for this On Demand kernel. @@ -26511,7 +29131,7 @@ namespace simdjson { * It is expected that the content is a valid UTF-8 file, containing a valid JSON document. * Otherwise the iterate method may return an error. In particular, the whole input should be * valid: we do not attempt to tolerate incorrect content either before or after a JSON - * document. + * document. If there is a UTF-8 BOM, the parser skips it. * * ### IMPORTANT: Validate what you use * @@ -26559,6 +29179,8 @@ namespace simdjson { /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ simdjson_warn_unused simdjson_result iterate(const std::string& json) & noexcept; /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; @@ -26638,6 +29260,7 @@ namespace simdjson { * arrays or objects) MUST be separated with ASCII whitespace. * * The characters inside a JSON document, and between JSON documents, must be valid Unicode (UTF-8). + * If there is a UTF-8 BOM, the parser skips it. * * The documents must not exceed batch_size bytes (by default 1MB) or they will fail to parse. * Setting batch_size to excessively large or excessively small values may impact negatively the @@ -26666,21 +29289,26 @@ namespace simdjson { * spot is cache-related: small enough to fit in cache, yet big enough to * parse as many documents as possible in one tight loop. * Defaults to 10MB, which has been a reasonable sweet spot in our tests. + * @param allow_comma_separated (defaults on false) This allows a mode where the documents are + * separated by commas instead of whitespace. It comes with a performance + * penalty because the entire document is indexed at once (and the document must be + * less than 4 GB), and there is no multithreading. In this mode, the batch_size parameter + * is effectively ignored, as it is set to at least the document size. * @return The stream, or an error. An empty input will yield 0 documents rather than an EMPTY error. Errors: * - MEMALLOC if the parser does not have enough capacity and memory allocation fails * - CAPACITY if the parser does not have enough capacity and batch_size > max_capacity. * - other json errors if parsing fails. You should not rely on these errors to always the same for the * same document: they may vary under runtime dispatch (so they may vary depending on your system and hardware). */ - inline simdjson_result iterate_many(const uint8_t* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept; + inline simdjson_result iterate_many(const uint8_t* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ - inline simdjson_result iterate_many(const char* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept; + inline simdjson_result iterate_many(const char* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ - inline simdjson_result iterate_many(const std::string& s, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept; - inline simdjson_result iterate_many(const std::string&& s, size_t batch_size) = delete;// unsafe + inline simdjson_result iterate_many(const std::string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const std::string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ - inline simdjson_result iterate_many(const padded_string& s, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept; - inline simdjson_result iterate_many(const padded_string&& s, size_t batch_size) = delete;// unsafe + inline simdjson_result iterate_many(const padded_string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const padded_string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe /** @private We do not want to allow implicit conversion from C string to std::string. */ simdjson_result iterate_many(const char* buf, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept = delete; @@ -26784,22 +29412,1186 @@ namespace simdjson { }; } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { + struct simdjson_result : public arm64::implementation_simdjson_result_base { public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::parser&& value) noexcept; ///< @private + simdjson_inline simdjson_result(arm64::ondemand::parser&& value) noexcept; ///< @private simdjson_inline simdjson_result(error_code error) noexcept; ///< @private simdjson_inline simdjson_result() noexcept = default; }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/parser.h */ -/* begin file include/simdjson/generic/ondemand/document_stream.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_H +/* end file simdjson/generic/ondemand/parser.h for arm64 */ + +// All other declarations +/* including simdjson/generic/ondemand/array.h for arm64: #include "simdjson/generic/ondemand/array.h" */ +/* begin file simdjson/generic/ondemand/array.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + /** + * A forward-only JSON array. + */ + class array { + public: + /** + * Create a new invalid array. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline array() noexcept = default; + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an array is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the beginning of the array and checks whether the + * array is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result is_empty() & noexcept; + /** + * Reset the iterator so that we are pointing back at the + * beginning of the array. You should still consume values only once even if you + * can iterate through the array more than once. If you unescape a string + * within the array more than once, you have unsafe code. Note that rewinding + * an array means that you may need to reparse it anew: it is not a free + * operation. + * + * @returns true if the array contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"([ { "foo": { "a": [ 10, 20, 30 ] }} ])"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/0/foo/a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an array + * instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the array and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Get the value at the given index. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + protected: + /** + * Go to the end of the array, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + + /** + * Begin array iteration. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + */ + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + /** + * Begin array iteration from the root. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + * @error TAPE_ERROR if there is no closing ] at the end of the document. + */ + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + /** + * Begin array iteration. + * + * This version of the method should be called after the initial [ has been verified, and is + * intended for use by switch statements that check the type of a value. + * + * @param iter The iterator. Must be after the initial [. Will be *moved* into the resulting array. + */ + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + + /** + * Create an array at the given Internal array creation. Call array::start() or array::started() instead of this. + * + * @param iter The iterator. Must either be at the start of the first element with iter.is_alive() + * == true, or past the [] with is_alive() == false if the array is empty. Will be *moved* + * into the resulting array. + */ + simdjson_inline array(const value_iterator& iter) noexcept; + + /** + * Iterator marking current position. + * + * iter.is_alive() == false indicates iteration is complete. + */ + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + friend struct simdjson_result; + friend class array_iterator; + }; + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::array&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + inline simdjson_result count_elements() & noexcept; + inline simdjson_result is_empty() & noexcept; + inline simdjson_result reset() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_H +/* end file simdjson/generic/ondemand/array.h for arm64 */ +/* including simdjson/generic/ondemand/array_iterator.h for arm64: #include "simdjson/generic/ondemand/array_iterator.h" */ +/* begin file simdjson/generic/ondemand/array_iterator.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + /** + * A forward-only JSON array. + * + * This is an input_iterator, meaning: + * - It is forward-only + * - * must be called exactly once per element. + * - ++ must be called exactly once in between each * (*, ++, *, ++, * ...) + */ + class array_iterator { + public: + /** Create a new, invalid array iterator. */ + simdjson_inline array_iterator() noexcept = default; + + // + // Iterator interface + // + + /** + * Get the current element. + * + * Part of the std::iterator interface. + */ + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + /** + * Check if we are at the end of the JSON. + * + * Part of the std::iterator interface. + * + * @return true if there are no more elements in the JSON array. + */ + simdjson_inline bool operator==(const array_iterator&) const noexcept; + /** + * Check if there are more elements in the JSON array. + * + * Part of the std::iterator interface. + * + * @return true if there are more elements in the JSON array. + */ + simdjson_inline bool operator!=(const array_iterator&) const noexcept; + /** + * Move to the next element. + * + * Part of the std::iterator interface. + */ + simdjson_inline array_iterator& operator++() noexcept; + + private: + value_iterator iter{}; + + simdjson_inline array_iterator(const value_iterator& iter) noexcept; + + friend class array; + friend class value; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::array_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H +/* end file simdjson/generic/ondemand/array_iterator.h for arm64 */ +/* including simdjson/generic/ondemand/document.h for arm64: #include "simdjson/generic/ondemand/document.h" */ +/* begin file simdjson/generic/ondemand/document.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + /** + * A JSON document. It holds a json_iterator instance. + * + * Used by tokens to get text, and string buffer location. + * + * You must keep the document around during iteration. + */ + class document { + public: + /** + * Create a new invalid document. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline document() noexcept = default; + simdjson_inline document(const document& other) noexcept = delete; // pass your documents by reference, not by copy + simdjson_inline document(document&& other) noexcept = default; + simdjson_inline document& operator=(const document& other) noexcept = delete; + simdjson_inline document& operator=(document&& other) noexcept = default; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() & noexcept; + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() & noexcept; + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + /** + * Cast this JSON value (inside string) to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: Calling get_string() twice on the same document is an error. + * + * @param Whether to allow a replacement character for unmatched surrogate pairs. + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + /** + * Cast this JSON value to a string. + * + * The string is not guaranteed to be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * + * Important: Calling get_wobbly_string() twice on the same document is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is set to 1 (which is the case when building in Debug mode + * by default), and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value if a JSON array or object cannot be found. + * @returns SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result get_value() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() & noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + /** @overload template simdjson_result get() & noexcept */ + template simdjson_inline simdjson_result get() && noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool, value + * + * Be mindful that the document instance must remain in scope while you are accessing object, array and value instances. + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) & noexcept; + /** @overload template error_code get(T &out) & noexcept */ + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() & noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() & noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is defined, and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value value if a JSON array or object cannot be found. + * @exception SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline operator value() noexcept(false); +#endif + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) & noexcept; + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to + * a key a single time. Doing object["mykey"].to_string()and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the document is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the document is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the document is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. If this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view may be the padded buffer. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + /** + * Reset the iterator inside the document instance so we are pointing back at the + * beginning of the document, as if it had just been created. It invalidates all + * values, objects and arrays that you have created so far (including unescaped strings). + */ + inline void rewind() noexcept; + /** + * Returns debugging information. + */ + inline std::string to_debug_string() noexcept; + /** + * Some unrecoverable error conditions may render the document instance unusable. + * The is_alive() method returns true when the document is still suitable. + */ + inline bool is_alive() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Returns true if this document has been fully parsed. + * If you have consumed the whole document and at_end() returns + * false, then there may be trailing content. + */ + inline bool at_end() const noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() automatically calls rewind between each call. Thus + * all values, objects and arrays that you have created so far (including unescaped strings) + * are invalidated. After calling at_pointer, you need to consume the result: string values + * should be stored in your own variables, arrays should be decoded and stored in your own array-like + * structures and so forth. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + * - SCALAR_DOCUMENT_AS_VALUE if the json_pointer is empty and the document is not a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the document and returns a string_view instance corresponding to the + * document as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + protected: + /** + * Consumes the document. + */ + simdjson_inline error_code consume() noexcept; + + simdjson_inline document(ondemand::json_iterator&& iter) noexcept; + simdjson_inline const uint8_t* text(uint32_t idx) const noexcept; + + simdjson_inline value_iterator resume_value_iterator() noexcept; + simdjson_inline value_iterator get_root_value_iterator() noexcept; + simdjson_inline simdjson_result start_or_resume_object() noexcept; + static simdjson_inline document start(ondemand::json_iterator&& iter) noexcept; + + // + // Fields + // + json_iterator iter{}; ///< Current position in the document + static constexpr depth_t DOCUMENT_DEPTH = 0; ///< document depth is always 0 + + friend class array_iterator; + friend class value; + friend class ondemand::parser; + friend class object; + friend class array; + friend class field; + friend class token; + friend class document_stream; + friend class document_reference; + }; + + + /** + * A document_reference is a thin wrapper around a document reference instance. + */ + class document_reference { + public: + simdjson_inline document_reference() noexcept; + simdjson_inline document_reference(document& d) noexcept; + simdjson_inline document_reference(const document_reference& other) noexcept = default; + simdjson_inline document_reference& operator=(const document_reference& other) noexcept = default; + simdjson_inline void rewind() noexcept; + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + + simdjson_inline simdjson_result is_null() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + simdjson_inline operator document& () const noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator array() & noexcept(false); + simdjson_inline operator object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + private: + document* doc{ nullptr }; + }; + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::document&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() & noexcept; + template simdjson_inline simdjson_result get() && noexcept; + + template simdjson_inline error_code get(T& out) & noexcept; + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator arm64::ondemand::array() & noexcept(false); + simdjson_inline operator arm64::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator arm64::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator arm64::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool at_end() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + + + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::document_reference value, error_code error) noexcept; + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator arm64::ondemand::array() & noexcept(false); + simdjson_inline operator arm64::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator arm64::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator arm64::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document_reference::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H +/* end file simdjson/generic/ondemand/document.h for arm64 */ +/* including simdjson/generic/ondemand/document_stream.h for arm64: #include "simdjson/generic/ondemand/document_stream.h" */ +/* begin file simdjson/generic/ondemand/document_stream.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + #ifdef SIMDJSON_THREADS_ENABLED #include #include @@ -26807,13 +30599,9 @@ namespace simdjson { #endif namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { namespace ondemand { - class parser; - class json_iterator; - class document; - #ifdef SIMDJSON_THREADS_ENABLED /** @private Custom worker class **/ struct stage1_worker { @@ -27023,7 +30811,8 @@ namespace simdjson { ondemand::parser& parser, const uint8_t* buf, size_t len, - size_t batch_size + size_t batch_size, + bool allow_comma_separated ) noexcept; /** @@ -27036,8 +30825,7 @@ namespace simdjson { * Parse the next document found in the buffer previously given to document_stream. * * The content should be a valid JSON document encoded as UTF-8. If there is a - * UTF-8 BOM, the caller is responsible for omitting it, UTF-8 BOM are - * discouraged. + * UTF-8 BOM, the parser skips it. * * You do NOT need to pre-allocate a parser. This function takes care of * pre-allocating a capacity defined by the batch_size defined when creating the @@ -27072,6 +30860,7 @@ namespace simdjson { const uint8_t* buf; size_t len; size_t batch_size; + bool allow_comma_separated; /** * We are going to use just one document instance. The document owns * the json_iterator. It implies that we only ever pass a reference @@ -27116,21 +30905,440 @@ namespace simdjson { }; // document_stream } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { template<> - struct simdjson_result : public SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base { + struct simdjson_result : public arm64::implementation_simdjson_result_base { public: - simdjson_inline simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document_stream&& value) noexcept; ///< @private + simdjson_inline simdjson_result(arm64::ondemand::document_stream&& value) noexcept; ///< @private simdjson_inline simdjson_result(error_code error) noexcept; ///< @private simdjson_inline simdjson_result() noexcept = default; }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/document_stream.h */ -/* begin file include/simdjson/generic/ondemand/serialization.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H +/* end file simdjson/generic/ondemand/document_stream.h for arm64 */ +/* including simdjson/generic/ondemand/field.h for arm64: #include "simdjson/generic/ondemand/field.h" */ +/* begin file simdjson/generic/ondemand/field.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + /** + * A JSON field (key/value pair) in an object. + * + * Returned from object iteration. + * + * Extends from std::pair so you can use C++ algorithms that rely on pairs. + */ + class field : public std::pair { + public: + /** + * Create a new invalid field. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline field() noexcept; + + /** + * Get the key as a string_view (for higher speed, consider raw_key). + * We deliberately use a more cumbersome name (unescaped_key) to force users + * to think twice about using it. + * + * This consumes the key: once you have called unescaped_key(), you cannot + * call it again nor can you call key(). + */ + simdjson_inline simdjson_warn_unused simdjson_result unescaped_key(bool allow_replacement) noexcept; + /** + * Get the key as a raw_json_string. Can be used for direct comparison with + * an unescaped C string: e.g., key() == "test". + */ + simdjson_inline raw_json_string key() const noexcept; + /** + * Get the field value. + */ + simdjson_inline ondemand::value& value() & noexcept; + /** + * @overload ondemand::value &ondemand::value() & noexcept + */ + simdjson_inline ondemand::value value() && noexcept; + + protected: + simdjson_inline field(raw_json_string key, ondemand::value&& value) noexcept; + static simdjson_inline simdjson_result start(value_iterator& parent_iter) noexcept; + static simdjson_inline simdjson_result start(const value_iterator& parent_iter, raw_json_string key) noexcept; + friend struct simdjson_result; + friend class object_iterator; + }; + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::field&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result unescaped_key(bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result key() noexcept; + simdjson_inline simdjson_result value() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_H +/* end file simdjson/generic/ondemand/field.h for arm64 */ +/* including simdjson/generic/ondemand/object.h for arm64: #include "simdjson/generic/ondemand/object.h" */ +/* begin file simdjson/generic/ondemand/object.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + /** + * A forward-only JSON object field iterator. + */ + class object { + public: + /** + * Create a new invalid object. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a + * key a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an object + * instance: there is no rewind and no invalidation. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + /** + * Reset the iterator so that we are pointing back at the + * beginning of the object. You should still consume values only once even if you + * can iterate through the object more than once. If you unescape a string within + * the object more than once, you have unsafe code. Note that rewinding an object + * means that you may need to reparse it anew: it is not a free operation. + * + * @returns true if the object contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * This method scans the beginning of the object and checks whether the + * object is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + inline simdjson_result is_empty() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Consumes the object and returns a string_view instance corresponding to the + * object as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + protected: + /** + * Go to the end of the object, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + static simdjson_inline object resume(const value_iterator& iter) noexcept; + simdjson_inline object(const value_iterator& iter) noexcept; + + simdjson_warn_unused simdjson_inline error_code find_field_raw(const std::string_view key) noexcept; + + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::object&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + inline simdjson_result reset() noexcept; + inline simdjson_result is_empty() noexcept; + inline simdjson_result count_fields() & noexcept; + inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_H +/* end file simdjson/generic/ondemand/object.h for arm64 */ +/* including simdjson/generic/ondemand/object_iterator.h for arm64: #include "simdjson/generic/ondemand/object_iterator.h" */ +/* begin file simdjson/generic/ondemand/object_iterator.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + class object_iterator { + public: + /** + * Create a new invalid object_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object_iterator() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline simdjson_result operator*() noexcept; + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const object_iterator&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const object_iterator&) const noexcept; + // Checks for ']' and ',' + simdjson_inline object_iterator& operator++() noexcept; + + private: + /** + * The underlying JSON iterator. + * + * PERF NOTE: expected to be elided in favor of the parent document: this is set when the object + * is first used, and never changes afterwards. + */ + value_iterator iter{}; + + simdjson_inline object_iterator(const value_iterator& iter) noexcept; + friend struct simdjson_result; + friend class object; + }; + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public arm64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(arm64::ondemand::object_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + // Checks for ']' and ',' + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H +/* end file simdjson/generic/ondemand/object_iterator.h for arm64 */ +/* including simdjson/generic/ondemand/serialization.h for arm64: #include "simdjson/generic/ondemand/serialization.h" */ +/* begin file simdjson/generic/ondemand/serialization.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { /** @@ -27138,30 +31346,30 @@ namespace simdjson { * contains JSON text that is suitable to be parsed as JSON again. It does not * validate the content. */ - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document& x) noexcept; + inline simdjson_result to_json_string(arm64::ondemand::document& x) noexcept; /** * Create a string-view instance out of a value instance. The string-view instance * contains JSON text that is suitable to be parsed as JSON again. The value must * not have been accessed previously. It does not * validate the content. */ - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value& x) noexcept; + inline simdjson_result to_json_string(arm64::ondemand::value& x) noexcept; /** * Create a string-view instance out of an object instance. The string-view instance * contains JSON text that is suitable to be parsed as JSON again. It does not * validate the content. */ - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object& x) noexcept; + inline simdjson_result to_json_string(arm64::ondemand::object& x) noexcept; /** * Create a string-view instance out of an array instance. The string-view instance * contains JSON text that is suitable to be parsed as JSON again. It does not * validate the content. */ - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array& x) noexcept; - inline simdjson_result to_json_string(simdjson_result x); - inline simdjson_result to_json_string(simdjson_result x); - inline simdjson_result to_json_string(simdjson_result x); - inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(arm64::ondemand::array& x) noexcept; + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); } // namespace simdjson /** @@ -27172,7 +31380,7 @@ namespace simdjson { * See https://github.com/simdjson/simdjson/issues/1768 */ namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { namespace ondemand { /** @@ -27183,9 +31391,9 @@ namespace simdjson { * @param value The element. * @throw if there is an error with the underlying output stream. simdjson itself will not throw. */ - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value x); + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::value x); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); #endif /** * Print JSON to an output stream. It does not @@ -27195,9 +31403,9 @@ namespace simdjson { * @param value The array. * @throw if there is an error with the underlying output stream. simdjson itself will not throw. */ - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array value); + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::array value); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); #endif /** * Print JSON to an output stream. It does not @@ -27207,13 +31415,13 @@ namespace simdjson { * @param value The array. * @throw if there is an error with the underlying output stream. simdjson itself will not throw. */ - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document& value); + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::document& value); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); #endif - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document_reference& value); + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::document_reference& value); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); #endif /** * Print JSON to an output stream. It does not @@ -27223,678 +31431,1721 @@ namespace simdjson { * @param value The object. * @throw if there is an error with the underlying output stream. simdjson itself will not throw. */ - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object value); + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::object value); #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); #endif } } -} // namespace simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand -/* end file include/simdjson/generic/ondemand/serialization.h */ -/* end file include/simdjson/generic/ondemand.h */ +} // namespace simdjson::arm64::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H +/* end file simdjson/generic/ondemand/serialization.h for arm64 */ // Inline definitions -/* begin file include/simdjson/generic/implementation_simdjson_result_base-inl.h */ +/* including simdjson/generic/ondemand/array-inl.h for arm64: #include "simdjson/generic/ondemand/array-inl.h" */ +/* begin file simdjson/generic/ondemand/array-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - - // - // internal::implementation_simdjson_result_base inline implementation - // - - template - simdjson_inline void implementation_simdjson_result_base::tie(T& value, error_code& error) && noexcept { - error = this->second; - if (!error) { - value = std::forward>(*this).first; - } - } - - template - simdjson_warn_unused simdjson_inline error_code implementation_simdjson_result_base::get(T& value) && noexcept { - error_code error; - std::forward>(*this).tie(value, error); - return error; - } - - template - simdjson_inline error_code implementation_simdjson_result_base::error() const noexcept { - return this->second; - } - -#if SIMDJSON_EXCEPTIONS - - template - simdjson_inline T& implementation_simdjson_result_base::value() & noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return this->first; - } - - template - simdjson_inline T&& implementation_simdjson_result_base::value() && noexcept(false) { - return std::forward>(*this).take_value(); - } - - template - simdjson_inline T&& implementation_simdjson_result_base::take_value() && noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return std::forward(this->first); - } - - template - simdjson_inline implementation_simdjson_result_base::operator T && () && noexcept(false) { - return std::forward>(*this).take_value(); - } - -#endif // SIMDJSON_EXCEPTIONS - - template - simdjson_inline const T& implementation_simdjson_result_base::value_unsafe() const& noexcept { - return this->first; - } - - template - simdjson_inline T& implementation_simdjson_result_base::value_unsafe() & noexcept { - return this->first; - } - - template - simdjson_inline T&& implementation_simdjson_result_base::value_unsafe() && noexcept { - return std::forward(this->first); - } - - template - simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value, error_code error) noexcept - : first{ std::forward(value) }, second{ error } {} - template - simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(error_code error) noexcept - : implementation_simdjson_result_base(T{}, error) {} - template - simdjson_inline implementation_simdjson_result_base::implementation_simdjson_result_base(T&& value) noexcept - : implementation_simdjson_result_base(std::forward(value), SUCCESS) {} - - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson -/* end file include/simdjson/generic/implementation_simdjson_result_base-inl.h */ -/* begin file include/simdjson/generic/ondemand-inl.h */ -/* begin file include/simdjson/generic/ondemand/json_type-inl.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { namespace ondemand { - inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept { - switch (type) { - case json_type::array: out << "array"; break; - case json_type::object: out << "object"; break; - case json_type::number: out << "number"; break; - case json_type::string: out << "string"; break; - case json_type::boolean: out << "boolean"; break; - case json_type::null: out << "null"; break; - default: SIMDJSON_UNREACHABLE(); - } - return out; - } - - inline std::ostream& operator<<(std::ostream& out, number_type type) noexcept { - switch (type) { - case number_type::signed_integer: out << "integer in [-9223372036854775808,9223372036854775808)"; break; - case number_type::unsigned_integer: out << "unsigned integer in [9223372036854775808,18446744073709551616)"; break; - case number_type::floating_point_number: out << "floating-point number (binary64)"; break; - default: SIMDJSON_UNREACHABLE(); - } - return out; - } -#if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false) { - return out << type.value(); - } -#endif - - - - simdjson_inline number_type number::get_number_type() const noexcept { - return type; - } - - simdjson_inline bool number::is_uint64() const noexcept { - return get_number_type() == number_type::unsigned_integer; - } - - simdjson_inline uint64_t number::get_uint64() const noexcept { - return payload.unsigned_integer; - } - - simdjson_inline number::operator uint64_t() const noexcept { - return get_uint64(); - } - - - simdjson_inline bool number::is_int64() const noexcept { - return get_number_type() == number_type::signed_integer; - } - - simdjson_inline int64_t number::get_int64() const noexcept { - return payload.signed_integer; - } - - simdjson_inline number::operator int64_t() const noexcept { - return get_int64(); - } - - simdjson_inline bool number::is_double() const noexcept { - return get_number_type() == number_type::floating_point_number; - } - - simdjson_inline double number::get_double() const noexcept { - return payload.floating_point_number; - } - - simdjson_inline number::operator double() const noexcept { - return get_double(); - } - - simdjson_inline double number::as_double() const noexcept { - if (is_double()) { - return payload.floating_point_number; - } - if (is_int64()) { - return double(payload.signed_integer); - } - return double(payload.unsigned_integer); - } - - simdjson_inline void number::append_s64(int64_t value) noexcept { - payload.signed_integer = value; - type = number_type::signed_integer; - } - - simdjson_inline void number::append_u64(uint64_t value) noexcept { - payload.unsigned_integer = value; - type = number_type::unsigned_integer; - } - - simdjson_inline void number::append_double(double value) noexcept { - payload.floating_point_number = value; - type = number_type::floating_point_number; - } - - simdjson_inline void number::skip_double() noexcept { - type = number_type::floating_point_number; - } - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_type&& value) noexcept - : implementation_simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base(error) {} - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/json_type-inl.h */ -/* begin file include/simdjson/generic/ondemand/logger-inl.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - namespace logger { - - static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; - static constexpr const int LOG_EVENT_LEN = 20; - static constexpr const int LOG_BUFFER_LEN = 30; - static constexpr const int LOG_SMALL_BUFFER_LEN = 10; - static int log_depth = 0; // Not threadsafe. Log only. - - // Helper to turn unprintable or newline characters into spaces - static inline char printable_char(char c) { - if (c >= 0x20) { - return c; - } - else { - return ' '; - } - } - - inline void log_event(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { - log_line(iter, "", type, detail, delta, depth_delta); - } - - inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { - log_line(iter, index, depth, "", type, detail); - } - inline void log_value(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { - log_line(iter, "", type, detail, delta, depth_delta); - } - - inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { - log_line(iter, index, depth, "+", type, detail); - if (LOG_ENABLED) { log_depth++; } - } - inline void log_start_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { - log_line(iter, "+", type, "", delta, depth_delta); - if (LOG_ENABLED) { log_depth++; } - } - - inline void log_end_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { - if (LOG_ENABLED) { log_depth--; } - log_line(iter, "-", type, "", delta, depth_delta); - } - - inline void log_error(const json_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { - log_line(iter, "ERROR: ", error, detail, delta, depth_delta); - } - inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail) noexcept { - log_line(iter, index, depth, "ERROR: ", error, detail); - } - - inline void log_event(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { - log_event(iter.json_iter(), type, detail, delta, depth_delta); - } - - inline void log_value(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { - log_value(iter.json_iter(), type, detail, delta, depth_delta); - } - - inline void log_start_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { - log_start_value(iter.json_iter(), type, delta, depth_delta); - } - - inline void log_end_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { - log_end_value(iter.json_iter(), type, delta, depth_delta); - } - - inline void log_error(const value_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { - log_error(iter.json_iter(), error, detail, delta, depth_delta); - } - - inline void log_headers() noexcept { - if (LOG_ENABLED) { - // Technically a static variable is not thread-safe, but if you are using threads - // and logging... well... - static bool displayed_hint{ false }; - log_depth = 0; - printf("\n"); - if (!displayed_hint) { - // We only print this helpful header once. - printf("# Logging provides the depth and position of the iterator user-visible steps:\n"); - printf("# +array says 'this is where we were when we discovered the start array'\n"); - printf("# -array says 'this is where we were when we ended the array'\n"); - printf("# skip says 'this is a structural or value I am skipping'\n"); - printf("# +/-skip says 'this is a start/end array or object I am skipping'\n"); - printf("#\n"); - printf("# The indentation of the terms (array, string,...) indicates the depth,\n"); - printf("# in addition to the depth being displayed.\n"); - printf("#\n"); - printf("# Every token in the document has a single depth determined by the tokens before it,\n"); - printf("# and is not affected by what the token actually is.\n"); - printf("#\n"); - printf("# Not all structural elements are presented as tokens in the logs.\n"); - printf("#\n"); - printf("# We never give control to the user within an empty array or an empty object.\n"); - printf("#\n"); - printf("# Inside an array, having a depth greater than the array's depth means that\n"); - printf("# we are pointing inside a value.\n"); - printf("# Having a depth equal to the array means that we are pointing right before a value.\n"); - printf("# Having a depth smaller than the array means that we have moved beyond the array.\n"); - displayed_hint = true; - } - printf("\n"); - printf("| %-*s ", LOG_EVENT_LEN, "Event"); - printf("| %-*s ", LOG_BUFFER_LEN, "Buffer"); - printf("| %-*s ", LOG_SMALL_BUFFER_LEN, "Next"); - // printf("| %-*s ", 5, "Next#"); - printf("| %-*s ", 5, "Depth"); - printf("| Detail "); - printf("|\n"); - - printf("|%.*s", LOG_EVENT_LEN + 2, DASHES); - printf("|%.*s", LOG_BUFFER_LEN + 2, DASHES); - printf("|%.*s", LOG_SMALL_BUFFER_LEN + 2, DASHES); - // printf("|%.*s", 5+2, DASHES); - printf("|%.*s", 5 + 2, DASHES); - printf("|--------"); - printf("|\n"); - fflush(stdout); - } - } - - inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta) noexcept { - log_line(iter, iter.position() + delta, depth_t(iter.depth() + depth_delta), title_prefix, title, detail); - } - inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail) noexcept { - if (LOG_ENABLED) { - const int indent = depth * 2; - const auto buf = iter.token.buf; - printf("| %*s%s%-*s ", - indent, "", - title_prefix, - LOG_EVENT_LEN - indent - int(strlen(title_prefix)), title - ); - { - // Print the current structural. - printf("| "); - // Before we begin, the index might point right before the document. - // This could be unsafe, see https://github.com/simdjson/simdjson/discussions/1938 - if (index < iter._root) { - printf("%*s", LOG_BUFFER_LEN, ""); - } - else { - auto current_structural = &buf[*index]; - for (int i = 0; i < LOG_BUFFER_LEN; i++) { - printf("%c", printable_char(current_structural[i])); - } - } - printf(" "); - } - { - // Print the next structural. - printf("| "); - auto next_structural = &buf[*(index + 1)]; - for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { - printf("%c", printable_char(next_structural[i])); - } - printf(" "); - } - // printf("| %5u ", *(index+1)); - printf("| %5i ", depth); - printf("| %6.*s ", int(detail.size()), detail.data()); - printf("|\n"); - fflush(stdout); - } - } - - } // namespace logger - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/logger-inl.h */ -/* begin file include/simdjson/generic/ondemand/raw_json_string-inl.h */ -namespace simdjson { - - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - simdjson_inline raw_json_string::raw_json_string(const uint8_t* _buf) noexcept : buf{ _buf } {} - - simdjson_inline const char* raw_json_string::raw() const noexcept { return reinterpret_cast(buf); } - - - simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(std::string_view target) noexcept { - size_t pos{ 0 }; - // if the content has no escape character, just scan through it quickly! - for (; pos < target.size() && target[pos] != '\\'; pos++) {} - // slow path may begin. - bool escaping{ false }; - for (; pos < target.size(); pos++) { - if ((target[pos] == '"') && !escaping) { - return false; - } - else if (target[pos] == '\\') { - escaping = !escaping; - } - else { - escaping = false; - } - } - return true; - } - - simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(const char* target) noexcept { - size_t pos{ 0 }; - // if the content has no escape character, just scan through it quickly! - for (; target[pos] && target[pos] != '\\'; pos++) {} - // slow path may begin. - bool escaping{ false }; - for (; target[pos]; pos++) { - if ((target[pos] == '"') && !escaping) { - return false; - } - else if (target[pos] == '\\') { - escaping = !escaping; - } - else { - escaping = false; - } - } - return true; - } - - - simdjson_inline bool raw_json_string::unsafe_is_equal(size_t length, std::string_view target) const noexcept { - // If we are going to call memcmp, then we must know something about the length of the raw_json_string. - return (length >= target.size()) && (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); - } - - simdjson_inline bool raw_json_string::unsafe_is_equal(std::string_view target) const noexcept { - // Assumptions: does not contain unescaped quote characters, and - // the raw content is quote terminated within a valid JSON string. - if (target.size() <= SIMDJSON_PADDING) { - return (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); - } - const char* r{ raw() }; - size_t pos{ 0 }; - for (; pos < target.size(); pos++) { - if (r[pos] != target[pos]) { return false; } - } - if (r[pos] != '"') { return false; } - return true; - } - - simdjson_inline bool raw_json_string::is_equal(std::string_view target) const noexcept { - const char* r{ raw() }; - size_t pos{ 0 }; - bool escaping{ false }; - for (; pos < target.size(); pos++) { - if (r[pos] != target[pos]) { return false; } - // if target is a compile-time constant and it is free from - // quotes, then the next part could get optimized away through - // inlining. - if ((target[pos] == '"') && !escaping) { - // We have reached the end of the raw_json_string but - // the target is not done. - return false; - } - else if (target[pos] == '\\') { - escaping = !escaping; - } - else { - escaping = false; - } - } - if (r[pos] != '"') { return false; } - return true; - } - - - simdjson_inline bool raw_json_string::unsafe_is_equal(const char* target) const noexcept { - // Assumptions: 'target' does not contain unescaped quote characters, is null terminated and - // the raw content is quote terminated within a valid JSON string. - const char* r{ raw() }; - size_t pos{ 0 }; - for (; target[pos]; pos++) { - if (r[pos] != target[pos]) { return false; } - } - if (r[pos] != '"') { return false; } - return true; - } - - simdjson_inline bool raw_json_string::is_equal(const char* target) const noexcept { - // Assumptions: does not contain unescaped quote characters, and - // the raw content is quote terminated within a valid JSON string. - const char* r{ raw() }; - size_t pos{ 0 }; - bool escaping{ false }; - for (; target[pos]; pos++) { - if (r[pos] != target[pos]) { return false; } - // if target is a compile-time constant and it is free from - // quotes, then the next part could get optimized away through - // inlining. - if ((target[pos] == '"') && !escaping) { - // We have reached the end of the raw_json_string but - // the target is not done. - return false; - } - else if (target[pos] == '\\') { - escaping = !escaping; - } - else { - escaping = false; - } - } - if (r[pos] != '"') { return false; } - return true; - } - - simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept { - return a.unsafe_is_equal(c); - } - - simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept { - return a == c; - } - - simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept { - return !(a == c); - } - - simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept { - return !(a == c); - } - - - simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape(json_iterator& iter, bool allow_replacement) const noexcept { - return iter.unescape(*this, allow_replacement); - } - - simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape_wobbly(json_iterator& iter) const noexcept { - return iter.unescape_wobbly(*this); - } - - simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream& out, const raw_json_string& str) noexcept { - bool in_escape = false; - const char* s = str.raw(); - while (true) { - switch (*s) { - case '\\': in_escape = !in_escape; break; - case '"': if (in_escape) { in_escape = false; } - else { return out; } break; - default: if (in_escape) { in_escape = false; } - } - out << *s; - s++; - } - } - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string&& value) noexcept - : implementation_simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base(error) {} - - simdjson_inline simdjson_result simdjson_result::raw() const noexcept { - if (error()) { return error(); } - return first.raw(); - } - simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_iterator& iter, bool allow_replacement) const noexcept { - if (error()) { return error(); } - return first.unescape(iter, allow_replacement); - } - simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape_wobbly(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_iterator& iter) const noexcept { - if (error()) { return error(); } - return first.unescape_wobbly(iter); - } -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/raw_json_string-inl.h */ -/* begin file include/simdjson/generic/ondemand/token_iterator-inl.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - simdjson_inline token_iterator::token_iterator( - const uint8_t* _buf, - token_position position - ) noexcept : buf{ _buf }, _position{ position } + // + // ### Live States + // + // While iterating or looking up values, depth >= iter->depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the array is first found and the iterator is just past the `{`. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the `,` before the next value (or `]`). In this state, + // depth == iter->depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter->depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter->depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the array iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet element may be missing or not be an + // array--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter->depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between elements, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter->depth == depth, and at_start == false. + // + // ## Terminal State + // + // The terminal state has iter->depth < depth. at_start is always false. + // + // - Finished: When we have reached a `]` or have reported an error, we are finished. We signal this + // by decrementing depth. In this state, iter->depth < depth, at_start == false, and + // error == SUCCESS. + // + + simdjson_inline array::array(const value_iterator& _iter) noexcept + : iter{ _iter } { } - simdjson_inline uint32_t token_iterator::current_offset() const noexcept { - return *(_position); + simdjson_inline simdjson_result array::start(value_iterator& iter) noexcept { + // We don't need to know if the array is empty to start iteration, but we do want to know if there + // is an error--thus `simdjson_unused`. + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::start_root(value_iterator& iter) noexcept { + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_root_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::started(value_iterator& iter) noexcept { + bool has_value; + SIMDJSON_TRY(iter.started_array().get(has_value)); + return array(iter); } - - simdjson_inline const uint8_t* token_iterator::return_current_and_advance() noexcept { - return &buf[*(_position++)]; + simdjson_inline simdjson_result array::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return array_iterator(iter); + } + simdjson_inline simdjson_result array::end() noexcept { + return array_iterator(iter); + } + simdjson_inline error_code array::consume() noexcept { + auto error = iter.json_iter().skip_child(iter.depth() - 1); + if (error) { iter.abandon(); } + return error; } - simdjson_inline const uint8_t* token_iterator::peek(token_position position) const noexcept { - return &buf[*position]; - } - simdjson_inline uint32_t token_iterator::peek_index(token_position position) const noexcept { - return *position; - } - simdjson_inline uint32_t token_iterator::peek_length(token_position position) const noexcept { - return *(position + 1) - *position; + simdjson_inline simdjson_result array::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter._json_iter->unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); } - simdjson_inline const uint8_t* token_iterator::peek(int32_t delta) const noexcept { - return &buf[*(_position + delta)]; + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline simdjson_result array::count_elements() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the array after counting the number of elements. + iter.reset_array(); + return count; } - simdjson_inline uint32_t token_iterator::peek_index(int32_t delta) const noexcept { - return *(_position + delta); - } - simdjson_inline uint32_t token_iterator::peek_length(int32_t delta) const noexcept { - return *(_position + delta + 1) - *(_position + delta); + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline simdjson_result array::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_array().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; } - simdjson_inline token_position token_iterator::position() const noexcept { - return _position; - } - simdjson_inline void token_iterator::set_position(token_position target_position) noexcept { - _position = target_position; + inline simdjson_result array::reset() & noexcept { + return iter.reset_array(); } - simdjson_inline bool token_iterator::operator==(const token_iterator& other) const noexcept { - return _position == other._position; + inline simdjson_result array::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + // - means "the append position" or "the element after the end of the array" + // We don't support this, because we're returning a real element, not a position. + if (json_pointer == "-") { return INDEX_OUT_OF_BOUNDS; } + + // Read the array index + size_t array_index = 0; + size_t i; + for (i = 0; i < json_pointer.length() && json_pointer[i] != '/'; i++) { + uint8_t digit = uint8_t(json_pointer[i] - '0'); + // Check for non-digit in array index. If it's there, we're trying to get a field in an object + if (digit > 9) { return INCORRECT_TYPE; } + array_index = array_index * 10 + digit; + } + + // 0 followed by other digits is invalid + if (i > 1 && json_pointer[0] == '0') { return INVALID_JSON_POINTER; } // "JSON pointer array index has other characters after 0" + + // Empty string is invalid; so is a "/" with no digits before it + if (i == 0) { return INVALID_JSON_POINTER; } // "Empty string in JSON pointer array index" + // Get the child + auto child = at(array_index); + // If there is an error, it ends here + if (child.error()) { + return child; + } + + // If there is a /, we're not done yet, call recursively. + if (i < json_pointer.length()) { + child = child.at_pointer(json_pointer.substr(i)); + } + return child; } - simdjson_inline bool token_iterator::operator!=(const token_iterator& other) const noexcept { - return _position != other._position; - } - simdjson_inline bool token_iterator::operator>(const token_iterator& other) const noexcept { - return _position > other._position; - } - simdjson_inline bool token_iterator::operator>=(const token_iterator& other) const noexcept { - return _position >= other._position; - } - simdjson_inline bool token_iterator::operator<(const token_iterator& other) const noexcept { - return _position < other._position; - } - simdjson_inline bool token_iterator::operator<=(const token_iterator& other) const noexcept { - return _position <= other._position; + + simdjson_inline simdjson_result array::at(size_t index) noexcept { + size_t i = 0; + for (auto value : *this) { + if (i == index) { return value; } + i++; + } + return INDEX_OUT_OF_BOUNDS; } } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::token_iterator&& value) noexcept - : implementation_simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base(error) {} + simdjson_inline simdjson_result::simdjson_result( + arm64::ondemand::array&& value + ) noexcept + : implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept + : implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::is_empty() & noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H +/* end file simdjson/generic/ondemand/array-inl.h for arm64 */ +/* including simdjson/generic/ondemand/array_iterator-inl.h for arm64: #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/array_iterator-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + simdjson_inline array_iterator::array_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result array_iterator::operator*() noexcept { + if (iter.error()) { iter.abandon(); return iter.error(); } + return value(iter.child()); + } + simdjson_inline bool array_iterator::operator==(const array_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool array_iterator::operator!=(const array_iterator&) const noexcept { + return iter.is_open(); + } + simdjson_inline array_iterator& array_iterator::operator++() noexcept { + error_code error; + // PERF NOTE this is a safety rail ... users should exit loops as soon as they receive an error, so we'll never get here. + // However, it does not seem to make a perf difference, so we add it out of an abundance of caution. + if ((error = iter.error())) { return *this; } + if ((error = iter.skip_child())) { return *this; } + if ((error = iter.has_next_element().error())) { return *this; } + return *this; + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + arm64::ondemand::array_iterator&& value + ) noexcept + : arm64::implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : arm64::implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++(first); + return *this; + } } // namespace simdjson -/* end file include/simdjson/generic/ondemand/token_iterator-inl.h */ -/* begin file include/simdjson/generic/ondemand/json_iterator-inl.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/array_iterator-inl.h for arm64 */ +/* including simdjson/generic/ondemand/document-inl.h for arm64: #include "simdjson/generic/ondemand/document-inl.h" */ +/* begin file simdjson/generic/ondemand/document-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { + namespace ondemand { + + simdjson_inline document::document(ondemand::json_iterator&& _iter) noexcept + : iter{ std::forward(_iter) } + { + logger::log_start_value(iter, "document"); + } + + simdjson_inline document document::start(json_iterator&& iter) noexcept { + return document(std::forward(iter)); + } + + inline void document::rewind() noexcept { + iter.rewind(); + } + + inline std::string document::to_debug_string() noexcept { + return iter.to_string(); + } + + inline simdjson_result document::current_location() const noexcept { + return iter.current_location(); + } + + inline int32_t document::current_depth() const noexcept { + return iter.depth(); + } + + inline bool document::at_end() const noexcept { + return iter.at_end(); + } + + + inline bool document::is_alive() noexcept { + return iter.is_alive(); + } + simdjson_inline value_iterator document::resume_value_iterator() noexcept { + return value_iterator(&iter, 1, iter.root_position()); + } + simdjson_inline value_iterator document::get_root_value_iterator() noexcept { + return resume_value_iterator(); + } + simdjson_inline simdjson_result document::start_or_resume_object() noexcept { + if (iter.at_root()) { + return get_object(); + } + else { + return object::resume(resume_value_iterator()); + } + } + simdjson_inline simdjson_result document::get_value() noexcept { + // Make sure we start any arrays or objects before returning, so that start_root_() + // gets called. + + // It is the convention throughout the code that the macro `SIMDJSON_DEVELOPMENT_CHECKS` determines whether + // we check for OUT_OF_ORDER_ITERATION. Proper on::demand code should never trigger this error. +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.at_root()) { return OUT_OF_ORDER_ITERATION; } +#endif + // assert_at_root() serves two purposes: in Debug mode, whether or not + // SIMDJSON_DEVELOPMENT_CHECKS is set or not, it checks that we are at the root of + // the document (this will typically be redundant). In release mode, it generates + // SIMDJSON_ASSUME statements to allow the compiler to make assumptions. + iter.assert_at_root(); + switch (*iter.peek()) { + case '[': { + // The following lines check that the document ends with ]. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_array(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + case '{': { + // The following lines would check that the document ends with }. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_object(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + default: + // Unfortunately, scalar documents are a special case in simdjson and they cannot + // be safely converted to value instances. + return SCALAR_DOCUMENT_AS_VALUE; + } + } + simdjson_inline simdjson_result document::get_array() & noexcept { + auto value = get_root_value_iterator(); + return array::start_root(value); + } + simdjson_inline simdjson_result document::get_object() & noexcept { + auto value = get_root_value_iterator(); + return object::start_root(value); + } + + /** + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. We want to disallow trailing + * content. + * Thus, in several implementations below, we pass a 'true' parameter value to + * a get_root_value_iterator() method: this indicates that we disallow trailing content. + */ + + simdjson_inline simdjson_result document::get_uint64() noexcept { + return get_root_value_iterator().get_root_uint64(true); + } + simdjson_inline simdjson_result document::get_uint64_in_string() noexcept { + return get_root_value_iterator().get_root_uint64_in_string(true); + } + simdjson_inline simdjson_result document::get_int64() noexcept { + return get_root_value_iterator().get_root_int64(true); + } + simdjson_inline simdjson_result document::get_int64_in_string() noexcept { + return get_root_value_iterator().get_root_int64_in_string(true); + } + simdjson_inline simdjson_result document::get_double() noexcept { + return get_root_value_iterator().get_root_double(true); + } + simdjson_inline simdjson_result document::get_double_in_string() noexcept { + return get_root_value_iterator().get_root_double_in_string(true); + } + simdjson_inline simdjson_result document::get_string(bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(true, allow_replacement); + } + template + simdjson_inline error_code document::get_string(string_type& receiver, bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(receiver, true, allow_replacement); + } + simdjson_inline simdjson_result document::get_wobbly_string() noexcept { + return get_root_value_iterator().get_root_wobbly_string(true); + } + simdjson_inline simdjson_result document::get_raw_json_string() noexcept { + return get_root_value_iterator().get_root_raw_json_string(true); + } + simdjson_inline simdjson_result document::get_bool() noexcept { + return get_root_value_iterator().get_root_bool(true); + } + simdjson_inline simdjson_result document::is_null() noexcept { + return get_root_value_iterator().is_root_null(true); + } + + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_array(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_object(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_double(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_bool(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_value(); } + + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_double(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_uint64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_int64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_bool(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_value(); } + + template simdjson_inline error_code document::get(T& out) & noexcept { + return get().get(out); + } + template simdjson_inline error_code document::get(T& out) && noexcept { + return std::forward(*this).get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document::operator array() & noexcept(false) { return get_array(); } + simdjson_inline document::operator object() & noexcept(false) { return get_object(); } + simdjson_inline document::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document::operator double() noexcept(false) { return get_double(); } + simdjson_inline document::operator std::string_view() noexcept(false) { return get_string(false); } + simdjson_inline document::operator raw_json_string() noexcept(false) { return get_raw_json_string(); } + simdjson_inline document::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document::operator value() noexcept(false) { return get_value(); } + +#endif + simdjson_inline simdjson_result document::count_elements() & noexcept { + auto a = get_array(); + simdjson_result answer = a.count_elements(); + /* If there was an array, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::count_fields() & noexcept { + auto a = get_object(); + simdjson_result answer = a.count_fields(); + /* If there was an object, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::at(size_t index) & noexcept { + auto a = get_array(); + return a.at(index); + } + simdjson_inline simdjson_result document::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result document::end() & noexcept { + return {}; + } + + simdjson_inline simdjson_result document::find_field(std::string_view key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field(const char* key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field_unordered(std::string_view key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::find_field_unordered(const char* key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::operator[](std::string_view key) & noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result document::operator[](const char* key) & noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline error_code document::consume() noexcept { + auto error = iter.skip_child(0); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result document::raw_json() noexcept { + auto _iter = get_root_value_iterator(); + const uint8_t* starting_point{ _iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter.unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result document::type() noexcept { + return get_root_value_iterator().type(); + } + + simdjson_inline simdjson_result document::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool document::is_negative() noexcept { + return get_root_value_iterator().is_root_negative(); + } + + simdjson_inline simdjson_result document::is_integer() noexcept { + return get_root_value_iterator().is_root_integer(true); + } + + simdjson_inline simdjson_result document::get_number_type() noexcept { + return get_root_value_iterator().get_root_number_type(true); + } + + simdjson_inline simdjson_result document::get_number() noexcept { + return get_root_value_iterator().get_root_number(true); + } + + + simdjson_inline simdjson_result document::raw_json_token() noexcept { + auto _iter = get_root_value_iterator(); + return std::string_view(reinterpret_cast(_iter.peek_start()), _iter.peek_start_length()); + } + + simdjson_inline simdjson_result document::at_pointer(std::string_view json_pointer) noexcept { + rewind(); // Rewind the document each time at_pointer is called + if (json_pointer.empty()) { + return this->get_value(); + } + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + arm64::ondemand::document&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base( + error + ) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template + simdjson_inline simdjson_result simdjson_result::get() & noexcept { + if (error()) { return error(); } + return first.get(); + } + template + simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first).get(); + } + template + simdjson_inline error_code simdjson_result::get(T& out) & noexcept { + if (error()) { return error(); } + return first.get(out); + } + template + simdjson_inline error_code simdjson_result::get(T& out) && noexcept { + if (error()) { return error(); } + return std::forward(first).get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() & noexcept = delete; + template<> simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first); + } + template<> simdjson_inline error_code simdjson_result::get(arm64::ondemand::document& out) & noexcept = delete; + template<> simdjson_inline error_code simdjson_result::get(arm64::ondemand::document& out) && noexcept { + if (error()) { return error(); } + out = std::forward(first); + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + + + simdjson_inline bool simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } + + +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator arm64::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline bool simdjson_result::at_end() const noexcept { + if (error()) { return error(); } + return first.at_end(); + } + + + simdjson_inline int32_t simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + simdjson_inline document_reference::document_reference() noexcept : doc{ nullptr } {} + simdjson_inline document_reference::document_reference(document& d) noexcept : doc(&d) {} + simdjson_inline void document_reference::rewind() noexcept { doc->rewind(); } + simdjson_inline simdjson_result document_reference::get_array() & noexcept { return doc->get_array(); } + simdjson_inline simdjson_result document_reference::get_object() & noexcept { return doc->get_object(); } + /** + * The document_reference instances are used primarily/solely for streams of JSON + * documents. + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. + * + * However, for streams of JSON documents, we want to be able to start from + * "321" "321" "321" + * and parse it successfully as a stream of JSON documents, calling get_uint64_in_string() + * successfully each time. + * + * To achieve this result, we pass a 'false' to a get_root_value_iterator() method: + * this indicates that we allow trailing content. + */ + simdjson_inline simdjson_result document_reference::get_uint64() noexcept { return doc->get_root_value_iterator().get_root_uint64(false); } + simdjson_inline simdjson_result document_reference::get_uint64_in_string() noexcept { return doc->get_root_value_iterator().get_root_uint64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_int64() noexcept { return doc->get_root_value_iterator().get_root_int64(false); } + simdjson_inline simdjson_result document_reference::get_int64_in_string() noexcept { return doc->get_root_value_iterator().get_root_int64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_double() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_double_in_string() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_string(bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(false, allow_replacement); } + template + simdjson_inline error_code document_reference::get_string(string_type& receiver, bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(receiver, false, allow_replacement); } + simdjson_inline simdjson_result document_reference::get_wobbly_string() noexcept { return doc->get_root_value_iterator().get_root_wobbly_string(false); } + simdjson_inline simdjson_result document_reference::get_raw_json_string() noexcept { return doc->get_root_value_iterator().get_root_raw_json_string(false); } + simdjson_inline simdjson_result document_reference::get_bool() noexcept { return doc->get_root_value_iterator().get_root_bool(false); } + simdjson_inline simdjson_result document_reference::get_value() noexcept { return doc->get_value(); } + simdjson_inline simdjson_result document_reference::is_null() noexcept { return doc->get_root_value_iterator().is_root_null(false); } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document_reference::operator array() & noexcept(false) { return array(*doc); } + simdjson_inline document_reference::operator object() & noexcept(false) { return object(*doc); } + simdjson_inline document_reference::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document_reference::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document_reference::operator double() noexcept(false) { return get_double(); } + simdjson_inline document_reference::operator std::string_view() noexcept(false) { return std::string_view(*doc); } + simdjson_inline document_reference::operator raw_json_string() noexcept(false) { return raw_json_string(*doc); } + simdjson_inline document_reference::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document_reference::operator value() noexcept(false) { return value(*doc); } +#endif + simdjson_inline simdjson_result document_reference::count_elements() & noexcept { return doc->count_elements(); } + simdjson_inline simdjson_result document_reference::count_fields() & noexcept { return doc->count_fields(); } + simdjson_inline simdjson_result document_reference::at(size_t index) & noexcept { return doc->at(index); } + simdjson_inline simdjson_result document_reference::begin() & noexcept { return doc->begin(); } + simdjson_inline simdjson_result document_reference::end() & noexcept { return doc->end(); } + simdjson_inline simdjson_result document_reference::find_field(std::string_view key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::find_field(const char* key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::operator[](std::string_view key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::operator[](const char* key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::find_field_unordered(std::string_view key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::find_field_unordered(const char* key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::type() noexcept { return doc->type(); } + simdjson_inline simdjson_result document_reference::is_scalar() noexcept { return doc->is_scalar(); } + simdjson_inline simdjson_result document_reference::current_location() noexcept { return doc->current_location(); } + simdjson_inline int32_t document_reference::current_depth() const noexcept { return doc->current_depth(); } + simdjson_inline bool document_reference::is_negative() noexcept { return doc->is_negative(); } + simdjson_inline simdjson_result document_reference::is_integer() noexcept { return doc->get_root_value_iterator().is_root_integer(false); } + simdjson_inline simdjson_result document_reference::get_number_type() noexcept { return doc->get_root_value_iterator().get_root_number_type(false); } + simdjson_inline simdjson_result document_reference::get_number() noexcept { return doc->get_root_value_iterator().get_root_number(false); } + simdjson_inline simdjson_result document_reference::raw_json_token() noexcept { return doc->raw_json_token(); } + simdjson_inline simdjson_result document_reference::at_pointer(std::string_view json_pointer) noexcept { return doc->at_pointer(json_pointer); } + simdjson_inline simdjson_result document_reference::raw_json() noexcept { return doc->raw_json(); } + simdjson_inline document_reference::operator document& () const noexcept { return *doc; } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + + + +namespace simdjson { + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::document_reference value, error_code error) + noexcept : implementation_simdjson_result_base(std::forward(value), error) {} + + + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator arm64::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H +/* end file simdjson/generic/ondemand/document-inl.h for arm64 */ +/* including simdjson/generic/ondemand/document_stream-inl.h for arm64: #include "simdjson/generic/ondemand/document_stream-inl.h" */ +/* begin file simdjson/generic/ondemand/document_stream-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace arm64 { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void stage1_worker::finish() { + // After calling "run" someone would call finish() to wait + // for the end of the processing. + // This function will wait until either the thread has done + // the processing or, else, the destructor has been called. + std::unique_lock lock(locking_mutex); + cond_var.wait(lock, [this] {return has_work == false; }); + } + + inline stage1_worker::~stage1_worker() { + // The thread may never outlive the stage1_worker instance + // and will always be stopped/joined before the stage1_worker + // instance is gone. + stop_thread(); + } + + inline void stage1_worker::start_thread() { + std::unique_lock lock(locking_mutex); + if (thread.joinable()) { + return; // This should never happen but we never want to create more than one thread. + } + thread = std::thread([this] { + while (true) { + std::unique_lock thread_lock(locking_mutex); + // We wait for either "run" or "stop_thread" to be called. + cond_var.wait(thread_lock, [this] {return has_work || !can_work; }); + // If, for some reason, the stop_thread() method was called (i.e., the + // destructor of stage1_worker is called, then we want to immediately destroy + // the thread (and not do any more processing). + if (!can_work) { + break; + } + this->owner->stage1_thread_error = this->owner->run_stage1(*this->stage1_thread_parser, + this->_next_batch_start); + this->has_work = false; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify "finish" + thread_lock.unlock(); + } + } + ); + } + + + inline void stage1_worker::stop_thread() { + std::unique_lock lock(locking_mutex); + // We have to make sure that all locks can be released. + can_work = false; + has_work = false; + cond_var.notify_all(); + lock.unlock(); + if (thread.joinable()) { + thread.join(); + } + } + + inline void stage1_worker::run(document_stream* ds, parser* stage1, size_t next_batch_start) { + std::unique_lock lock(locking_mutex); + owner = ds; + _next_batch_start = next_batch_start; + stage1_thread_parser = stage1; + has_work = true; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify the thread lock that we have work + lock.unlock(); + } + +#endif // SIMDJSON_THREADS_ENABLED + + simdjson_inline document_stream::document_stream( + ondemand::parser& _parser, + const uint8_t* _buf, + size_t _len, + size_t _batch_size, + bool _allow_comma_separated + ) noexcept + : parser{ &_parser }, + buf{ _buf }, + len{ _len }, + batch_size{ _batch_size <= MINIMAL_BATCH_SIZE ? MINIMAL_BATCH_SIZE : _batch_size }, + allow_comma_separated{ _allow_comma_separated }, + error{ SUCCESS } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(_parser.threaded) // we need to make a copy because _parser.threaded can change +#endif + { +#ifdef SIMDJSON_THREADS_ENABLED + if (worker.get() == nullptr) { + error = MEMALLOC; + } +#endif + } + + simdjson_inline document_stream::document_stream() noexcept + : parser{ nullptr }, + buf{ nullptr }, + len{ 0 }, + batch_size{ 0 }, + allow_comma_separated{ false }, + error{ UNINITIALIZED } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(false) +#endif + { + } + + simdjson_inline document_stream::~document_stream() noexcept + { +#ifdef SIMDJSON_THREADS_ENABLED + worker.reset(); +#endif + } + + inline size_t document_stream::size_in_bytes() const noexcept { + return len; + } + + inline size_t document_stream::truncated_bytes() const noexcept { + if (error == CAPACITY) { return len - batch_start; } + return parser->implementation->structural_indexes[parser->implementation->n_structural_indexes] - parser->implementation->structural_indexes[parser->implementation->n_structural_indexes + 1]; + } + + simdjson_inline document_stream::iterator::iterator() noexcept + : stream{ nullptr }, finished{ true } { + } + + simdjson_inline document_stream::iterator::iterator(document_stream* _stream, bool is_end) noexcept + : stream{ _stream }, finished{ is_end } { + } + + simdjson_inline simdjson_result document_stream::iterator::operator*() noexcept { + //if(stream->error) { return stream->error; } + return simdjson_result(stream->doc, stream->error); + } + + simdjson_inline document_stream::iterator& document_stream::iterator::operator++() noexcept { + // If there is an error, then we want the iterator + // to be finished, no matter what. (E.g., we do not + // keep generating documents with errors, or go beyond + // a document with errors.) + // + // Users do not have to call "operator*()" when they use operator++, + // so we need to end the stream in the operator++ function. + // + // Note that setting finished = true is essential otherwise + // we would enter an infinite loop. + if (stream->error) { finished = true; } + // Note that stream->error() is guarded against error conditions + // (it will immediately return if stream->error casts to false). + // In effect, this next function does nothing when (stream->error) + // is true (hence the risk of an infinite loop). + stream->next(); + // If that was the last document, we're finished. + // It is the only type of error we do not want to appear + // in operator*. + if (stream->error == EMPTY) { finished = true; } + // If we had any other kind of error (not EMPTY) then we want + // to pass it along to the operator* and we cannot mark the result + // as "finished" just yet. + return *this; + } + + simdjson_inline bool document_stream::iterator::operator!=(const document_stream::iterator& other) const noexcept { + return finished != other.finished; + } + + simdjson_inline document_stream::iterator document_stream::begin() noexcept { + start(); + // If there are no documents, we're finished. + return iterator(this, error == EMPTY); + } + + simdjson_inline document_stream::iterator document_stream::end() noexcept { + return iterator(this, true); + } + + inline void document_stream::start() noexcept { + if (error) { return; } + error = parser->allocate(batch_size); + if (error) { return; } + // Always run the first stage 1 parse immediately + batch_start = 0; + error = run_stage1(*parser, batch_start); + while (error == EMPTY) { + // In exceptional cases, we may start with an empty block + batch_start = next_batch_start(); + if (batch_start >= len) { return; } + error = run_stage1(*parser, batch_start); + } + if (error) { return; } + doc_index = batch_start; + doc = document(json_iterator(&buf[batch_start], parser)); + doc.iter._streaming = true; + +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread && next_batch_start() < len) { + // Kick off the first thread on next batch if needed + error = stage1_thread_parser.allocate(batch_size); + if (error) { return; } + worker->start_thread(); + start_stage1_thread(); + if (error) { return; } + } +#endif // SIMDJSON_THREADS_ENABLED + } + + inline void document_stream::next() noexcept { + // We always enter at once once in an error condition. + if (error) { return; } + next_document(); + if (error) { return; } + auto cur_struct_index = doc.iter._root - parser->implementation->structural_indexes.get(); + doc_index = batch_start + parser->implementation->structural_indexes[cur_struct_index]; + + // Check if at end of structural indexes (i.e. at end of batch) + if (cur_struct_index >= static_cast(parser->implementation->n_structural_indexes)) { + error = EMPTY; + // Load another batch (if available) + while (error == EMPTY) { + batch_start = next_batch_start(); + if (batch_start >= len) { break; } +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread) { + load_from_stage1_thread(); + } + else { + error = run_stage1(*parser, batch_start); + } +#else + error = run_stage1(*parser, batch_start); +#endif + /** + * Whenever we move to another window, we need to update all pointers to make + * it appear as if the input buffer started at the beginning of the window. + * + * Take this input: + * + * {"z":5} {"1":1,"2":2,"4":4} [7, 10, 9] [15, 11, 12, 13] [154, 110, 112, 1311] + * + * Say you process the following window... + * + * '{"z":5} {"1":1,"2":2,"4":4} [7, 10, 9]' + * + * When you do so, the json_iterator has a pointer at the beginning of the memory region + * (pointing at the beginning of '{"z"...'. + * + * When you move to the window that starts at... + * + * '[7, 10, 9] [15, 11, 12, 13] ... + * + * then it is not sufficient to just run stage 1. You also need to re-anchor the + * json_iterator so that it believes we are starting at '[7, 10, 9]...'. + * + * Under the DOM front-end, this gets done automatically because the parser owns + * the pointer the data, and when you call stage1 and then stage2 on the same + * parser, then stage2 will run on the pointer acquired by stage1. + * + * That is, stage1 calls "this->buf = _buf" so the parser remembers the buffer that + * we used. But json_iterator has no callback when stage1 is called on the parser. + * In fact, I think that the parser is unaware of json_iterator. + * + * + * So we need to re-anchor the json_iterator after each call to stage 1 so that + * all of the pointers are in sync. + */ + doc.iter = json_iterator(&buf[batch_start], parser); + doc.iter._streaming = true; + /** + * End of resync. + */ + + if (error) { continue; } // If the error was EMPTY, we may want to load another batch. + doc_index = batch_start; + } + } + } + + inline void document_stream::next_document() noexcept { + // Go to next place where depth=0 (document depth) + error = doc.iter.skip_child(0); + if (error) { return; } + // Always set depth=1 at the start of document + doc.iter._depth = 1; + // consume comma if comma separated is allowed + if (allow_comma_separated) { doc.iter.consume_character(','); } + // Resets the string buffer at the beginning, thus invalidating the strings. + doc.iter._string_buf_loc = parser->string_buf.get(); + doc.iter._root = doc.iter.position(); + } + + inline size_t document_stream::next_batch_start() const noexcept { + return batch_start + parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]; + } + + inline error_code document_stream::run_stage1(ondemand::parser& p, size_t _batch_start) noexcept { + // This code only updates the structural index in the parser, it does not update any json_iterator + // instance. + size_t remaining = len - _batch_start; + if (remaining <= batch_size) { + return p.implementation->stage1(&buf[_batch_start], remaining, stage1_mode::streaming_final); + } + else { + return p.implementation->stage1(&buf[_batch_start], batch_size, stage1_mode::streaming_partial); + } + } + + simdjson_inline size_t document_stream::iterator::current_index() const noexcept { + return stream->doc_index; + } + + simdjson_inline std::string_view document_stream::iterator::source() const noexcept { + auto depth = stream->doc.iter.depth(); + auto cur_struct_index = stream->doc.iter._root - stream->parser->implementation->structural_indexes.get(); + + // If at root, process the first token to determine if scalar value + if (stream->doc.iter.at_root()) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': // Depth=1 already at start of document + break; + case '}': case ']': + depth--; + break; + default: // Scalar value document + // TODO: Remove any trailing whitespaces + // This returns a string spanning from start of value to the beginning of the next document (excluded) + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[++cur_struct_index] - current_index() - 1); + } + cur_struct_index++; + } + + while (cur_struct_index <= static_cast(stream->parser->implementation->n_structural_indexes)) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': + depth++; + break; + case '}': case ']': + depth--; + break; + } + if (depth == 0) { break; } + cur_struct_index++; + } + + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[cur_struct_index] - current_index() + stream->batch_start + 1);; + } + + inline error_code document_stream::iterator::error() const noexcept { + return stream->error; + } + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void document_stream::load_from_stage1_thread() noexcept { + worker->finish(); + // Swap to the parser that was loaded up in the thread. Make sure the parser has + // enough memory to swap to, as well. + std::swap(stage1_thread_parser, *parser); + error = stage1_thread_error; + if (error) { return; } + + // If there's anything left, start the stage 1 thread! + if (next_batch_start() < len) { + start_stage1_thread(); + } + } + + inline void document_stream::start_stage1_thread() noexcept { + // we call the thread on a lambda that will update + // this->stage1_thread_error + // there is only one thread that may write to this value + // TODO this is NOT exception-safe. + this->stage1_thread_error = UNINITIALIZED; // In case something goes wrong, make sure it's an error + size_t _next_batch_start = this->next_batch_start(); + + worker->run(this, &this->stage1_thread_parser, _next_batch_start); + } + +#endif // SIMDJSON_THREADS_ENABLED + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result::simdjson_result( + arm64::ondemand::document_stream&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + +} + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H +/* end file simdjson/generic/ondemand/document_stream-inl.h for arm64 */ +/* including simdjson/generic/ondemand/field-inl.h for arm64: #include "simdjson/generic/ondemand/field-inl.h" */ +/* begin file simdjson/generic/ondemand/field-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + // clang 6 doesn't think the default constructor can be noexcept, so we make it explicit + simdjson_inline field::field() noexcept : std::pair() {} + + simdjson_inline field::field(raw_json_string key, ondemand::value&& value) noexcept + : std::pair(key, std::forward(value)) + { + } + + simdjson_inline simdjson_result field::start(value_iterator& parent_iter) noexcept { + raw_json_string key; + SIMDJSON_TRY(parent_iter.field_key().get(key)); + SIMDJSON_TRY(parent_iter.field_value()); + return field::start(parent_iter, key); + } + + simdjson_inline simdjson_result field::start(const value_iterator& parent_iter, raw_json_string key) noexcept { + return field(key, parent_iter.child()); + } + + simdjson_inline simdjson_warn_unused simdjson_result field::unescaped_key(bool allow_replacement) noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() but Visual Studio won't let us. + simdjson_result answer = first.unescape(second.iter.json_iter(), allow_replacement); + first.consume(); + return answer; + } + + simdjson_inline raw_json_string field::key() const noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() by Visual Studio won't let us. + return first; + } + + simdjson_inline value& field::value() & noexcept { + return second; + } + + simdjson_inline value field::value() && noexcept { + return std::forward(*this).second; + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + arm64::ondemand::field&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::key() noexcept { + if (error()) { return error(); } + return first.key(); + } + simdjson_inline simdjson_result simdjson_result::unescaped_key(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.unescaped_key(allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::value() noexcept { + if (error()) { return error(); } + return std::move(first.value()); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H +/* end file simdjson/generic/ondemand/field-inl.h for arm64 */ +/* including simdjson/generic/ondemand/json_iterator-inl.h for arm64: #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/json_iterator-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { namespace ondemand { simdjson_inline json_iterator::json_iterator(json_iterator&& other) noexcept @@ -28103,7 +33354,7 @@ namespace simdjson { + std::string(" ]"); } - inline simdjson_result json_iterator::current_location() noexcept { + inline simdjson_result json_iterator::current_location() const noexcept { if (!is_alive()) { // Unrecoverable error if (!at_root()) { return reinterpret_cast(token.peek(-1)); @@ -28136,7 +33387,7 @@ namespace simdjson { simdjson_inline const uint8_t* json_iterator::unsafe_pointer() const noexcept { // deliberately done without safety guard: - return token.peek(0); + return token.peek(); } simdjson_inline const uint8_t* json_iterator::peek(int32_t delta) const noexcept { @@ -28233,6 +33484,14 @@ namespace simdjson { _depth = child_depth; } + simdjson_inline error_code json_iterator::consume_character(char c) noexcept { + if (*peek() == c) { + return_current_and_advance(); + return SUCCESS; + } + return TAPE_ERROR; + } + #if SIMDJSON_DEVELOPMENT_CHECKS simdjson_inline token_position json_iterator::start_position(depth_t depth) const noexcept { @@ -28254,38 +33513,2024 @@ namespace simdjson { return _error; } - template - simdjson_warn_unused simdjson_inline bool json_iterator::copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t(&tmpbuf)[N]) noexcept { + + simdjson_warn_unused simdjson_inline bool json_iterator::copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept { + // This function is not expected to be called in performance-sensitive settings. // Let us guard against silly cases: if ((N < max_len) || (N == 0)) { return false; } - // Truncate whitespace to fit the buffer. - if (max_len > N - 1) { - // if (jsoncharutils::is_not_structural_or_whitespace(json[N-1])) { return false; } - max_len = N - 1; - } - // Copy to the buffer. std::memcpy(tmpbuf, json, max_len); - tmpbuf[max_len] = ' '; + if (N > max_len) { // We pad whatever remains with ' '. + std::memset(tmpbuf + max_len, ' ', N - max_len); + } return true; } } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_iterator&& value) noexcept - : implementation_simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base(error) {} + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::json_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} } // namespace simdjson -/* end file include/simdjson/generic/ondemand/json_iterator-inl.h */ -/* begin file include/simdjson/generic/ondemand/value_iterator-inl.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/json_iterator-inl.h for arm64 */ +/* including simdjson/generic/ondemand/json_type-inl.h for arm64: #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* begin file simdjson/generic/ondemand/json_type-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace arm64 { + namespace ondemand { + + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept { + switch (type) { + case json_type::array: out << "array"; break; + case json_type::object: out << "object"; break; + case json_type::number: out << "number"; break; + case json_type::string: out << "string"; break; + case json_type::boolean: out << "boolean"; break; + case json_type::null: out << "null"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false) { + return out << type.value(); + } +#endif + + + + simdjson_inline number_type number::get_number_type() const noexcept { + return type; + } + + simdjson_inline bool number::is_uint64() const noexcept { + return get_number_type() == number_type::unsigned_integer; + } + + simdjson_inline uint64_t number::get_uint64() const noexcept { + return payload.unsigned_integer; + } + + simdjson_inline number::operator uint64_t() const noexcept { + return get_uint64(); + } + + + simdjson_inline bool number::is_int64() const noexcept { + return get_number_type() == number_type::signed_integer; + } + + simdjson_inline int64_t number::get_int64() const noexcept { + return payload.signed_integer; + } + + simdjson_inline number::operator int64_t() const noexcept { + return get_int64(); + } + + simdjson_inline bool number::is_double() const noexcept { + return get_number_type() == number_type::floating_point_number; + } + + simdjson_inline double number::get_double() const noexcept { + return payload.floating_point_number; + } + + simdjson_inline number::operator double() const noexcept { + return get_double(); + } + + simdjson_inline double number::as_double() const noexcept { + if (is_double()) { + return payload.floating_point_number; + } + if (is_int64()) { + return double(payload.signed_integer); + } + return double(payload.unsigned_integer); + } + + simdjson_inline void number::append_s64(int64_t value) noexcept { + payload.signed_integer = value; + type = number_type::signed_integer; + } + + simdjson_inline void number::append_u64(uint64_t value) noexcept { + payload.unsigned_integer = value; + type = number_type::unsigned_integer; + } + + simdjson_inline void number::append_double(double value) noexcept { + payload.floating_point_number = value; + type = number_type::floating_point_number; + } + + simdjson_inline void number::skip_double() noexcept { + type = number_type::floating_point_number; + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::json_type&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H +/* end file simdjson/generic/ondemand/json_type-inl.h for arm64 */ +/* including simdjson/generic/ondemand/logger-inl.h for arm64: #include "simdjson/generic/ondemand/logger-inl.h" */ +/* begin file simdjson/generic/ondemand/logger-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace arm64 { + namespace ondemand { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static int log_depth = 0; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + template + static inline std::string string_format(const std::string& format, const Args&... args) + { + SIMDJSON_PUSH_DISABLE_ALL_WARNINGS + int size_s = std::snprintf(nullptr, 0, format.c_str(), args...) + 1; + auto size = static_cast(size_s); + if (size <= 0) return std::string(); + std::unique_ptr buf(new char[size]); + std::snprintf(buf.get(), size, format.c_str(), args...); + SIMDJSON_POP_DISABLE_WARNINGS + return std::string(buf.get(), buf.get() + size - 1); + } + + static inline log_level get_log_level_from_env() + { + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe + char* lvl = getenv("SIMDJSON_LOG_LEVEL"); + SIMDJSON_POP_DISABLE_WARNINGS + if (lvl && simdjson_strcasecmp(lvl, "ERROR") == 0) { return log_level::error; } + return log_level::info; + } + + static inline log_level log_threshold() + { + static log_level threshold = get_log_level_from_env(); + return threshold; + } + + static inline bool should_log(log_level level) + { + return level >= log_threshold(); + } + + inline void log_event(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "", type, detail, log_level::info); + } + inline void log_value(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "+", type, detail, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + inline void log_start_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_line(iter, "+", type, "", delta, depth_delta, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + + inline void log_end_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + if (LOG_ENABLED) { log_depth--; } + log_line(iter, "-", type, "", delta, depth_delta, log_level::info); + } + + inline void log_error(const json_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_line(iter, "ERROR: ", error, detail, delta, depth_delta, log_level::error); + } + inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail) noexcept { + log_line(iter, index, depth, "ERROR: ", error, detail, log_level::error); + } + + inline void log_event(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_event(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_value(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_value(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_start_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_start_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_end_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_end_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_error(const value_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_error(iter.json_iter(), error, detail, delta, depth_delta); + } + + inline void log_headers() noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(log_level::info))) { + // Technically a static variable is not thread-safe, but if you are using threads and logging... well... + static bool displayed_hint{ false }; + log_depth = 0; + printf("\n"); + if (!displayed_hint) { + // We only print this helpful header once. + printf("# Logging provides the depth and position of the iterator user-visible steps:\n"); + printf("# +array says 'this is where we were when we discovered the start array'\n"); + printf( + "# -array says 'this is where we were when we ended the array'\n"); + printf("# skip says 'this is a structural or value I am skipping'\n"); + printf("# +/-skip says 'this is a start/end array or object I am skipping'\n"); + printf("#\n"); + printf("# The indentation of the terms (array, string,...) indicates the depth,\n"); + printf("# in addition to the depth being displayed.\n"); + printf("#\n"); + printf("# Every token in the document has a single depth determined by the tokens before it,\n"); + printf("# and is not affected by what the token actually is.\n"); + printf("#\n"); + printf("# Not all structural elements are presented as tokens in the logs.\n"); + printf("#\n"); + printf("# We never give control to the user within an empty array or an empty object.\n"); + printf("#\n"); + printf("# Inside an array, having a depth greater than the array's depth means that\n"); + printf("# we are pointing inside a value.\n"); + printf("# Having a depth equal to the array means that we are pointing right before a value.\n"); + printf("# Having a depth smaller than the array means that we have moved beyond the array.\n"); + displayed_hint = true; + } + printf("\n"); + printf("| %-*s ", LOG_EVENT_LEN, "Event"); + printf("| %-*s ", LOG_BUFFER_LEN, "Buffer"); + printf("| %-*s ", LOG_SMALL_BUFFER_LEN, "Next"); + // printf("| %-*s ", 5, "Next#"); + printf("| %-*s ", 5, "Depth"); + printf("| Detail "); + printf("|\n"); + + printf("|%.*s", LOG_EVENT_LEN + 2, DASHES); + printf("|%.*s", LOG_BUFFER_LEN + 2, DASHES); + printf("|%.*s", LOG_SMALL_BUFFER_LEN + 2, DASHES); + // printf("|%.*s", 5+2, DASHES); + printf("|%.*s", 5 + 2, DASHES); + printf("|--------"); + printf("|\n"); + fflush(stdout); + } + } + } + + template + inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, log_level level, Args&&... args) noexcept { + log_line(iter, iter.position() + delta, depth_t(iter.depth() + depth_delta), title_prefix, title, detail, level, std::forward(args)...); + } + + template + inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, log_level level, Args&&... args) noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(level))) { + const int indent = depth * 2; + const auto buf = iter.token.buf; + auto msg = string_format(title, std::forward(args)...); + printf("| %*s%s%-*s ", indent, "", title_prefix, + LOG_EVENT_LEN - indent - int(strlen(title_prefix)), msg.c_str()); + { + // Print the current structural. + printf("| "); + // Before we begin, the index might point right before the document. + // This could be unsafe, see https://github.com/simdjson/simdjson/discussions/1938 + if (index < iter._root) { + printf("%*s", LOG_BUFFER_LEN, ""); + } + else { + auto current_structural = &buf[*index]; + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current_structural[i])); + } + } + printf(" "); + } + { + // Print the next structural. + printf("| "); + auto next_structural = &buf[*(index + 1)]; + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next_structural[i])); + } + printf(" "); + } + // printf("| %5u ", *(index+1)); + printf("| %5i ", depth); + printf("| %6.*s ", int(detail.size()), detail.data()); + printf("|\n"); + fflush(stdout); + } + } + } + + } // namespace logger + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H +/* end file simdjson/generic/ondemand/logger-inl.h for arm64 */ +/* including simdjson/generic/ondemand/object-inl.h for arm64: #include "simdjson/generic/ondemand/object-inl.h" */ +/* begin file simdjson/generic/ondemand/object-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) & noexcept { + return find_field_unordered(key); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) && noexcept { + return std::forward(*this).find_field_unordered(key); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + + simdjson_inline simdjson_result object::start(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_object().error()); + return object(iter); + } + simdjson_inline simdjson_result object::start_root(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_root_object().error()); + return object(iter); + } + simdjson_inline error_code object::consume() noexcept { + if (iter.is_at_key()) { + /** + * whenever you are pointing at a key, calling skip_child() is + * unsafe because you will hit a string and you will assume that + * it is string value, and this mistake will lead you to make bad + * depth computation. + */ + /** + * We want to 'consume' the key. We could really + * just do _json_iter->return_current_and_advance(); at this + * point, but, for clarity, we will use the high-level API to + * eat the key. We assume that the compiler optimizes away + * most of the work. + */ + simdjson_unused raw_json_string actual_key; + auto error = iter.field_key().get(actual_key); + if (error) { iter.abandon(); return error; }; + // Let us move to the value while we are at it. + if ((error = iter.field_value())) { iter.abandon(); return error; } + } + auto error_skip = iter.json_iter().skip_child(iter.depth() - 1); + if (error_skip) { iter.abandon(); } + return error_skip; + } + + simdjson_inline simdjson_result object::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + const uint8_t* final_point{ iter._json_iter->peek() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result object::started(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.started_object().error()); + return object(iter); + } + + simdjson_inline object object::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline object::object(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result object::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return object_iterator(iter); + } + simdjson_inline simdjson_result object::end() noexcept { + return object_iterator(iter); + } + + inline simdjson_result object::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + size_t slash = json_pointer.find('/'); + std::string_view key = json_pointer.substr(0, slash); + // Grab the child with the given key + simdjson_result child; + + // If there is an escape character in the key, unescape it and then get the child. + size_t escape = key.find('~'); + if (escape != std::string_view::npos) { + // Unescape the key + std::string unescaped(key); + do { + switch (unescaped[escape + 1]) { + case '0': + unescaped.replace(escape, 2, "~"); + break; + case '1': + unescaped.replace(escape, 2, "/"); + break; + default: + return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); + } + escape = unescaped.find('~', escape + 1); + } while (escape != std::string::npos); + child = find_field(unescaped); // Take note find_field does not unescape keys when matching + } + else { + child = find_field(key); + } + if (child.error()) { + return child; // we do not continue if there was an error + } + // If there is a /, we have to recurse and look up more of the path + if (slash != std::string_view::npos) { + child = child.at_pointer(json_pointer.substr(slash)); + } + return child; + } + + simdjson_inline simdjson_result object::count_fields() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the object after counting the number of elements. + iter.reset_object(); + return count; + } + + simdjson_inline simdjson_result object::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_object().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + simdjson_inline simdjson_result object::reset() & noexcept { + return iter.reset_object(); + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::object&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first)[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + inline simdjson_result simdjson_result::reset() noexcept { + if (error()) { return error(); } + return first.reset(); + } + + inline simdjson_result simdjson_result::is_empty() noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H +/* end file simdjson/generic/ondemand/object-inl.h for arm64 */ +/* including simdjson/generic/ondemand/object_iterator-inl.h for arm64: #include "simdjson/generic/ondemand/object_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/object_iterator-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + // + // object_iterator + // + + simdjson_inline object_iterator::object_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result object_iterator::operator*() noexcept { + error_code error = iter.error(); + if (error) { iter.abandon(); return error; } + auto result = field::start(iter); + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (result.error()) { iter.abandon(); } + return result; + } + simdjson_inline bool object_iterator::operator==(const object_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool object_iterator::operator!=(const object_iterator&) const noexcept { + return iter.is_open(); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline object_iterator& object_iterator::operator++() noexcept { + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (!iter.is_open()) { return *this; } // Iterator will be released if there is an error + + simdjson_unused error_code error; + if ((error = iter.skip_child())) { return *this; } + + simdjson_unused bool has_value; + if ((error = iter.has_next_field().get(has_value))) { return *this; }; + return *this; + } + SIMDJSON_POP_DISABLE_WARNINGS + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter.depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the object is first found and the iterator is just past the {. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the , or } before the next value. In this state, + // depth == iter.depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter.depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter.depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the object iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet field may be missing or not be an + // object--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter.depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between fields, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter.depth == depth, and at_start == false. + // + // Errors that occur while reading a field to give to the user (such as when the key is not a + // string or the field is missing a colon) are yielded immediately. Depth is then decremented, + // moving to the Finished state without transitioning through an Error state at all. + // + // ## Terminal State + // + // The terminal state has iter.depth < depth. at_start is always false. + // + // - Finished: When we have reached a }, we are finished. We signal this by decrementing depth. + // In this state, iter.depth < depth, at_start == false, and error == SUCCESS. + // + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + arm64::ondemand::object_iterator&& value + ) noexcept + : implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + // Checks for ']' and ',' + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++first; + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/object_iterator-inl.h for arm64 */ +/* including simdjson/generic/ondemand/parser-inl.h for arm64: #include "simdjson/generic/ondemand/parser-inl.h" */ +/* begin file simdjson/generic/ondemand/parser-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string_view.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/dom/base.h" // for MINIMAL_DOCUMENT_CAPACITY */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + simdjson_inline parser::parser(size_t max_capacity) noexcept + : _max_capacity{ max_capacity } { + } + + simdjson_warn_unused simdjson_inline error_code parser::allocate(size_t new_capacity, size_t new_max_depth) noexcept { + if (new_capacity > max_capacity()) { return CAPACITY; } + if (string_buf && new_capacity == capacity() && new_max_depth == max_depth()) { return SUCCESS; } + + // string_capacity copied from document::allocate + _capacity = 0; + size_t string_capacity = SIMDJSON_ROUNDUP_N(5 * new_capacity / 3 + SIMDJSON_PADDING, 64); + string_buf.reset(new (std::nothrow) uint8_t[string_capacity]); +#if SIMDJSON_DEVELOPMENT_CHECKS + start_positions.reset(new (std::nothrow) token_position[new_max_depth]); +#endif + if (implementation) { + SIMDJSON_TRY(implementation->set_capacity(new_capacity)); + SIMDJSON_TRY(implementation->set_max_depth(new_max_depth)); + } + else { + SIMDJSON_TRY(simdjson::get_active_implementation()->create_dom_parser_implementation(new_capacity, new_max_depth, implementation)); + } + _capacity = new_capacity; + _max_depth = new_max_depth; + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length() || !string_buf) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return document::start({ reinterpret_cast(json.data()), this }); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const char* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const uint8_t* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string_view json, size_t allocated) & noexcept { + return iterate(padded_string_view(json, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string& json) & noexcept { + if (json.capacity() - json.size() < SIMDJSON_PADDING) { + json.reserve(json.size() + SIMDJSON_PADDING); + } + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const std::string& json) & noexcept { + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + padded_string_view json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + const padded_string& json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate_raw(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length()) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return json_iterator(reinterpret_cast(json.data()), this); + } + + inline simdjson_result parser::iterate_many(const uint8_t* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + if (allow_comma_separated && batch_size < len) { batch_size = len; } + return document_stream(*this, buf, len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const char* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(reinterpret_cast(buf), len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const std::string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const padded_string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + + simdjson_inline size_t parser::capacity() const noexcept { + return _capacity; + } + simdjson_inline size_t parser::max_capacity() const noexcept { + return _max_capacity; + } + simdjson_inline size_t parser::max_depth() const noexcept { + return _max_depth; + } + + simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { + if (max_capacity < dom::MINIMAL_DOCUMENT_CAPACITY) { + _max_capacity = max_capacity; + } + else { + _max_capacity = dom::MINIMAL_DOCUMENT_CAPACITY; + } + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement) const noexcept { + uint8_t* end = implementation->parse_string(in.buf, dst, allow_replacement); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept { + uint8_t* end = implementation->parse_wobbly_string(in.buf, dst); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::parser&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H +/* end file simdjson/generic/ondemand/parser-inl.h for arm64 */ +/* including simdjson/generic/ondemand/raw_json_string-inl.h for arm64: #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + namespace arm64 { + namespace ondemand { + + simdjson_inline raw_json_string::raw_json_string(const uint8_t* _buf) noexcept : buf{ _buf } {} + + simdjson_inline const char* raw_json_string::raw() const noexcept { return reinterpret_cast(buf); } + + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(std::string_view target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; pos < target.size() && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(const char* target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; target[pos] && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; target[pos]; pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(size_t length, std::string_view target) const noexcept { + // If we are going to call memcmp, then we must know something about the length of the raw_json_string. + return (length >= target.size()) && (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + + simdjson_inline bool raw_json_string::unsafe_is_equal(std::string_view target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + if (target.size() <= SIMDJSON_PADDING) { + return (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + const char* r{ raw() }; + size_t pos{ 0 }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(std::string_view target) const noexcept { + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(const char* target) const noexcept { + // Assumptions: 'target' does not contain unescaped quote characters, is null terminated and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(const char* target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept { + return a.unsafe_is_equal(c); + } + + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept { + return a == c; + } + + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept { + return !(a == c); + } + + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept { + return !(a == c); + } + + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape(json_iterator& iter, bool allow_replacement) const noexcept { + return iter.unescape(*this, allow_replacement); + } + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape_wobbly(json_iterator& iter) const noexcept { + return iter.unescape_wobbly(*this); + } + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream& out, const raw_json_string& str) noexcept { + bool in_escape = false; + const char* s = str.raw(); + while (true) { + switch (*s) { + case '\\': in_escape = !in_escape; break; + case '"': if (in_escape) { in_escape = false; } + else { return out; } break; + default: if (in_escape) { in_escape = false; } + } + out << *s; + s++; + } + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::raw_json_string&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::raw() const noexcept { + if (error()) { return error(); } + return first.raw(); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape(arm64::ondemand::json_iterator& iter, bool allow_replacement) const noexcept { + if (error()) { return error(); } + return first.unescape(iter, allow_replacement); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape_wobbly(arm64::ondemand::json_iterator& iter) const noexcept { + if (error()) { return error(); } + return first.unescape_wobbly(iter); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H +/* end file simdjson/generic/ondemand/raw_json_string-inl.h for arm64 */ +/* including simdjson/generic/ondemand/serialization-inl.h for arm64: #include "simdjson/generic/ondemand/serialization-inl.h" */ +/* begin file simdjson/generic/ondemand/serialization-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/serialization.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + inline std::string_view trim(const std::string_view str) noexcept { + // We can almost surely do better by rolling our own find_first_not_of function. + size_t first = str.find_first_not_of(" \t\n\r"); + // If we have the empty string (just white space), then no trimming is possible, and + // we return the empty string_view. + if (std::string_view::npos == first) { return std::string_view(); } + size_t last = str.find_last_not_of(" \t\n\r"); + return str.substr(first, (last - first + 1)); + } + + + inline simdjson_result to_json_string(arm64::ondemand::document& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(arm64::ondemand::document_reference& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(arm64::ondemand::value& x) noexcept { + /** + * If we somehow receive a value that has already been consumed, + * then the following code could be in trouble. E.g., we create + * an array as needed, but if an array was already created, then + * it could be bad. + */ + using namespace arm64::ondemand; + arm64::ondemand::json_type t; + auto error = x.type().get(t); + if (error != SUCCESS) { return error; } + switch (t) + { + case json_type::array: + { + arm64::ondemand::array array; + error = x.get_array().get(array); + if (error) { return error; } + return to_json_string(array); + } + case json_type::object: + { + arm64::ondemand::object object; + error = x.get_object().get(object); + if (error) { return error; } + return to_json_string(object); + } + default: + return trim(x.raw_json_token()); + } + } + + inline simdjson_result to_json_string(arm64::ondemand::object& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(arm64::ondemand::array& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } +} // namespace simdjson + +namespace simdjson { + namespace arm64 { + namespace ondemand { + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::document_reference& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::arm64::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + } + } +} // namespace simdjson::arm64::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H +/* end file simdjson/generic/ondemand/serialization-inl.h for arm64 */ +/* including simdjson/generic/ondemand/token_iterator-inl.h for arm64: #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/token_iterator-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + simdjson_inline token_iterator::token_iterator( + const uint8_t* _buf, + token_position position + ) noexcept : buf{ _buf }, _position{ position } + { + } + + simdjson_inline uint32_t token_iterator::current_offset() const noexcept { + return *(_position); + } + + + simdjson_inline const uint8_t* token_iterator::return_current_and_advance() noexcept { + return &buf[*(_position++)]; + } + + simdjson_inline const uint8_t* token_iterator::peek(token_position position) const noexcept { + return &buf[*position]; + } + simdjson_inline uint32_t token_iterator::peek_index(token_position position) const noexcept { + return *position; + } + simdjson_inline uint32_t token_iterator::peek_length(token_position position) const noexcept { + return *(position + 1) - *position; + } + + simdjson_inline const uint8_t* token_iterator::peek(int32_t delta) const noexcept { + return &buf[*(_position + delta)]; + } + simdjson_inline uint32_t token_iterator::peek_index(int32_t delta) const noexcept { + return *(_position + delta); + } + simdjson_inline uint32_t token_iterator::peek_length(int32_t delta) const noexcept { + return *(_position + delta + 1) - *(_position + delta); + } + + simdjson_inline token_position token_iterator::position() const noexcept { + return _position; + } + simdjson_inline void token_iterator::set_position(token_position target_position) noexcept { + _position = target_position; + } + + simdjson_inline bool token_iterator::operator==(const token_iterator& other) const noexcept { + return _position == other._position; + } + simdjson_inline bool token_iterator::operator!=(const token_iterator& other) const noexcept { + return _position != other._position; + } + simdjson_inline bool token_iterator::operator>(const token_iterator& other) const noexcept { + return _position > other._position; + } + simdjson_inline bool token_iterator::operator>=(const token_iterator& other) const noexcept { + return _position >= other._position; + } + simdjson_inline bool token_iterator::operator<(const token_iterator& other) const noexcept { + return _position < other._position; + } + simdjson_inline bool token_iterator::operator<=(const token_iterator& other) const noexcept { + return _position <= other._position; + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::token_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/token_iterator-inl.h for arm64 */ +/* including simdjson/generic/ondemand/value-inl.h for arm64: #include "simdjson/generic/ondemand/value-inl.h" */ +/* begin file simdjson/generic/ondemand/value-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { + namespace ondemand { + + simdjson_inline value::value(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + simdjson_inline value value::start(const value_iterator& iter) noexcept { + return iter; + } + simdjson_inline value value::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline simdjson_result value::get_array() noexcept { + return array::start(iter); + } + simdjson_inline simdjson_result value::get_object() noexcept { + return object::start(iter); + } + simdjson_inline simdjson_result value::start_or_resume_object() noexcept { + if (iter.at_start()) { + return get_object(); + } + else { + return object::resume(iter); + } + } + + simdjson_inline simdjson_result value::get_raw_json_string() noexcept { + return iter.get_raw_json_string(); + } + simdjson_inline simdjson_result value::get_string(bool allow_replacement) noexcept { + return iter.get_string(allow_replacement); + } + template + simdjson_inline error_code value::get_string(string_type& receiver, bool allow_replacement) noexcept { + return iter.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result value::get_wobbly_string() noexcept { + return iter.get_wobbly_string(); + } + simdjson_inline simdjson_result value::get_double() noexcept { + return iter.get_double(); + } + simdjson_inline simdjson_result value::get_double_in_string() noexcept { + return iter.get_double_in_string(); + } + simdjson_inline simdjson_result value::get_uint64() noexcept { + return iter.get_uint64(); + } + simdjson_inline simdjson_result value::get_uint64_in_string() noexcept { + return iter.get_uint64_in_string(); + } + simdjson_inline simdjson_result value::get_int64() noexcept { + return iter.get_int64(); + } + simdjson_inline simdjson_result value::get_int64_in_string() noexcept { + return iter.get_int64_in_string(); + } + simdjson_inline simdjson_result value::get_bool() noexcept { + return iter.get_bool(); + } + simdjson_inline simdjson_result value::is_null() noexcept { + return iter.is_null(); + } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_array(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_object(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_number(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_double(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_bool(); } + + template simdjson_inline error_code value::get(T& out) noexcept { + return get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline value::operator array() noexcept(false) { + return get_array(); + } + simdjson_inline value::operator object() noexcept(false) { + return get_object(); + } + simdjson_inline value::operator uint64_t() noexcept(false) { + return get_uint64(); + } + simdjson_inline value::operator int64_t() noexcept(false) { + return get_int64(); + } + simdjson_inline value::operator double() noexcept(false) { + return get_double(); + } + simdjson_inline value::operator std::string_view() noexcept(false) { + return get_string(false); + } + simdjson_inline value::operator raw_json_string() noexcept(false) { + return get_raw_json_string(); + } + simdjson_inline value::operator bool() noexcept(false) { + return get_bool(); + } +#endif + + simdjson_inline simdjson_result value::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result value::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result value::count_elements() & noexcept { + simdjson_result answer; + auto a = get_array(); + answer = a.count_elements(); + // count_elements leaves you pointing inside the array, at the first element. + // We need to move back so that the user can create a new array (which requires that + // we point at '['). + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::count_fields() & noexcept { + simdjson_result answer; + auto a = get_object(); + answer = a.count_fields(); + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::at(size_t index) noexcept { + auto a = get_array(); + return a.at(index); + } + + simdjson_inline simdjson_result value::find_field(std::string_view key) noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result value::find_field(const char* key) noexcept { + return start_or_resume_object().find_field(key); + } + + simdjson_inline simdjson_result value::find_field_unordered(std::string_view key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result value::find_field_unordered(const char* key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + + simdjson_inline simdjson_result value::operator[](std::string_view key) noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result value::operator[](const char* key) noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline simdjson_result value::type() noexcept { + return iter.type(); + } + + simdjson_inline simdjson_result value::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool value::is_negative() noexcept { + return iter.is_negative(); + } + + simdjson_inline simdjson_result value::is_integer() noexcept { + return iter.is_integer(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number_type() noexcept { + return iter.get_number_type(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number() noexcept { + return iter.get_number(); + } + + simdjson_inline std::string_view value::raw_json_token() noexcept { + return std::string_view(reinterpret_cast(iter.peek_start()), iter.peek_start_length()); + } + + simdjson_inline simdjson_result value::raw_json() noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: { + ondemand::array array; + SIMDJSON_TRY(get_array().get(array)); + return array.raw_json(); + } + case json_type::object: { + ondemand::object object; + SIMDJSON_TRY(get_object().get(object)); + return object.raw_json(); + } + default: + return raw_json_token(); + } + } + + simdjson_inline simdjson_result value::current_location() noexcept { + return iter.json_iter().current_location(); + } + + simdjson_inline int32_t value::current_depth() const noexcept { + return iter.json_iter().depth(); + } + + simdjson_inline simdjson_result value::at_pointer(std::string_view json_pointer) noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace arm64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + arm64::ondemand::value&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + if (error()) { return error(); } + return {}; + } + + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) noexcept { + if (error()) { return error(); } + return first[key]; + } + + simdjson_inline simdjson_result simdjson_result::get_array() noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return first.get(); + } + template simdjson_inline error_code simdjson_result::get(T& out) noexcept { + if (error()) { return error(); } + return first.get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return std::move(first); + } + template<> simdjson_inline error_code simdjson_result::get(arm64::ondemand::value& out) noexcept { + if (error()) { return error(); } + out = first; + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator arm64::ondemand::array() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::object() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator arm64::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H +/* end file simdjson/generic/ondemand/value-inl.h for arm64 */ +/* including simdjson/generic/ondemand/value_iterator-inl.h for arm64: #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/value_iterator-inl.h for arm64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/atomparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace arm64 { namespace ondemand { simdjson_inline value_iterator::value_iterator( @@ -28320,12 +35565,17 @@ namespace simdjson { return true; } - simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_object() noexcept { + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_object() noexcept { // When in streaming mode, we cannot expect peek_last() to be the last structural element of the // current document. It only works in the normal mode where we have indexed a single document. // Note that adding a check for 'streaming' is not expensive since we only have at most // one root element. if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // object: e.g., `{"a":2} foo }`. Users concerned with garbage content should + // call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // if (*_json_iter->peek_last() != '}') { _json_iter->abandon(); return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing } at end"); @@ -28342,6 +35592,12 @@ namespace simdjson { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); } } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_object() noexcept { + auto error = check_root_object(); + if (error) { return error; } return started_object(); } @@ -28709,12 +35965,17 @@ namespace simdjson { return true; } - simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_array() noexcept { + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_array() noexcept { // When in streaming mode, we cannot expect peek_last() to be the last structural element of the // current document. It only works in the normal mode where we have indexed a single document. // Note that adding a check for 'streaming' is not expensive since we only have at most // one root element. if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // array: e.g., `[1, 2] foo]`. Users concerned with garbage content should + // also call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // if (*_json_iter->peek_last() != ']') { _json_iter->abandon(); return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing ] at end"); @@ -28731,6 +35992,12 @@ namespace simdjson { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); } } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_array() noexcept { + auto error = check_root_array(); + if (error) { return error; } return started_array(); } @@ -28768,6 +36035,14 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_string(bool allow_replacement) noexcept { return get_raw_json_string().unescape(json_iter(), allow_replacement); } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_string(string_type& receiver, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_string(allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_wobbly_string() noexcept { return get_raw_json_string().unescape_wobbly(json_iter()); } @@ -28840,8 +36115,9 @@ namespace simdjson { simdjson_inline simdjson_result value_iterator::is_root_integer(bool check_trailing) noexcept { auto max_len = peek_start_length(); auto json = peek_root_scalar("is_root_integer"); - uint8_t tmpbuf[20 + 1]; // <20 digits> is the longest possible unsigned integer - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { return false; // if there are more than 20 characters, it cannot be represented as an integer. } auto answer = numberparsing::is_integer(tmpbuf); @@ -28852,14 +36128,15 @@ namespace simdjson { return answer; } - simdjson_inline simdjson_result value_iterator::get_root_number_type(bool check_trailing) noexcept { + simdjson_inline simdjson_result value_iterator::get_root_number_type(bool check_trailing) noexcept { auto max_len = peek_start_length(); auto json = peek_root_scalar("number"); // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest // number: -0.e-308. - uint8_t tmpbuf[1074 + 8 + 1]; - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); return NUMBER_ERROR; } @@ -28873,8 +36150,9 @@ namespace simdjson { // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest // number: -0.e-308. - uint8_t tmpbuf[1074 + 8 + 1]; - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); return NUMBER_ERROR; } @@ -28888,6 +36166,14 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_string(bool check_trailing, bool allow_replacement) noexcept { return get_root_raw_json_string(check_trailing).unescape(json_iter(), allow_replacement); } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_root_string(check_trailing, allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_wobbly_string(bool check_trailing) noexcept { return get_root_raw_json_string(check_trailing).unescape_wobbly(json_iter()); } @@ -28901,8 +36187,9 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64(bool check_trailing) noexcept { auto max_len = peek_start_length(); auto json = peek_root_scalar("uint64"); - uint8_t tmpbuf[20 + 1]; // <20 digits> is the longest possible unsigned integer - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); return NUMBER_ERROR; } @@ -28916,8 +36203,9 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64_in_string(bool check_trailing) noexcept { auto max_len = peek_start_length(); auto json = peek_root_scalar("uint64"); - uint8_t tmpbuf[20 + 1]; // <20 digits> is the longest possible unsigned integer - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); return NUMBER_ERROR; } @@ -28931,8 +36219,9 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64(bool check_trailing) noexcept { auto max_len = peek_start_length(); auto json = peek_root_scalar("int64"); - uint8_t tmpbuf[20 + 1]; // -<19 digits> is the longest possible integer - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); return NUMBER_ERROR; } @@ -28947,8 +36236,9 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64_in_string(bool check_trailing) noexcept { auto max_len = peek_start_length(); auto json = peek_root_scalar("int64"); - uint8_t tmpbuf[20 + 1]; // -<19 digits> is the longest possible integer - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); return NUMBER_ERROR; } @@ -28966,8 +36256,9 @@ namespace simdjson { // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest // number: -0.e-308. - uint8_t tmpbuf[1074 + 8 + 1]; - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); return NUMBER_ERROR; } @@ -28985,8 +36276,9 @@ namespace simdjson { // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest // number: -0.e-308. - uint8_t tmpbuf[1074 + 8 + 1]; - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); return NUMBER_ERROR; } @@ -29000,8 +36292,9 @@ namespace simdjson { simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_bool(bool check_trailing) noexcept { auto max_len = peek_start_length(); auto json = peek_root_scalar("bool"); - uint8_t tmpbuf[5 + 1]; - if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf)) { return incorrect_type_error("Not a boolean"); } + uint8_t tmpbuf[5 + 1 + 1]; // +1 for null termination + tmpbuf[5 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 5 + 1)) { return incorrect_type_error("Not a boolean"); } auto result = parse_bool(tmpbuf); if (result.error() == SUCCESS) { if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } @@ -29215,11 +36508,13 @@ namespace simdjson { } simdjson_inline simdjson_result value_iterator::reset_array() noexcept { + if (error()) { return error(); } move_at_container_start(); return started_array(); } simdjson_inline simdjson_result value_iterator::reset_object() noexcept { + if (error()) { return error(); } move_at_container_start(); return started_object(); } @@ -29290,217 +36585,4842 @@ namespace simdjson { } } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace arm64 } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value_iterator&& value) noexcept - : implementation_simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base(error) {} + simdjson_inline simdjson_result::simdjson_result(arm64::ondemand::value_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} } // namespace simdjson -/* end file include/simdjson/generic/ondemand/value_iterator-inl.h */ -/* begin file include/simdjson/generic/ondemand/array_iterator-inl.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/value_iterator-inl.h for arm64 */ +/* end file simdjson/generic/ondemand/amalgamated.h for arm64 */ +/* including simdjson/arm64/end.h: #include "simdjson/arm64/end.h" */ +/* begin file simdjson/arm64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/arm64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "arm64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/arm64/end.h */ + +#endif // SIMDJSON_ARM64_ONDEMAND_H +/* end file simdjson/arm64/ondemand.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(fallback) +/* including simdjson/fallback/ondemand.h: #include "simdjson/fallback/ondemand.h" */ +/* begin file simdjson/fallback/ondemand.h */ +#ifndef SIMDJSON_FALLBACK_ONDEMAND_H +#define SIMDJSON_FALLBACK_ONDEMAND_H + +/* including simdjson/fallback/begin.h: #include "simdjson/fallback/begin.h" */ +/* begin file simdjson/fallback/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "fallback" */ +#define SIMDJSON_IMPLEMENTATION fallback +/* including simdjson/fallback/base.h: #include "simdjson/fallback/base.h" */ +/* begin file simdjson/fallback/base.h */ +#ifndef SIMDJSON_FALLBACK_BASE_H +#define SIMDJSON_FALLBACK_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + /** + * Fallback implementation (runs on any machine). + */ + namespace fallback { + + class implementation; + + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_BASE_H +/* end file simdjson/fallback/base.h */ +/* including simdjson/fallback/bitmanipulation.h: #include "simdjson/fallback/bitmanipulation.h" */ +/* begin file simdjson/fallback/bitmanipulation.h */ +#ifndef SIMDJSON_FALLBACK_BITMANIPULATION_H +#define SIMDJSON_FALLBACK_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + +#if defined(_MSC_VER) && !defined(_M_ARM64) && !defined(_M_X64) + static inline unsigned char _BitScanForward64(unsigned long* ret, uint64_t x) { + unsigned long x0 = (unsigned long)x, top, bottom; + _BitScanForward(&top, (unsigned long)(x >> 32)); + _BitScanForward(&bottom, x0); + *ret = x0 ? bottom : 32 + top; + return x != 0; + } + static unsigned char _BitScanReverse64(unsigned long* ret, uint64_t x) { + unsigned long x1 = (unsigned long)(x >> 32), top, bottom; + _BitScanReverse(&top, x1); + _BitScanReverse(&bottom, (unsigned long)x); + *ret = x1 ? top + 32 : bottom; + return x != 0; + } +#endif + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#ifdef _MSC_VER + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// _MSC_VER + } + + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_BITMANIPULATION_H +/* end file simdjson/fallback/bitmanipulation.h */ +/* including simdjson/fallback/stringparsing_defs.h: #include "simdjson/fallback/stringparsing_defs.h" */ +/* begin file simdjson/fallback/stringparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +#define SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace { + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 1; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return c == '"'; } + simdjson_inline bool has_backslash() { return c == '\\'; } + simdjson_inline int quote_index() { return c == '"' ? 0 : 1; } + simdjson_inline int backslash_index() { return c == '\\' ? 0 : 1; } + + uint8_t c; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // store to dest unconditionally - we can overwrite the bits we don't like later + dst[0] = src[0]; + return { src[0] }; + } + + } // unnamed namespace + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_FALLBACK_STRINGPARSING_DEFS_H +/* end file simdjson/fallback/stringparsing_defs.h */ +/* including simdjson/fallback/numberparsing_defs.h: #include "simdjson/fallback/numberparsing_defs.h" */ +/* begin file simdjson/fallback/numberparsing_defs.h */ +#ifndef SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +#define SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#ifdef JSON_TEST_NUMBERS // for unit testing +void found_invalid_number(const uint8_t* buf); +void found_integer(int64_t result, const uint8_t* buf); +void found_unsigned_integer(uint64_t result, const uint8_t* buf); +void found_float(double result, const uint8_t* buf); +#endif + +namespace simdjson { + namespace fallback { + namespace numberparsing { + + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const char* chars) { + uint64_t val; + memcpy(&val, chars, sizeof(uint64_t)); + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + return parse_eight_digits_unrolled(reinterpret_cast(chars)); + } + +#if SIMDJSON_IS_32BITS // _umul128 for x86, arm + // this is a slow emulation routine for 32-bit + // + static simdjson_inline uint64_t __emulu(uint32_t x, uint32_t y) { + return x * (uint64_t)y; + } + static simdjson_inline uint64_t _umul128(uint64_t ab, uint64_t cd, uint64_t* hi) { + uint64_t ad = __emulu((uint32_t)(ab >> 32), (uint32_t)cd); + uint64_t bd = __emulu((uint32_t)ab, (uint32_t)cd); + uint64_t adbc = ad + __emulu((uint32_t)ab, (uint32_t)(cd >> 32)); + uint64_t adbc_carry = !!(adbc < ad); + uint64_t lo = bd + (adbc << 32); + *hi = __emulu((uint32_t)(ab >> 32), (uint32_t)(cd >> 32)) + (adbc >> 32) + + (adbc_carry << 32) + !!(lo < bd); + return lo; + } +#endif + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace fallback +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_FALLBACK_NUMBERPARSING_DEFS_H +/* end file simdjson/fallback/numberparsing_defs.h */ +/* end file simdjson/fallback/begin.h */ +/* including simdjson/generic/ondemand/amalgamated.h for fallback: #include "simdjson/generic/ondemand/amalgamated.h" */ +/* begin file simdjson/generic/ondemand/amalgamated.h for fallback */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H) +#error simdjson/generic/ondemand/dependencies.h must be included before simdjson/generic/ondemand/amalgamated.h! +#endif + +// Stuff other things depend on +/* including simdjson/generic/ondemand/base.h for fallback: #include "simdjson/generic/ondemand/base.h" */ +/* begin file simdjson/generic/ondemand/base.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + /** + * A fast, simple, DOM-like interface that parses JSON as you use it. + * + * Designed for maximum speed and a lower memory profile. + */ namespace ondemand { - simdjson_inline array_iterator::array_iterator(const value_iterator& _iter) noexcept - : iter{ _iter } - {} + /** Represents the depth of a JSON value (number of nested arrays/objects). */ + using depth_t = int32_t; - simdjson_inline simdjson_result array_iterator::operator*() noexcept { - if (iter.error()) { iter.abandon(); return iter.error(); } - return value(iter.child()); - } - simdjson_inline bool array_iterator::operator==(const array_iterator& other) const noexcept { - return !(*this != other); - } - simdjson_inline bool array_iterator::operator!=(const array_iterator&) const noexcept { - return iter.is_open(); - } - simdjson_inline array_iterator& array_iterator::operator++() noexcept { + /** @copydoc simdjson::fallback::number_type */ + using number_type = simdjson::fallback::number_type; + + /** @private Position in the JSON buffer indexes */ + using token_position = const uint32_t*; + + class array; + class array_iterator; + class document; + class document_reference; + class document_stream; + class field; + class json_iterator; + enum class json_type; + struct number; + class object; + class object_iterator; + class parser; + class raw_json_string; + class token_iterator; + class value; + class value_iterator; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_BASE_H +/* end file simdjson/generic/ondemand/base.h for fallback */ +/* including simdjson/generic/ondemand/value_iterator.h for fallback: #include "simdjson/generic/ondemand/value_iterator.h" */ +/* begin file simdjson/generic/ondemand/value_iterator.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * Iterates through a single JSON value at a particular depth. + * + * Does not keep track of the type of value: provides methods for objects, arrays and scalars and expects + * the caller to call the right ones. + * + * @private This is not intended for external use. + */ + class value_iterator { + protected: + /** The underlying JSON iterator */ + json_iterator* _json_iter{}; + /** The depth of this value */ + depth_t _depth{}; + /** + * The starting token index for this value + */ + token_position _start_position{}; + + public: + simdjson_inline value_iterator() noexcept = default; + + /** + * Denote that we're starting a document. + */ + simdjson_inline void start_document() noexcept; + + /** + * Skips a non-iterated or partially-iterated JSON value, whether it is a scalar, array or object. + * + * Optimized for scalars. + */ + simdjson_warn_unused simdjson_inline error_code skip_child() noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is at the start of the value + */ + simdjson_inline bool at_start() const noexcept; + + /** + * Tell whether the value is open--if the value has not been used, or the array/object is still open. + */ + simdjson_inline bool is_open() const noexcept; + + /** + * Tell whether the value is at an object's first field (just after the {). + */ + simdjson_inline bool at_first_field() const noexcept; + + /** + * Abandon all iteration. + */ + simdjson_inline void abandon() noexcept; + + /** + * Get the child value as a value_iterator. + */ + simdjson_inline value_iterator child_value() const noexcept; + + /** + * Get the depth of this value. + */ + simdjson_inline int32_t depth() const noexcept; + + /** + * Get the JSON type of this value. + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() const noexcept; + + /** + * @addtogroup object Object iteration + * + * Methods to iterate and find object fields. These methods generally *assume* the value is + * actually an object; the caller is responsible for keeping track of that fact. + * + * @{ + */ + + /** + * Start an object iteration. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + */ + simdjson_warn_unused simdjson_inline simdjson_result start_object() noexcept; + /** + * Start an object iteration from the root. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_object() noexcept; + /** + * Checks whether an object could be started from the root. May be called by start_root_object. + * + * @returns SUCCESS if it is possible to safely start an object from the root (document level). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_object() noexcept; + /** + * Start an object iteration after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_object() noexcept; + /** + * Start an object iteration from the root, after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_object() noexcept; + + /** + * Moves to the next field in an object. + * + * Looks for , and }. If } is found, the object is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return whether there is another field in the object. + * @error TAPE_ERROR If there is a comma missing between fields. + * @error TAPE_ERROR If there is a comma, but not enough tokens remaining to have a key, :, and value. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_field() noexcept; + + /** + * Get the current field's key. + */ + simdjson_warn_unused simdjson_inline simdjson_result field_key() noexcept; + + /** + * Pass the : in the field and move to its value. + */ + simdjson_warn_unused simdjson_inline error_code field_value() noexcept; + + /** + * Find the next field with the given key. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline error_code find_field(const std::string_view key) noexcept; + + /** + * Find the next field with the given key, *without* unescaping. This assumes object order: it + * will not find the field if it was already passed when looking for some *other* field. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_raw(const std::string_view key) noexcept; + + /** + * Find the field with the given key without regard to order, and *without* unescaping. + * + * This is an unordered object lookup: if the field is not found initially, it will cycle around and scan from the beginning. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_unordered_raw(const std::string_view key) noexcept; + + /** @} */ + + /** + * @addtogroup array Array iteration + * Methods to iterate over array elements. These methods generally *assume* the value is actually + * an object; the caller is responsible for keeping track of that fact. + * @{ + */ + + /** + * Check for an opening [ and start an array iteration. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + */ + simdjson_warn_unused simdjson_inline simdjson_result start_array() noexcept; + /** + * Check for an opening [ and start an array iteration while at the root. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_array() noexcept; + /** + * Checks whether an array could be started from the root. May be called by start_root_array. + * + * @returns SUCCESS if it is possible to safely start an array from the root (document level). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_array() noexcept; + /** + * Start an array iteration, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_array() noexcept; + /** + * Start an array iteration from the root, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_array() noexcept; + + /** + * Moves to the next element in an array. + * + * Looks for , and ]. If ] is found, the array is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return Whether there is another element in the array. + * @error TAPE_ERROR If there is a comma missing between elements. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_element() noexcept; + + /** + * Get a child value iterator. + */ + simdjson_warn_unused simdjson_inline value_iterator child() const noexcept; + + /** @} */ + + /** + * @defgroup scalar Scalar values + * @addtogroup scalar + * @{ + */ + + simdjson_warn_unused simdjson_inline simdjson_result get_string(bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_bool() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_null() noexcept; + simdjson_warn_unused simdjson_inline bool is_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_integer() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + simdjson_warn_unused simdjson_inline simdjson_result get_root_string(bool check_trailing, bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_wobbly_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_raw_json_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_bool(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline bool is_root_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_integer(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number_type(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_null(bool check_trailing) noexcept; + + simdjson_inline error_code error() const noexcept; + simdjson_inline uint8_t*& string_buf_loc() noexcept; + simdjson_inline const json_iterator& json_iter() const noexcept; + simdjson_inline json_iterator& json_iter() noexcept; + + simdjson_inline void assert_is_valid() const noexcept; + simdjson_inline bool is_valid() const noexcept; + + /** @} */ + protected: + /** + * Restarts an array iteration. + * @returns Whether the array has any elements (returns false for empty). + */ + simdjson_inline simdjson_result reset_array() noexcept; + /** + * Restarts an object iteration. + * @returns Whether the object has any fields (returns false for empty). + */ + simdjson_inline simdjson_result reset_object() noexcept; + /** + * move_at_start(): moves us so that we are pointing at the beginning of + * the container. It updates the index so that at_start() is true and it + * syncs the depth. The user can then create a new container instance. + * + * Usage: used with value::count_elements(). + **/ + simdjson_inline void move_at_start() noexcept; + + /** + * move_at_container_start(): moves us so that we are pointing at the beginning of + * the container so that assert_at_container_start() passes. + * + * Usage: used with reset_array() and reset_object(). + **/ + simdjson_inline void move_at_container_start() noexcept; + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + simdjson_inline value_iterator(json_iterator* json_iter, depth_t depth, token_position start_index) noexcept; + + simdjson_inline simdjson_result parse_null(const uint8_t* json) const noexcept; + simdjson_inline simdjson_result parse_bool(const uint8_t* json) const noexcept; + simdjson_inline const uint8_t* peek_start() const noexcept; + simdjson_inline uint32_t peek_start_length() const noexcept; + + /** + * The general idea of the advance_... methods and the peek_* methods + * is that you first peek and check that you have desired type. If you do, + * and only if you do, then you advance. + * + * We used to unconditionally advance. But this made reasoning about our + * current state difficult. + * Suppose you always advance. Look at the 'value' matching the key + * "shadowable" in the following example... + * + * ({"globals":{"a":{"shadowable":[}}}}) + * + * If the user thinks it is a Boolean and asks for it, then we check the '[', + * decide it is not a Boolean, but still move into the next character ('}'). Now + * we are left pointing at '}' right after a '['. And we have not yet reported + * an error, only that we do not have a Boolean. + * + * If, instead, you just stand your ground until it is content that you know, then + * you will only even move beyond the '[' if the user tells you that you have an + * array. So you will be at the '}' character inside the array and, hopefully, you + * will then catch the error because an array cannot start with '}', but the code + * processing Boolean values does not know this. + * + * So the contract is: first call 'peek_...' and then call 'advance_...' only + * if you have determined that it is a type you can handle. + * + * Unfortunately, it makes the code more verbose, longer and maybe more error prone. + */ + + simdjson_inline void advance_scalar(const char* type) noexcept; + simdjson_inline void advance_root_scalar(const char* type) noexcept; + simdjson_inline void advance_non_root_scalar(const char* type) noexcept; + + simdjson_inline const uint8_t* peek_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_root_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_non_root_scalar(const char* type) noexcept; + + + simdjson_inline error_code start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept; + simdjson_inline error_code end_container() noexcept; + + /** + * Advance to a place expecting a value (increasing depth). + * + * @return The current token (the one left behind). + * @error TAPE_ERROR If the document ended early. + */ + simdjson_inline simdjson_result advance_to_value() noexcept; + + simdjson_inline error_code incorrect_type_error(const char* message) const noexcept; + simdjson_inline error_code error_unless_more_tokens(uint32_t tokens = 1) const noexcept; + + simdjson_inline bool is_at_start() const noexcept; + /** + * is_at_iterator_start() returns true on an array or object after it has just been + * created, whether the instance is empty or not. + * + * Usage: used by array::begin() in debug mode (SIMDJSON_DEVELOPMENT_CHECKS) + */ + simdjson_inline bool is_at_iterator_start() const noexcept; + + /** + * Assuming that we are within an object, this returns true if we + * are pointing at a key. + * + * Usage: the skip_child() method should never be used while we are pointing + * at a key inside an object. + */ + simdjson_inline bool is_at_key() const noexcept; + + inline void assert_at_start() const noexcept; + inline void assert_at_container_start() const noexcept; + inline void assert_at_root() const noexcept; + inline void assert_at_child() const noexcept; + inline void assert_at_next() const noexcept; + inline void assert_at_non_root_start() const noexcept; + + /** Get the starting position of this value */ + simdjson_inline token_position start_position() const noexcept; + + /** @copydoc error_code json_iterator::position() const noexcept; */ + simdjson_inline token_position position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position last_position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position end_position() const noexcept; + /** @copydoc error_code json_iterator::report_error(error_code error, const char *message) noexcept; */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + friend class document; + friend class object; + friend class array; + friend class value; + }; // value_iterator + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::value_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H +/* end file simdjson/generic/ondemand/value_iterator.h for fallback */ +/* including simdjson/generic/ondemand/value.h for fallback: #include "simdjson/generic/ondemand/value.h" */ +/* begin file simdjson/generic/ondemand/value.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * An ephemeral JSON value returned during iteration. It is only valid for as long as you do + * not access more data in the JSON document. + */ + class value { + public: + /** + * Create a new invalid value. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline value() noexcept = default; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) noexcept; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() noexcept; + + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() noexcept; + + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + + /** + * Cast this JSON value (inside string) to a unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + + /** + * Cast this JSON value to a "wobbly" string. + * + * The string is may not be a valid UTF-8 string. + * See https://simonsapin.github.io/wtf-8/ + * + * Important: a value should be consumed once. Calling get_wobbly_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); +#endif + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + * + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * Performance hint: You should only call count_elements() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method on the object instance. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @return The type of JSON value (json_type::array, json_type::object, json_type::string, + * json_type::number, json_type::boolean, or json_type::null). + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the value is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the value is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the value is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * Performance note: if you call this function systematically + * before parsing a number, you may have fallen for a performance + * anti-pattern. + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + * + * Performance note: this is designed with performance in mind. When + * calling 'get_number()', you scan the number string only once, determining + * efficiently the type and storing it in an efficient manner. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. However, if this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view is guaranteed to be + * a non-space token. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + * + * See also value::raw_json(). + */ + simdjson_inline std::string_view raw_json_token() noexcept; + + /** + * Get a string_view pointing at this value in the JSON document. + * If this element is an array or an object, it consumes the array or the object + * and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + * If this element is a scalar (string, number, Boolean, null), it returns what + * raw_json_token() would return. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + simdjson_inline simdjson_result current_location() noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. + * + * Calling at_pointer() on non-document instances (e.g., arrays and objects) is not + * standardized (by RFC 6901). We provide some experimental support for JSON pointers + * on non-document instances. Yet it is not the case when calling at_pointer on an array + * or an object instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + protected: + /** + * Create a value. + */ + simdjson_inline value(const value_iterator& iter) noexcept; + + /** + * Skip this value, allowing iteration to continue. + */ + simdjson_inline void skip() noexcept; + + /** + * Start a value at the current position. + * + * (It should already be started; this is just a self-documentation method.) + */ + static simdjson_inline value start(const value_iterator& iter) noexcept; + + /** + * Resume a value. + */ + static simdjson_inline value resume(const value_iterator& iter) noexcept; + + /** + * Get the object, starting or resuming it as necessary + */ + simdjson_inline simdjson_result start_or_resume_object() noexcept; + + // simdjson_inline void log_value(const char *type) const noexcept; + // simdjson_inline void log_error(const char *message) const noexcept; + + value_iterator iter{}; + + friend class document; + friend class array_iterator; + friend class field; + friend class object; + friend struct simdjson_result; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::value&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result get_array() noexcept; + simdjson_inline simdjson_result get_object() noexcept; + + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() noexcept; + + template simdjson_inline error_code get(T& out) noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator fallback::ondemand::array() noexcept(false); + simdjson_inline operator fallback::ondemand::object() noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator fallback::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + */ + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + + /** @copydoc simdjson_inline std::string_view value::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + /** @copydoc simdjson_inline simdjson_result current_location() noexcept */ + simdjson_inline simdjson_result current_location() noexcept; + /** @copydoc simdjson_inline int32_t current_depth() const noexcept */ + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_H +/* end file simdjson/generic/ondemand/value.h for fallback */ +/* including simdjson/generic/ondemand/logger.h for fallback: #include "simdjson/generic/ondemand/logger.h" */ +/* begin file simdjson/generic/ondemand/logger.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + // Logging should be free unless SIMDJSON_VERBOSE_LOGGING is set. Importantly, it is critical + // that the call to the log functions be side-effect free. Thus, for example, you should not + // create temporary std::string instances. + namespace logger { + + enum class log_level : int32_t { + info = 0, + error = 1 + }; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + + // We do not want these functions to be 'really inlined' since real inlining is + // for performance purposes and if you are using the loggers, you do not care about + // performance (or should not). + static inline void log_headers() noexcept; + // If args are provided, title will be treated as format string + template + static inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + template + static inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + static inline void log_event(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_value(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_start_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail = "") noexcept; + static inline void log_error(const json_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_event(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_error(const value_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + } // namespace logger + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_H +/* end file simdjson/generic/ondemand/logger.h for fallback */ +/* including simdjson/generic/ondemand/token_iterator.h for fallback: #include "simdjson/generic/ondemand/token_iterator.h" */ +/* begin file simdjson/generic/ondemand/token_iterator.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * Iterates through JSON tokens (`{` `}` `[` `]` `,` `:` `""` `123` `true` `false` `null`) + * detected by stage 1. + * + * @private This is not intended for external use. + */ + class token_iterator { + public: + /** + * Create a new invalid token_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline token_iterator() noexcept = default; + simdjson_inline token_iterator(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator& operator=(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator(const token_iterator& other) noexcept = default; + simdjson_inline token_iterator& operator=(const token_iterator& other) noexcept = default; + + /** + * Advance to the next token (returning the current one). + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + /** + * Reports the current offset in bytes from the start of the underlying buffer. + */ + simdjson_inline uint32_t current_offset() const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + + /** + * Return the current index. + */ + simdjson_inline token_position position() const noexcept; + /** + * Reset to a previously saved index. + */ + simdjson_inline void set_position(token_position target_position) noexcept; + + // NOTE: we don't support a full C++ iterator interface, because we expect people to make + // different calls to advance the iterator based on *their own* state. + + simdjson_inline bool operator==(const token_iterator& other) const noexcept; + simdjson_inline bool operator!=(const token_iterator& other) const noexcept; + simdjson_inline bool operator>(const token_iterator& other) const noexcept; + simdjson_inline bool operator>=(const token_iterator& other) const noexcept; + simdjson_inline bool operator<(const token_iterator& other) const noexcept; + simdjson_inline bool operator<=(const token_iterator& other) const noexcept; + + protected: + simdjson_inline token_iterator(const uint8_t* buf, token_position position) noexcept; + + /** + * Get the index of the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_index(int32_t delta = 0) const noexcept; + /** + * Get the index of the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline uint32_t peek_index(token_position position) const noexcept; + + const uint8_t* buf{}; + token_position _position{}; + + friend class json_iterator; + friend class value_iterator; + friend class object; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::token_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H +/* end file simdjson/generic/ondemand/token_iterator.h for fallback */ +/* including simdjson/generic/ondemand/json_iterator.h for fallback: #include "simdjson/generic/ondemand/json_iterator.h" */ +/* begin file simdjson/generic/ondemand/json_iterator.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * Iterates through JSON tokens, keeping track of depth and string buffer. + * + * @private This is not intended for external use. + */ + class json_iterator { + protected: + token_iterator token{}; + ondemand::parser* parser{}; + /** + * Next free location in the string buffer. + * + * Used by raw_json_string::unescape() to have a place to unescape strings to. + */ + uint8_t* _string_buf_loc{}; + /** + * JSON error, if there is one. + * + * INCORRECT_TYPE and NO_SUCH_FIELD are *not* stored here, ever. + * + * PERF NOTE: we *hope* this will be elided into control flow, as it is only used (a) in the first + * iteration of the loop, or (b) for the final iteration after a missing comma is found in ++. If + * this is not elided, we should make sure it's at least not using up a register. Failing that, + * we should store it in document so there's only one of them. + */ + error_code error{ SUCCESS }; + /** + * Depth of the current token in the JSON. + * + * - 0 = finished with document + * - 1 = document root value (could be [ or {, not yet known) + * - 2 = , or } inside root array/object + * - 3 = key or value inside root array/object. + */ + depth_t _depth{}; + /** + * Beginning of the document indexes. + * Normally we have root == parser->implementation->structural_indexes.get() + * but this may differ, especially in streaming mode (where we have several + * documents); + */ + token_position _root{}; + /** + * Normally, a json_iterator operates over a single document, but in + * some cases, we may have a stream of documents. This attribute is meant + * as meta-data: the json_iterator works the same irrespective of the + * value of this attribute. + */ + bool _streaming{ false }; + + public: + simdjson_inline json_iterator() noexcept = default; + simdjson_inline json_iterator(json_iterator&& other) noexcept; + simdjson_inline json_iterator& operator=(json_iterator&& other) noexcept; + simdjson_inline explicit json_iterator(const json_iterator& other) noexcept = default; + simdjson_inline json_iterator& operator=(const json_iterator& other) noexcept = default; + /** + * Skips a JSON value, whether it is a scalar, array or object. + */ + simdjson_warn_unused simdjson_inline error_code skip_child(depth_t parent_depth) noexcept; + + /** + * Tell whether the iterator is still at the start + */ + simdjson_inline bool at_root() const noexcept; + + /** + * Tell whether we should be expected to run in streaming + * mode (iterating over many documents). It is pure metadata + * that does not affect how the iterator works. It is used by + * start_root_array() and start_root_object(). + */ + simdjson_inline bool streaming() const noexcept; + + /** + * Get the root value iterator + */ + simdjson_inline token_position root_position() const noexcept; + /** + * Assert that we are at the document depth (== 1) + */ + simdjson_inline void assert_at_document_depth() const noexcept; + /** + * Assert that we are at the root of the document + */ + simdjson_inline void assert_at_root() const noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is live (has not been moved). + */ + simdjson_inline bool is_alive() const noexcept; + + /** + * Abandon this iterator, setting depth to 0 (as if the document is finished). + */ + simdjson_inline void abandon() noexcept; + + /** + * Advance the current token without modifying depth. + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + + /** + * Returns true if there is a single token in the index (i.e., it is + * a JSON with a scalar value such as a single number). + * + * @return whether there is a single token + */ + simdjson_inline bool is_single_token() const noexcept; + + /** + * Assert that there are at least the given number of tokens left. + * + * Has no effect in release builds. + */ + simdjson_inline void assert_more_tokens(uint32_t required_tokens = 1) const noexcept; + /** + * Assert that the given position addresses an actual token (is within bounds). + * + * Has no effect in release builds. + */ + simdjson_inline void assert_valid_position(token_position position) const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + /** + * Get a pointer to the current location in the input buffer. + * + * This is not null-terminated; it is a view into the JSON. + * + * You may be pointing outside of the input buffer: it is not generally + * safe to dereference this pointer. + */ + simdjson_inline const uint8_t* unsafe_pointer() const noexcept; + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token to retrieve. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token to retrieve. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + /** + * Get the JSON text for the last token in the document. + * + * This is not null-terminated; it is a view into the JSON. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek_last() const noexcept; + + /** + * Ascend one level. + * + * Validates that the depth - 1 == parent_depth. + * + * @param parent_depth the expected parent depth. + */ + simdjson_inline void ascend_to(depth_t parent_depth) noexcept; + + /** + * Descend one level. + * + * Validates that the new depth == child_depth. + * + * @param child_depth the expected child depth. + */ + simdjson_inline void descend_to(depth_t child_depth) noexcept; + simdjson_inline void descend_to(depth_t child_depth, int32_t delta) noexcept; + + /** + * Get current depth. + */ + simdjson_inline depth_t depth() const noexcept; + + /** + * Get current (writeable) location in the string buffer. + */ + simdjson_inline uint8_t*& string_buf_loc() noexcept; + + /** + * Report an unrecoverable error, preventing further iteration. + * + * @param error The error to report. Must not be SUCCESS, UNINITIALIZED, INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + /** + * Log error, but don't stop iteration. + * @param error The error to report. Must be INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code optional_error(error_code error, const char* message) noexcept; + + /** + * Take an input in json containing max_len characters and attempt to copy it over to tmpbuf, a buffer with + * N bytes of capacity. It will return false if N is too small (smaller than max_len) of if it is zero. + * The buffer (tmpbuf) is padded with space characters. + */ + simdjson_warn_unused simdjson_inline bool copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept; + + simdjson_inline token_position position() const noexcept; + /** + * Write the raw_json_string to the string buffer and return a string_view. + * Each raw_json_string should be unescaped once, or else the string buffer might + * overflow. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, bool allow_replacement) noexcept; + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in) noexcept; + + simdjson_inline void reenter_child(token_position position, depth_t child_depth) noexcept; + + simdjson_inline error_code consume_character(char c) noexcept; +#if SIMDJSON_DEVELOPMENT_CHECKS + simdjson_inline token_position start_position(depth_t depth) const noexcept; + simdjson_inline void set_start_position(depth_t depth, token_position position) noexcept; +#endif + + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Updates this json iterator so that it is back at the beginning of the document, + * as if it had just been created. + */ + inline void rewind() noexcept; + /** + * This checks whether the {,},[,] are balanced so that the document + * ends with proper zero depth. This requires scanning the whole document + * and it may be expensive. It is expected that it will be rarely called. + * It does not attempt to match { with } and [ with ]. + */ + inline bool balanced() const noexcept; + protected: + simdjson_inline json_iterator(const uint8_t* buf, ondemand::parser* parser) noexcept; + /// The last token before the end + simdjson_inline token_position last_position() const noexcept; + /// The token *at* the end. This points at gibberish and should only be used for comparison. + simdjson_inline token_position end_position() const noexcept; + /// The end of the buffer. + simdjson_inline token_position end() const noexcept; + + friend class document; + friend class document_stream; + friend class object; + friend class array; + friend class value; + friend class raw_json_string; + friend class parser; + friend class value_iterator; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; // json_iterator + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::json_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H +/* end file simdjson/generic/ondemand/json_iterator.h for fallback */ +/* including simdjson/generic/ondemand/json_type.h for fallback: #include "simdjson/generic/ondemand/json_type.h" */ +/* begin file simdjson/generic/ondemand/json_type.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * The type of a JSON value. + */ + enum class json_type { + // Start at 1 to catch uninitialized / default values more easily + array = 1, ///< A JSON array ( [ 1, 2, 3 ... ] ) + object, ///< A JSON object ( { "a": 1, "b" 2, ... } ) + number, ///< A JSON number ( 1 or -2.3 or 4.5e6 ...) + string, ///< A JSON string ( "a" or "hello world\n" ...) + boolean, ///< A JSON boolean (true or false) + null ///< A JSON null (null) + }; + + /** + * A type representing a JSON number. + * The design of the struct is deliberately straight-forward. All + * functions return standard values with no error check. + */ + struct number { + + /** + * return the automatically determined type of + * the number: number_type::floating_point_number, + * number_type::signed_integer or number_type::unsigned_integer. + * + * enum class number_type { + * floating_point_number=1, /// a binary64 number + * signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + * unsigned_integer /// a positive integer larger or equal to 1<<63 + * }; + */ + simdjson_inline ondemand::number_type get_number_type() const noexcept; + /** + * return true if the automatically determined type of + * the number is number_type::unsigned_integer. + */ + simdjson_inline bool is_uint64() const noexcept; + /** + * return the value as a uint64_t, only valid if is_uint64() is true. + */ + simdjson_inline uint64_t get_uint64() const noexcept; + simdjson_inline operator uint64_t() const noexcept; + + /** + * return true if the automatically determined type of + * the number is number_type::signed_integer. + */ + simdjson_inline bool is_int64() const noexcept; + /** + * return the value as a int64_t, only valid if is_int64() is true. + */ + simdjson_inline int64_t get_int64() const noexcept; + simdjson_inline operator int64_t() const noexcept; + + + /** + * return true if the automatically determined type of + * the number is number_type::floating_point_number. + */ + simdjson_inline bool is_double() const noexcept; + /** + * return the value as a double, only valid if is_double() is true. + */ + simdjson_inline double get_double() const noexcept; + simdjson_inline operator double() const noexcept; + + /** + * Convert the number to a double. Though it always succeed, the conversion + * may be lossy if the number cannot be represented exactly. + */ + simdjson_inline double as_double() const noexcept; + + + protected: + /** + * The next block of declaration is designed so that we can call the number parsing + * functions on a number type. They are protected and should never be used outside + * of the core simdjson library. + */ + friend class value_iterator; + template + friend error_code numberparsing::slow_float_parsing(simdjson_unused const uint8_t* src, W writer); + template + friend error_code numberparsing::write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer); + template + friend error_code numberparsing::parse_number(const uint8_t* const src, W& writer); + /** Store a signed 64-bit value to the number. */ + simdjson_inline void append_s64(int64_t value) noexcept; + /** Store an unsigned 64-bit value to the number. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + /** Store a double value to the number. */ + simdjson_inline void append_double(double value) noexcept; + /** Specifies that the value is a double, but leave it undefined. */ + simdjson_inline void skip_double() noexcept; + /** + * End of friend declarations. + */ + + /** + * Our attributes are a union type (size = 64 bits) + * followed by a type indicator. + */ + union { + double floating_point_number; + int64_t signed_integer; + uint64_t unsigned_integer; + } payload{ 0 }; + number_type type{ number_type::signed_integer }; + }; + + /** + * Write the JSON type to the output stream + * + * @param out The output stream. + * @param type The json_type. + */ + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Send JSON type to an output stream. + * + * @param out The output stream. + * @param type The json_type. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false); +#endif + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::json_type&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H +/* end file simdjson/generic/ondemand/json_type.h for fallback */ +/* including simdjson/generic/ondemand/raw_json_string.h for fallback: #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * A string escaped per JSON rules, terminated with quote ("). They are used to represent + * unescaped keys inside JSON documents. + * + * (In other words, a pointer to the beginning of a string, just after the start quote, inside a + * JSON file.) + * + * This class is deliberately simplistic and has little functionality. You can + * compare a raw_json_string instance with an unescaped C string, but + * that is nearly all you can do. + * + * The raw_json_string is unescaped. If you wish to write an unescaped version of it to your own + * buffer, you may do so using the parser.unescape(string, buff) method, using an ondemand::parser + * instance. Doing so requires you to have a sufficiently large buffer. + * + * The raw_json_string instances originate typically from field instance which in turn represent + * key-value pairs from object instances. From a field instance, you get the raw_json_string + * instance by calling key(). You can, if you want a more usable string_view instance, call + * the unescaped_key() method on the field instance. You may also create a raw_json_string from + * any other string value, with the value.get_raw_json_string() method. Again, you can get + * a more usable string_view instance by calling get_string(). + * + */ + class raw_json_string { + public: + /** + * Create a new invalid raw_json_string. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline raw_json_string() noexcept = default; + + /** + * Create a new invalid raw_json_string pointed at the given location in the JSON. + * + * The given location must be just *after* the beginning quote (") in the JSON file. + * + * It *must* be terminated by a ", and be a valid JSON string. + */ + simdjson_inline raw_json_string(const uint8_t* _buf) noexcept; + /** + * Get the raw pointer to the beginning of the string in the JSON (just after the "). + * + * It is possible for this function to return a null pointer if the instance + * has outlived its existence. + */ + simdjson_inline const char* raw() const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done) on target.size() characters, + * and if the raw_json_string instance has a quote character at byte index target.size(). + * We never read more than length + 1 bytes in the raw_json_string instance. + * If length is smaller than target.size(), this will return false. + * + * The std::string_view instance may contain any characters. However, the caller + * is responsible for setting length so that length bytes may be read in the + * raw_json_string. + * + * Performance: the comparison may be done using memcmp which may be efficient + * for long strings. + */ + simdjson_inline bool unsafe_is_equal(size_t length, std::string_view target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The std::string_view instance should not contain unescaped quote characters: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * Performance: the comparison is done byte-by-byte which might be inefficient for + * long strings. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The provided C string should not contain an unescaped quote character: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(const char* target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(const char* target) const noexcept; + + /** + * Returns true if target is free from unescaped quote. If target is known at + * compile-time, we might expect the computation to happen at compile time with + * many compilers (not all!). + */ + static simdjson_inline bool is_free_from_unescaped_quote(std::string_view target) noexcept; + static simdjson_inline bool is_free_from_unescaped_quote(const char* target) noexcept; + + private: + + + /** + * This will set the inner pointer to zero, effectively making + * this instance unusable. + */ + simdjson_inline void consume() noexcept { buf = nullptr; } + + /** + * Checks whether the inner pointer is non-null and thus usable. + */ + simdjson_inline simdjson_warn_unused bool alive() const noexcept { return buf != nullptr; } + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result will be a valid UTF-8. + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + * @param allow_replacement Whether we allow replacement of invalid surrogate pairs. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape(json_iterator& iter, bool allow_replacement) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result may not be a valid UTF-8. https://simonsapin.github.io/wtf-8/ + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(json_iterator& iter) const noexcept; + const uint8_t* buf{}; + friend class object; + friend class field; + friend class parser; + friend struct simdjson_result; + }; + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream&, const raw_json_string&) noexcept; + + /** + * Comparisons between raw_json_string and std::string_view instances are potentially unsafe: the user is responsible + * for providing a string with no unescaped quote. Note that unescaped quotes cannot be present in valid JSON strings. + */ + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept; + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept; + + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::raw_json_string&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + + simdjson_inline simdjson_result raw() const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape(fallback::ondemand::json_iterator& iter, bool allow_replacement) const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(fallback::ondemand::json_iterator& iter) const noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H +/* end file simdjson/generic/ondemand/raw_json_string.h for fallback */ +/* including simdjson/generic/ondemand/parser.h for fallback: #include "simdjson/generic/ondemand/parser.h" */ +/* begin file simdjson/generic/ondemand/parser.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * The default batch size for document_stream instances for this On Demand kernel. + * Note that different On Demand kernel may use a different DEFAULT_BATCH_SIZE value + * in the future. + */ + static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; + /** + * Some adversary might try to set the batch size to 0 or 1, which might cause problems. + * We set a minimum of 32B since anything else is highly likely to be an error. In practice, + * most users will want a much larger batch size. + * + * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON + * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. + */ + static constexpr size_t MINIMAL_BATCH_SIZE = 32; + + /** + * A JSON fragment iterator. + * + * This holds the actual iterator as well as the buffer for writing strings. + */ + class parser { + public: + /** + * Create a JSON parser. + * + * The new parser will have zero capacity. + */ + inline explicit parser(size_t max_capacity = SIMDJSON_MAXSIZE_BYTES) noexcept; + + inline parser(parser&& other) noexcept = default; + simdjson_inline parser(const parser& other) = delete; + simdjson_inline parser& operator=(const parser& other) = delete; + simdjson_inline parser& operator=(parser&& other) noexcept = default; + + /** Deallocate the JSON parser. */ + inline ~parser() noexcept = default; + + /** + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * document doc = parser.iterate(json); + * + * It is expected that the content is a valid UTF-8 file, containing a valid JSON document. + * Otherwise the iterate method may return an error. In particular, the whole input should be + * valid: we do not attempt to tolerate incorrect content either before or after a JSON + * document. If there is a UTF-8 BOM, the parser skips it. + * + * ### IMPORTANT: Validate what you use + * + * Calling iterate on an invalid JSON document may not immediately trigger an error. The call to + * iterate does not parse and validate the whole document. + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * @param len The length of the JSON. + * @param capacity The number of bytes allocated in the JSON (must be at least len+SIMDJSON_PADDING). + * + * @return The document, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate(padded_string_view json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const char* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const uint8_t* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string_view json, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(padded_string&& json) & noexcept = delete; + + /** + * @private + * + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * json_iterator doc = parser.iterate(json); + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * The ondemand::document instance holds the iterator. The document must remain in scope + * while you are accessing instances of ondemand::value, ondemand::object, ondemand::array. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * + * @return The iterator, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate_raw(padded_string_view json) & noexcept; + + + /** + * Parse a buffer containing many JSON documents. + * + * auto json = R"({ "foo": 1 } { "foo": 2 } { "foo": 3 } )"_padded; + * ondemand::parser parser; + * ondemand::document_stream docs = parser.iterate_many(json); + * for (auto & doc : docs) { + * std::cout << doc["foo"] << std::endl; + * } + * // Prints 1 2 3 + * + * No copy of the input buffer is made. + * + * The function is lazy: it may be that no more than one JSON document at a time is parsed. + * + * The caller is responsabile to ensure that the input string data remains unchanged and is + * not deleted during the loop. + * + * ### Format + * + * The buffer must contain a series of one or more JSON documents, concatenated into a single + * buffer, separated by ASCII whitespace. It effectively parses until it has a fully valid document, + * then starts parsing the next document at that point. (It does this with more parallelism and + * lookahead than you might think, though.) + * + * documents that consist of an object or array may omit the whitespace between them, concatenating + * with no separator. Documents that consist of a single primitive (i.e. documents that are not + * arrays or objects) MUST be separated with ASCII whitespace. + * + * The characters inside a JSON document, and between JSON documents, must be valid Unicode (UTF-8). + * If there is a UTF-8 BOM, the parser skips it. + * + * The documents must not exceed batch_size bytes (by default 1MB) or they will fail to parse. + * Setting batch_size to excessively large or excessively small values may impact negatively the + * performance. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * ### Threads + * + * When compiled with SIMDJSON_THREADS_ENABLED, this method will use a single thread under the + * hood to do some lookahead. + * + * ### Parser Capacity + * + * If the parser's current capacity is less than batch_size, it will allocate enough capacity + * to handle it (up to max_capacity). + * + * @param buf The concatenated JSON to parse. + * @param len The length of the concatenated JSON. + * @param batch_size The batch size to use. MUST be larger than the largest document. The sweet + * spot is cache-related: small enough to fit in cache, yet big enough to + * parse as many documents as possible in one tight loop. + * Defaults to 10MB, which has been a reasonable sweet spot in our tests. + * @param allow_comma_separated (defaults on false) This allows a mode where the documents are + * separated by commas instead of whitespace. It comes with a performance + * penalty because the entire document is indexed at once (and the document must be + * less than 4 GB), and there is no multithreading. In this mode, the batch_size parameter + * is effectively ignored, as it is set to at least the document size. + * @return The stream, or an error. An empty input will yield 0 documents rather than an EMPTY error. Errors: + * - MEMALLOC if the parser does not have enough capacity and memory allocation fails + * - CAPACITY if the parser does not have enough capacity and batch_size > max_capacity. + * - other json errors if parsing fails. You should not rely on these errors to always the same for the + * same document: they may vary under runtime dispatch (so they may vary depending on your system and hardware). + */ + inline simdjson_result iterate_many(const uint8_t* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const char* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const std::string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const std::string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const padded_string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const padded_string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + + /** @private We do not want to allow implicit conversion from C string to std::string. */ + simdjson_result iterate_many(const char* buf, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept = delete; + + /** The capacity of this parser (the largest document it can process). */ + simdjson_inline size_t capacity() const noexcept; + /** The maximum capacity of this parser (the largest document it is allowed to process). */ + simdjson_inline size_t max_capacity() const noexcept; + simdjson_inline void set_max_capacity(size_t max_capacity) noexcept; + /** + * The maximum depth of this parser (the most deeply nested objects and arrays it can process). + * This parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + */ + simdjson_inline size_t max_depth() const noexcept; + + /** + * Ensure this parser has enough memory to process JSON documents up to `capacity` bytes in length + * and `max_depth` depth. + * + * The max_depth parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. Defaults to DEFAULT_MAX_DEPTH. + * @return The error, if there is one. + */ + simdjson_warn_unused error_code allocate(size_t capacity, size_t max_depth = DEFAULT_MAX_DEPTH) noexcept; + +#ifdef SIMDJSON_THREADS_ENABLED + /** + * The parser instance can use threads when they are available to speed up some + * operations. It is enabled by default. Changing this attribute will change the + * behavior of the parser for future operations. + */ + bool threaded{ true }; +#endif + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result must be valid UTF-8. + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @param allow_replacement Whether we allow a replacement if the input string contains unmatched surrogate pairs. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement = false) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result may not be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept; + + private: + /** @private [for benchmarking access] The implementation to use */ + std::unique_ptr implementation{}; + size_t _capacity{ 0 }; + size_t _max_capacity; + size_t _max_depth{ DEFAULT_MAX_DEPTH }; + std::unique_ptr string_buf{}; +#if SIMDJSON_DEVELOPMENT_CHECKS + std::unique_ptr start_positions{}; +#endif + + friend class json_iterator; + friend class document_stream; + }; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::parser&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_H +/* end file simdjson/generic/ondemand/parser.h for fallback */ + +// All other declarations +/* including simdjson/generic/ondemand/array.h for fallback: #include "simdjson/generic/ondemand/array.h" */ +/* begin file simdjson/generic/ondemand/array.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * A forward-only JSON array. + */ + class array { + public: + /** + * Create a new invalid array. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline array() noexcept = default; + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an array is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the beginning of the array and checks whether the + * array is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result is_empty() & noexcept; + /** + * Reset the iterator so that we are pointing back at the + * beginning of the array. You should still consume values only once even if you + * can iterate through the array more than once. If you unescape a string + * within the array more than once, you have unsafe code. Note that rewinding + * an array means that you may need to reparse it anew: it is not a free + * operation. + * + * @returns true if the array contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"([ { "foo": { "a": [ 10, 20, 30 ] }} ])"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/0/foo/a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an array + * instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the array and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Get the value at the given index. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + protected: + /** + * Go to the end of the array, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + + /** + * Begin array iteration. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + */ + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + /** + * Begin array iteration from the root. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + * @error TAPE_ERROR if there is no closing ] at the end of the document. + */ + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + /** + * Begin array iteration. + * + * This version of the method should be called after the initial [ has been verified, and is + * intended for use by switch statements that check the type of a value. + * + * @param iter The iterator. Must be after the initial [. Will be *moved* into the resulting array. + */ + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + + /** + * Create an array at the given Internal array creation. Call array::start() or array::started() instead of this. + * + * @param iter The iterator. Must either be at the start of the first element with iter.is_alive() + * == true, or past the [] with is_alive() == false if the array is empty. Will be *moved* + * into the resulting array. + */ + simdjson_inline array(const value_iterator& iter) noexcept; + + /** + * Iterator marking current position. + * + * iter.is_alive() == false indicates iteration is complete. + */ + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + friend struct simdjson_result; + friend class array_iterator; + }; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::array&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + inline simdjson_result count_elements() & noexcept; + inline simdjson_result is_empty() & noexcept; + inline simdjson_result reset() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_H +/* end file simdjson/generic/ondemand/array.h for fallback */ +/* including simdjson/generic/ondemand/array_iterator.h for fallback: #include "simdjson/generic/ondemand/array_iterator.h" */ +/* begin file simdjson/generic/ondemand/array_iterator.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * A forward-only JSON array. + * + * This is an input_iterator, meaning: + * - It is forward-only + * - * must be called exactly once per element. + * - ++ must be called exactly once in between each * (*, ++, *, ++, * ...) + */ + class array_iterator { + public: + /** Create a new, invalid array iterator. */ + simdjson_inline array_iterator() noexcept = default; + + // + // Iterator interface + // + + /** + * Get the current element. + * + * Part of the std::iterator interface. + */ + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + /** + * Check if we are at the end of the JSON. + * + * Part of the std::iterator interface. + * + * @return true if there are no more elements in the JSON array. + */ + simdjson_inline bool operator==(const array_iterator&) const noexcept; + /** + * Check if there are more elements in the JSON array. + * + * Part of the std::iterator interface. + * + * @return true if there are more elements in the JSON array. + */ + simdjson_inline bool operator!=(const array_iterator&) const noexcept; + /** + * Move to the next element. + * + * Part of the std::iterator interface. + */ + simdjson_inline array_iterator& operator++() noexcept; + + private: + value_iterator iter{}; + + simdjson_inline array_iterator(const value_iterator& iter) noexcept; + + friend class array; + friend class value; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::array_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H +/* end file simdjson/generic/ondemand/array_iterator.h for fallback */ +/* including simdjson/generic/ondemand/document.h for fallback: #include "simdjson/generic/ondemand/document.h" */ +/* begin file simdjson/generic/ondemand/document.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * A JSON document. It holds a json_iterator instance. + * + * Used by tokens to get text, and string buffer location. + * + * You must keep the document around during iteration. + */ + class document { + public: + /** + * Create a new invalid document. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline document() noexcept = default; + simdjson_inline document(const document& other) noexcept = delete; // pass your documents by reference, not by copy + simdjson_inline document(document&& other) noexcept = default; + simdjson_inline document& operator=(const document& other) noexcept = delete; + simdjson_inline document& operator=(document&& other) noexcept = default; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() & noexcept; + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() & noexcept; + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + /** + * Cast this JSON value (inside string) to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: Calling get_string() twice on the same document is an error. + * + * @param Whether to allow a replacement character for unmatched surrogate pairs. + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + /** + * Cast this JSON value to a string. + * + * The string is not guaranteed to be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * + * Important: Calling get_wobbly_string() twice on the same document is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is set to 1 (which is the case when building in Debug mode + * by default), and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value if a JSON array or object cannot be found. + * @returns SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result get_value() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() & noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + /** @overload template simdjson_result get() & noexcept */ + template simdjson_inline simdjson_result get() && noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool, value + * + * Be mindful that the document instance must remain in scope while you are accessing object, array and value instances. + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) & noexcept; + /** @overload template error_code get(T &out) & noexcept */ + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() & noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() & noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is defined, and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value value if a JSON array or object cannot be found. + * @exception SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline operator value() noexcept(false); +#endif + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) & noexcept; + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to + * a key a single time. Doing object["mykey"].to_string()and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the document is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the document is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the document is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. If this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view may be the padded buffer. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + /** + * Reset the iterator inside the document instance so we are pointing back at the + * beginning of the document, as if it had just been created. It invalidates all + * values, objects and arrays that you have created so far (including unescaped strings). + */ + inline void rewind() noexcept; + /** + * Returns debugging information. + */ + inline std::string to_debug_string() noexcept; + /** + * Some unrecoverable error conditions may render the document instance unusable. + * The is_alive() method returns true when the document is still suitable. + */ + inline bool is_alive() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Returns true if this document has been fully parsed. + * If you have consumed the whole document and at_end() returns + * false, then there may be trailing content. + */ + inline bool at_end() const noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() automatically calls rewind between each call. Thus + * all values, objects and arrays that you have created so far (including unescaped strings) + * are invalidated. After calling at_pointer, you need to consume the result: string values + * should be stored in your own variables, arrays should be decoded and stored in your own array-like + * structures and so forth. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + * - SCALAR_DOCUMENT_AS_VALUE if the json_pointer is empty and the document is not a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the document and returns a string_view instance corresponding to the + * document as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + protected: + /** + * Consumes the document. + */ + simdjson_inline error_code consume() noexcept; + + simdjson_inline document(ondemand::json_iterator&& iter) noexcept; + simdjson_inline const uint8_t* text(uint32_t idx) const noexcept; + + simdjson_inline value_iterator resume_value_iterator() noexcept; + simdjson_inline value_iterator get_root_value_iterator() noexcept; + simdjson_inline simdjson_result start_or_resume_object() noexcept; + static simdjson_inline document start(ondemand::json_iterator&& iter) noexcept; + + // + // Fields + // + json_iterator iter{}; ///< Current position in the document + static constexpr depth_t DOCUMENT_DEPTH = 0; ///< document depth is always 0 + + friend class array_iterator; + friend class value; + friend class ondemand::parser; + friend class object; + friend class array; + friend class field; + friend class token; + friend class document_stream; + friend class document_reference; + }; + + + /** + * A document_reference is a thin wrapper around a document reference instance. + */ + class document_reference { + public: + simdjson_inline document_reference() noexcept; + simdjson_inline document_reference(document& d) noexcept; + simdjson_inline document_reference(const document_reference& other) noexcept = default; + simdjson_inline document_reference& operator=(const document_reference& other) noexcept = default; + simdjson_inline void rewind() noexcept; + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + + simdjson_inline simdjson_result is_null() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + simdjson_inline operator document& () const noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator array() & noexcept(false); + simdjson_inline operator object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + private: + document* doc{ nullptr }; + }; + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::document&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() & noexcept; + template simdjson_inline simdjson_result get() && noexcept; + + template simdjson_inline error_code get(T& out) & noexcept; + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator fallback::ondemand::array() & noexcept(false); + simdjson_inline operator fallback::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator fallback::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator fallback::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool at_end() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + + + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::document_reference value, error_code error) noexcept; + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator fallback::ondemand::array() & noexcept(false); + simdjson_inline operator fallback::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator fallback::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator fallback::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document_reference::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H +/* end file simdjson/generic/ondemand/document.h for fallback */ +/* including simdjson/generic/ondemand/document_stream.h for fallback: #include "simdjson/generic/ondemand/document_stream.h" */ +/* begin file simdjson/generic/ondemand/document_stream.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#ifdef SIMDJSON_THREADS_ENABLED +#include +#include +#include +#endif + +namespace simdjson { + namespace fallback { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + /** @private Custom worker class **/ + struct stage1_worker { + stage1_worker() noexcept = default; + stage1_worker(const stage1_worker&) = delete; + stage1_worker(stage1_worker&&) = delete; + stage1_worker operator=(const stage1_worker&) = delete; + ~stage1_worker(); + /** + * We only start the thread when it is needed, not at object construction, this may throw. + * You should only call this once. + **/ + void start_thread(); + /** + * Start a stage 1 job. You should first call 'run', then 'finish'. + * You must call start_thread once before. + */ + void run(document_stream* ds, parser* stage1, size_t next_batch_start); + /** Wait for the run to finish (blocking). You should first call 'run', then 'finish'. **/ + void finish(); + + private: + + /** + * Normally, we would never stop the thread. But we do in the destructor. + * This function is only safe assuming that you are not waiting for results. You + * should have called run, then finish, and be done. + **/ + void stop_thread(); + + std::thread thread{}; + /** These three variables define the work done by the thread. **/ + ondemand::parser* stage1_thread_parser{}; + size_t _next_batch_start{}; + document_stream* owner{}; + /** + * We have two state variables. This could be streamlined to one variable in the future but + * we use two for clarity. + */ + bool has_work{ false }; + bool can_work{ true }; + + /** + * We lock using a mutex. + */ + std::mutex locking_mutex{}; + std::condition_variable cond_var{}; + + friend class document_stream; + }; +#endif // SIMDJSON_THREADS_ENABLED + + /** + * A forward-only stream of documents. + * + * Produced by parser::iterate_many. + * + */ + class document_stream { + public: + /** + * Construct an uninitialized document_stream. + * + * ```c++ + * document_stream docs; + * auto error = parser.iterate_many(json).get(docs); + * ``` + */ + simdjson_inline document_stream() noexcept; + /** Move one document_stream to another. */ + simdjson_inline document_stream(document_stream&& other) noexcept = default; + /** Move one document_stream to another. */ + simdjson_inline document_stream& operator=(document_stream&& other) noexcept = default; + + simdjson_inline ~document_stream() noexcept; + + /** + * Returns the input size in bytes. + */ + inline size_t size_in_bytes() const noexcept; + + /** + * After iterating through the stream, this method + * returns the number of bytes that were not parsed at the end + * of the stream. If truncated_bytes() differs from zero, + * then the input was truncated maybe because incomplete JSON + * documents were found at the end of the stream. You + * may need to process the bytes in the interval [size_in_bytes()-truncated_bytes(), size_in_bytes()). + * + * You should only call truncated_bytes() after streaming through all + * documents, like so: + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto & doc : stream) { + * // do something with doc + * } + * size_t truncated = stream.truncated_bytes(); + * + */ + inline size_t truncated_bytes() const noexcept; + + class iterator { + public: + using value_type = simdjson_result; + using reference = value_type; + + using difference_type = std::ptrdiff_t; + + using iterator_category = std::input_iterator_tag; + + /** + * Default constructor. + */ + simdjson_inline iterator() noexcept; + /** + * Get the current document (or error). + */ + simdjson_inline simdjson_result operator*() noexcept; + /** + * Advance to the next document (prefix). + */ + inline iterator& operator++() noexcept; + /** + * Check if we're at the end yet. + * @param other the end iterator to compare to. + */ + simdjson_inline bool operator!=(const iterator& other) const noexcept; + /** + * @private + * + * Gives the current index in the input document in bytes. + * + * document_stream stream = parser.parse_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * auto doc = *i; + * size_t index = i.current_index(); + * } + * + * This function (current_index()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + */ + simdjson_inline size_t current_index() const noexcept; + + /** + * @private + * + * Gives a view of the current document at the current position. + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * std::string_view v = i.source(); + * } + * + * The returned string_view instance is simply a map to the (unparsed) + * source string: it may thus include white-space characters and all manner + * of padding. + * + * This function (source()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + * + */ + simdjson_inline std::string_view source() const noexcept; + + /** + * Returns error of the stream (if any). + */ + inline error_code error() const noexcept; + + private: + simdjson_inline iterator(document_stream* s, bool finished) noexcept; + /** The document_stream we're iterating through. */ + document_stream* stream; + /** Whether we're finished or not. */ + bool finished; + + friend class document; + friend class document_stream; + friend class json_iterator; + }; + + /** + * Start iterating the documents in the stream. + */ + simdjson_inline iterator begin() noexcept; + /** + * The end of the stream, for iterator comparison purposes. + */ + simdjson_inline iterator end() noexcept; + + private: + + document_stream& operator=(const document_stream&) = delete; // Disallow copying + document_stream(const document_stream& other) = delete; // Disallow copying + + /** + * Construct a document_stream. Does not allocate or parse anything until the iterator is + * used. + * + * @param parser is a reference to the parser instance used to generate this document_stream + * @param buf is the raw byte buffer we need to process + * @param len is the length of the raw byte buffer in bytes + * @param batch_size is the size of the windows (must be strictly greater or equal to the largest JSON document) + */ + simdjson_inline document_stream( + ondemand::parser& parser, + const uint8_t* buf, + size_t len, + size_t batch_size, + bool allow_comma_separated + ) noexcept; + + /** + * Parse the first document in the buffer. Used by begin(), to handle allocation and + * initialization. + */ + inline void start() noexcept; + + /** + * Parse the next document found in the buffer previously given to document_stream. + * + * The content should be a valid JSON document encoded as UTF-8. If there is a + * UTF-8 BOM, the parser skips it. + * + * You do NOT need to pre-allocate a parser. This function takes care of + * pre-allocating a capacity defined by the batch_size defined when creating the + * document_stream object. + * + * The function returns simdjson::EMPTY if there is no more data to be parsed. + * + * The function returns simdjson::SUCCESS (as integer = 0) in case of success + * and indicates that the buffer has successfully been parsed to the end. + * Every document it contained has been parsed without error. + * + * The function returns an error code from simdjson/simdjson.h in case of failure + * such as simdjson::CAPACITY, simdjson::MEMALLOC, simdjson::DEPTH_ERROR and so forth; + * the simdjson::error_message function converts these error codes into a string). + * + * You can also check validity by calling parser.is_valid(). The same parser can + * and should be reused for the other documents in the buffer. + */ + inline void next() noexcept; + + /** Move the json_iterator of the document to the location of the next document in the stream. */ + inline void next_document() noexcept; + + /** Get the next document index. */ + inline size_t next_batch_start() const noexcept; + + /** Pass the next batch through stage 1 with the given parser. */ + inline error_code run_stage1(ondemand::parser& p, size_t batch_start) noexcept; + + // Fields + ondemand::parser* parser; + const uint8_t* buf; + size_t len; + size_t batch_size; + bool allow_comma_separated; + /** + * We are going to use just one document instance. The document owns + * the json_iterator. It implies that we only ever pass a reference + * to the document to the users. + */ + document doc{}; + /** The error (or lack thereof) from the current document. */ error_code error; - // PERF NOTE this is a safety rail ... users should exit loops as soon as they receive an error, so we'll never get here. - // However, it does not seem to make a perf difference, so we add it out of an abundance of caution. - if ((error = iter.error())) { return *this; } - if ((error = iter.skip_child())) { return *this; } - if ((error = iter.has_next_element().error())) { return *this; } - return *this; - } + size_t batch_start{ 0 }; + size_t doc_index{}; + +#ifdef SIMDJSON_THREADS_ENABLED + /** Indicates whether we use threads. Note that this needs to be a constant during the execution of the parsing. */ + bool use_thread; + + inline void load_from_stage1_thread() noexcept; + + /** Start a thread to run stage 1 on the next batch. */ + inline void start_stage1_thread() noexcept; + + /** Wait for the stage 1 thread to finish and capture the results. */ + inline void finish_stage1_thread() noexcept; + + /** The error returned from the stage 1 thread. */ + error_code stage1_thread_error{ UNINITIALIZED }; + /** The thread used to run stage 1 against the next batch in the background. */ + std::unique_ptr worker{ new(std::nothrow) stage1_worker() }; + /** + * The parser used to run stage 1 in the background. Will be swapped + * with the regular parser when finished. + */ + ondemand::parser stage1_thread_parser{}; + + friend struct stage1_worker; +#endif // SIMDJSON_THREADS_ENABLED + + friend class parser; + friend class document; + friend class json_iterator; + friend struct simdjson_result; + friend struct internal::simdjson_result_base; + }; // document_stream } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace fallback } // namespace simdjson namespace simdjson { - - simdjson_inline simdjson_result::simdjson_result( - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array_iterator&& value - ) noexcept - : SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base(std::forward(value)) - { - first.iter.assert_is_valid(); - } - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : SIMDJSON_BUILTIN_IMPLEMENTATION::implementation_simdjson_result_base({}, error) - { - } - - simdjson_inline simdjson_result simdjson_result::operator*() noexcept { - if (error()) { return error(); } - return *first; - } - simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { - if (!first.iter.is_valid()) { return !error(); } - return first == other.first; - } - simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { - if (!first.iter.is_valid()) { return error(); } - return first != other.first; - } - simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { - // Clear the error if there is one, so we don't yield it twice - if (error()) { second = SUCCESS; return *this; } - ++(first); - return *this; - } + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::document_stream&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/array_iterator-inl.h */ -/* begin file include/simdjson/generic/ondemand/object_iterator-inl.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H +/* end file simdjson/generic/ondemand/document_stream.h for fallback */ +/* including simdjson/generic/ondemand/field.h for fallback: #include "simdjson/generic/ondemand/field.h" */ +/* begin file simdjson/generic/ondemand/field.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace fallback { namespace ondemand { - // - // object_iterator - // + /** + * A JSON field (key/value pair) in an object. + * + * Returned from object iteration. + * + * Extends from std::pair so you can use C++ algorithms that rely on pairs. + */ + class field : public std::pair { + public: + /** + * Create a new invalid field. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline field() noexcept; - simdjson_inline object_iterator::object_iterator(const value_iterator& _iter) noexcept - : iter{ _iter } - {} + /** + * Get the key as a string_view (for higher speed, consider raw_key). + * We deliberately use a more cumbersome name (unescaped_key) to force users + * to think twice about using it. + * + * This consumes the key: once you have called unescaped_key(), you cannot + * call it again nor can you call key(). + */ + simdjson_inline simdjson_warn_unused simdjson_result unescaped_key(bool allow_replacement) noexcept; + /** + * Get the key as a raw_json_string. Can be used for direct comparison with + * an unescaped C string: e.g., key() == "test". + */ + simdjson_inline raw_json_string key() const noexcept; + /** + * Get the field value. + */ + simdjson_inline ondemand::value& value() & noexcept; + /** + * @overload ondemand::value &ondemand::value() & noexcept + */ + simdjson_inline ondemand::value value() && noexcept; - simdjson_inline simdjson_result object_iterator::operator*() noexcept { - error_code error = iter.error(); - if (error) { iter.abandon(); return error; } - auto result = field::start(iter); - // TODO this is a safety rail ... users should exit loops as soon as they receive an error. - // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. - if (result.error()) { iter.abandon(); } - return result; - } - simdjson_inline bool object_iterator::operator==(const object_iterator& other) const noexcept { - return !(*this != other); - } - simdjson_inline bool object_iterator::operator!=(const object_iterator&) const noexcept { - return iter.is_open(); - } - - SIMDJSON_PUSH_DISABLE_WARNINGS - SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING - simdjson_inline object_iterator& object_iterator::operator++() noexcept { - // TODO this is a safety rail ... users should exit loops as soon as they receive an error. - // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. - if (!iter.is_open()) { return *this; } // Iterator will be released if there is an error - - simdjson_unused error_code error; - if ((error = iter.skip_child())) { return *this; } - - simdjson_unused bool has_value; - if ((error = iter.has_next_field().get(has_value))) { return *this; }; - return *this; - } - SIMDJSON_POP_DISABLE_WARNINGS - - // - // ### Live States - // - // While iterating or looking up values, depth >= iter.depth. at_start may vary. Error is - // always SUCCESS: - // - // - Start: This is the state when the object is first found and the iterator is just past the {. - // In this state, at_start == true. - // - Next: After we hand a scalar value to the user, or an array/object which they then fully - // iterate over, the iterator is at the , or } before the next value. In this state, - // depth == iter.depth, at_start == false, and error == SUCCESS. - // - Unfinished Business: When we hand an array/object to the user which they do not fully - // iterate over, we need to finish that iteration by skipping child values until we reach the - // Next state. In this state, depth > iter.depth, at_start == false, and error == SUCCESS. - // - // ## Error States - // - // In error states, we will yield exactly one more value before stopping. iter.depth == depth - // and at_start is always false. We decrement after yielding the error, moving to the Finished - // state. - // - // - Chained Error: When the object iterator is part of an error chain--for example, in - // `for (auto tweet : doc["tweets"])`, where the tweet field may be missing or not be an - // object--we yield that error in the loop, exactly once. In this state, error != SUCCESS and - // iter.depth == depth, and at_start == false. We decrement depth when we yield the error. - // - Missing Comma Error: When the iterator ++ method discovers there is no comma between fields, - // we flag that as an error and treat it exactly the same as a Chained Error. In this state, - // error == TAPE_ERROR, iter.depth == depth, and at_start == false. - // - // Errors that occur while reading a field to give to the user (such as when the key is not a - // string or the field is missing a colon) are yielded immediately. Depth is then decremented, - // moving to the Finished state without transitioning through an Error state at all. - // - // ## Terminal State - // - // The terminal state has iter.depth < depth. at_start is always false. - // - // - Finished: When we have reached a }, we are finished. We signal this by decrementing depth. - // In this state, iter.depth < depth, at_start == false, and error == SUCCESS. - // + protected: + simdjson_inline field(raw_json_string key, ondemand::value&& value) noexcept; + static simdjson_inline simdjson_result start(value_iterator& parent_iter) noexcept; + static simdjson_inline simdjson_result start(const value_iterator& parent_iter, raw_json_string key) noexcept; + friend struct simdjson_result; + friend class object_iterator; + }; } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace fallback } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result( - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object_iterator&& value - ) noexcept - : implementation_simdjson_result_base(std::forward(value)) - { - first.iter.assert_is_valid(); - } - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base({}, error) - { - } + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::field&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; - simdjson_inline simdjson_result simdjson_result::operator*() noexcept { - if (error()) { return error(); } - return *first; - } - // If we're iterating and there is an error, return the error once. - simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { - if (!first.iter.is_valid()) { return !error(); } - return first == other.first; - } - // If we're iterating and there is an error, return the error once. - simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { - if (!first.iter.is_valid()) { return error(); } - return first != other.first; - } - // Checks for ']' and ',' - simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { - // Clear the error if there is one, so we don't yield it twice - if (error()) { second = SUCCESS; return *this; } - ++first; - return *this; - } + simdjson_inline simdjson_result unescaped_key(bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result key() noexcept; + simdjson_inline simdjson_result value() noexcept; + }; } // namespace simdjson -/* end file include/simdjson/generic/ondemand/object_iterator-inl.h */ -/* begin file include/simdjson/generic/ondemand/array-inl.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_H +/* end file simdjson/generic/ondemand/field.h for fallback */ +/* including simdjson/generic/ondemand/object.h for fallback: #include "simdjson/generic/ondemand/object.h" */ +/* begin file simdjson/generic/ondemand/object.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace fallback { + namespace ondemand { + + /** + * A forward-only JSON object field iterator. + */ + class object { + public: + /** + * Create a new invalid object. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a + * key a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an object + * instance: there is no rewind and no invalidation. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + /** + * Reset the iterator so that we are pointing back at the + * beginning of the object. You should still consume values only once even if you + * can iterate through the object more than once. If you unescape a string within + * the object more than once, you have unsafe code. Note that rewinding an object + * means that you may need to reparse it anew: it is not a free operation. + * + * @returns true if the object contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * This method scans the beginning of the object and checks whether the + * object is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + inline simdjson_result is_empty() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Consumes the object and returns a string_view instance corresponding to the + * object as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + protected: + /** + * Go to the end of the object, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + static simdjson_inline object resume(const value_iterator& iter) noexcept; + simdjson_inline object(const value_iterator& iter) noexcept; + + simdjson_warn_unused simdjson_inline error_code find_field_raw(const std::string_view key) noexcept; + + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::object&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + inline simdjson_result reset() noexcept; + inline simdjson_result is_empty() noexcept; + inline simdjson_result count_fields() & noexcept; + inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_H +/* end file simdjson/generic/ondemand/object.h for fallback */ +/* including simdjson/generic/ondemand/object_iterator.h for fallback: #include "simdjson/generic/ondemand/object_iterator.h" */ +/* begin file simdjson/generic/ondemand/object_iterator.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + class object_iterator { + public: + /** + * Create a new invalid object_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object_iterator() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline simdjson_result operator*() noexcept; + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const object_iterator&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const object_iterator&) const noexcept; + // Checks for ']' and ',' + simdjson_inline object_iterator& operator++() noexcept; + + private: + /** + * The underlying JSON iterator. + * + * PERF NOTE: expected to be elided in favor of the parent document: this is set when the object + * is first used, and never changes afterwards. + */ + value_iterator iter{}; + + simdjson_inline object_iterator(const value_iterator& iter) noexcept; + friend struct simdjson_result; + friend class object; + }; + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public fallback::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(fallback::ondemand::object_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + // Checks for ']' and ',' + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H +/* end file simdjson/generic/ondemand/object_iterator.h for fallback */ +/* including simdjson/generic/ondemand/serialization.h for fallback: #include "simdjson/generic/ondemand/serialization.h" */ +/* begin file simdjson/generic/ondemand/serialization.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Create a string-view instance out of a document instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(fallback::ondemand::document& x) noexcept; + /** + * Create a string-view instance out of a value instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. The value must + * not have been accessed previously. It does not + * validate the content. + */ + inline simdjson_result to_json_string(fallback::ondemand::value& x) noexcept; + /** + * Create a string-view instance out of an object instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(fallback::ondemand::object& x) noexcept; + /** + * Create a string-view instance out of an array instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(fallback::ondemand::array& x) noexcept; + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); +} // namespace simdjson + +/** + * We want to support argument-dependent lookup (ADL). + * Hence we should define operator<< in the namespace + * where the argument (here value, object, etc.) resides. + * Credit: @madhur4127 + * See https://github.com/simdjson/simdjson/issues/1768 + */ +namespace simdjson { + namespace fallback { + namespace ondemand { + + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The element. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::value x); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::array value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::document& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::document_reference& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The object. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::object value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + } + } +} // namespace simdjson::fallback::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H +/* end file simdjson/generic/ondemand/serialization.h for fallback */ + +// Inline definitions +/* including simdjson/generic/ondemand/array-inl.h for fallback: #include "simdjson/generic/ondemand/array-inl.h" */ +/* begin file simdjson/generic/ondemand/array-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { namespace ondemand { // @@ -29662,55 +41582,159 @@ namespace simdjson { } } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace fallback } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result( - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array&& value + simdjson_inline simdjson_result::simdjson_result( + fallback::ondemand::array&& value ) noexcept - : implementation_simdjson_result_base( - std::forward(value) + : implementation_simdjson_result_base( + std::forward(value) ) { } - simdjson_inline simdjson_result::simdjson_result( + simdjson_inline simdjson_result::simdjson_result( error_code error ) noexcept - : implementation_simdjson_result_base(error) + : implementation_simdjson_result_base(error) { } - simdjson_inline simdjson_result simdjson_result::begin() noexcept { + simdjson_inline simdjson_result simdjson_result::begin() noexcept { if (error()) { return error(); } return first.begin(); } - simdjson_inline simdjson_result simdjson_result::end() noexcept { + simdjson_inline simdjson_result simdjson_result::end() noexcept { if (error()) { return error(); } return first.end(); } - simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { if (error()) { return error(); } return first.count_elements(); } - simdjson_inline simdjson_result simdjson_result::is_empty() & noexcept { + simdjson_inline simdjson_result simdjson_result::is_empty() & noexcept { if (error()) { return error(); } return first.is_empty(); } - simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { if (error()) { return error(); } return first.at(index); } - simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { if (error()) { return error(); } return first.at_pointer(json_pointer); } + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } } // namespace simdjson -/* end file include/simdjson/generic/ondemand/array-inl.h */ -/* begin file include/simdjson/generic/ondemand/document-inl.h */ + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H +/* end file simdjson/generic/ondemand/array-inl.h for fallback */ +/* including simdjson/generic/ondemand/array_iterator-inl.h for fallback: #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/array_iterator-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace fallback { + namespace ondemand { + + simdjson_inline array_iterator::array_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result array_iterator::operator*() noexcept { + if (iter.error()) { iter.abandon(); return iter.error(); } + return value(iter.child()); + } + simdjson_inline bool array_iterator::operator==(const array_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool array_iterator::operator!=(const array_iterator&) const noexcept { + return iter.is_open(); + } + simdjson_inline array_iterator& array_iterator::operator++() noexcept { + error_code error; + // PERF NOTE this is a safety rail ... users should exit loops as soon as they receive an error, so we'll never get here. + // However, it does not seem to make a perf difference, so we add it out of an abundance of caution. + if ((error = iter.error())) { return *this; } + if ((error = iter.skip_child())) { return *this; } + if ((error = iter.has_next_element().error())) { return *this; } + return *this; + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + fallback::ondemand::array_iterator&& value + ) noexcept + : fallback::implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : fallback::implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++(first); + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/array_iterator-inl.h for fallback */ +/* including simdjson/generic/ondemand/document-inl.h for fallback: #include "simdjson/generic/ondemand/document-inl.h" */ +/* begin file simdjson/generic/ondemand/document-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { namespace ondemand { simdjson_inline document::document(ondemand::json_iterator&& _iter) noexcept @@ -29731,7 +41755,7 @@ namespace simdjson { return iter.to_string(); } - inline simdjson_result document::current_location() noexcept { + inline simdjson_result document::current_location() const noexcept { return iter.current_location(); } @@ -29739,6 +41763,11 @@ namespace simdjson { return iter.depth(); } + inline bool document::at_end() const noexcept { + return iter.at_end(); + } + + inline bool document::is_alive() noexcept { return iter.is_alive(); } @@ -29759,16 +41788,36 @@ namespace simdjson { simdjson_inline simdjson_result document::get_value() noexcept { // Make sure we start any arrays or objects before returning, so that start_root_() // gets called. - iter.assert_at_document_depth(); + + // It is the convention throughout the code that the macro `SIMDJSON_DEVELOPMENT_CHECKS` determines whether + // we check for OUT_OF_ORDER_ITERATION. Proper on::demand code should never trigger this error. +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.at_root()) { return OUT_OF_ORDER_ITERATION; } +#endif + // assert_at_root() serves two purposes: in Debug mode, whether or not + // SIMDJSON_DEVELOPMENT_CHECKS is set or not, it checks that we are at the root of + // the document (this will typically be redundant). In release mode, it generates + // SIMDJSON_ASSUME statements to allow the compiler to make assumptions. + iter.assert_at_root(); switch (*iter.peek()) { - case '[': - case '{': + case '[': { + // The following lines check that the document ends with ]. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_array(); + if (error) { return error; } return value(get_root_value_iterator()); + } + case '{': { + // The following lines would check that the document ends with }. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_object(); + if (error) { return error; } + return value(get_root_value_iterator()); + } default: // Unfortunately, scalar documents are a special case in simdjson and they cannot // be safely converted to value instances. return SCALAR_DOCUMENT_AS_VALUE; - // return value(get_root_value_iterator()); } } simdjson_inline simdjson_result document::get_array() & noexcept { @@ -29809,6 +41858,10 @@ namespace simdjson { simdjson_inline simdjson_result document::get_string(bool allow_replacement) noexcept { return get_root_value_iterator().get_root_string(true, allow_replacement); } + template + simdjson_inline error_code document::get_string(string_type& receiver, bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(receiver, true, allow_replacement); + } simdjson_inline simdjson_result document::get_wobbly_string() noexcept { return get_root_value_iterator().get_root_wobbly_string(true); } @@ -29973,253 +42026,264 @@ namespace simdjson { } } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace fallback } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result( - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document&& value + simdjson_inline simdjson_result::simdjson_result( + fallback::ondemand::document&& value ) noexcept : - implementation_simdjson_result_base( - std::forward(value) + implementation_simdjson_result_base( + std::forward(value) ) { } - simdjson_inline simdjson_result::simdjson_result( + simdjson_inline simdjson_result::simdjson_result( error_code error ) noexcept : - implementation_simdjson_result_base( + implementation_simdjson_result_base( error ) { } - simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { if (error()) { return error(); } return first.count_elements(); } - simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { if (error()) { return error(); } return first.count_fields(); } - simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { if (error()) { return error(); } return first.at(index); } - simdjson_inline error_code simdjson_result::rewind() noexcept { + simdjson_inline error_code simdjson_result::rewind() noexcept { if (error()) { return error(); } first.rewind(); return SUCCESS; } - simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { if (error()) { return error(); } return first.begin(); } - simdjson_inline simdjson_result simdjson_result::end() & noexcept { + simdjson_inline simdjson_result simdjson_result::end() & noexcept { return {}; } - simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { if (error()) { return error(); } return first.find_field_unordered(key); } - simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { if (error()) { return error(); } return first.find_field_unordered(key); } - simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { if (error()) { return error(); } return first[key]; } - simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { if (error()) { return error(); } return first[key]; } - simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { if (error()) { return error(); } return first.find_field(key); } - simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { if (error()) { return error(); } return first.find_field(key); } - simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { if (error()) { return error(); } return first.get_array(); } - simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { if (error()) { return error(); } return first.get_object(); } - simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { if (error()) { return error(); } return first.get_uint64(); } - simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { if (error()) { return error(); } return first.get_uint64_in_string(); } - simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { if (error()) { return error(); } return first.get_int64(); } - simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { if (error()) { return error(); } return first.get_int64_in_string(); } - simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { if (error()) { return error(); } return first.get_double(); } - simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { if (error()) { return error(); } return first.get_double_in_string(); } - simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { if (error()) { return error(); } return first.get_string(allow_replacement); } - simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { if (error()) { return error(); } return first.get_wobbly_string(); } - simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { if (error()) { return error(); } return first.get_raw_json_string(); } - simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { if (error()) { return error(); } return first.get_bool(); } - simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { if (error()) { return error(); } return first.get_value(); } - simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { if (error()) { return error(); } return first.is_null(); } template - simdjson_inline simdjson_result simdjson_result::get() & noexcept { + simdjson_inline simdjson_result simdjson_result::get() & noexcept { if (error()) { return error(); } return first.get(); } template - simdjson_inline simdjson_result simdjson_result::get() && noexcept { + simdjson_inline simdjson_result simdjson_result::get() && noexcept { if (error()) { return error(); } - return std::forward(first).get(); + return std::forward(first).get(); } template - simdjson_inline error_code simdjson_result::get(T& out) & noexcept { + simdjson_inline error_code simdjson_result::get(T& out) & noexcept { if (error()) { return error(); } return first.get(out); } template - simdjson_inline error_code simdjson_result::get(T& out) && noexcept { + simdjson_inline error_code simdjson_result::get(T& out) && noexcept { if (error()) { return error(); } - return std::forward(first).get(out); + return std::forward(first).get(out); } - template<> simdjson_inline simdjson_result simdjson_result::get() & noexcept = delete; - template<> simdjson_inline simdjson_result simdjson_result::get() && noexcept { + template<> simdjson_inline simdjson_result simdjson_result::get() & noexcept = delete; + template<> simdjson_inline simdjson_result simdjson_result::get() && noexcept { if (error()) { return error(); } - return std::forward(first); + return std::forward(first); } - template<> simdjson_inline error_code simdjson_result::get(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document& out) & noexcept = delete; - template<> simdjson_inline error_code simdjson_result::get(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document& out) && noexcept { + template<> simdjson_inline error_code simdjson_result::get(fallback::ondemand::document& out) & noexcept = delete; + template<> simdjson_inline error_code simdjson_result::get(fallback::ondemand::document& out) && noexcept { if (error()) { return error(); } - out = std::forward(first); + out = std::forward(first); return SUCCESS; } - simdjson_inline simdjson_result simdjson_result::type() noexcept { + simdjson_inline simdjson_result simdjson_result::type() noexcept { if (error()) { return error(); } return first.type(); } - simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { if (error()) { return error(); } return first.is_scalar(); } - simdjson_inline bool simdjson_result::is_negative() noexcept { + simdjson_inline bool simdjson_result::is_negative() noexcept { if (error()) { return error(); } return first.is_negative(); } - simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { if (error()) { return error(); } return first.is_integer(); } - simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { if (error()) { return error(); } return first.get_number_type(); } - simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { if (error()) { return error(); } return first.get_number(); } #if SIMDJSON_EXCEPTIONS - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array() & noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::array() & noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object() & noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::object() & noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator double() noexcept(false) { + simdjson_inline simdjson_result::operator double() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string() noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::raw_json_string() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator bool() noexcept(false) { + simdjson_inline simdjson_result::operator bool() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value() noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::value() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } #endif - simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { if (error()) { return error(); } return first.current_location(); } - simdjson_inline int32_t simdjson_result::current_depth() const noexcept { + simdjson_inline bool simdjson_result::at_end() const noexcept { + if (error()) { return error(); } + return first.at_end(); + } + + + simdjson_inline int32_t simdjson_result::current_depth() const noexcept { if (error()) { return error(); } return first.current_depth(); } - simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { if (error()) { return error(); } return first.raw_json_token(); } - simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { if (error()) { return error(); } return first.at_pointer(json_pointer); } @@ -30229,7 +42293,7 @@ namespace simdjson { namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace fallback { namespace ondemand { simdjson_inline document_reference::document_reference() noexcept : doc{ nullptr } {} @@ -30258,6 +42322,8 @@ namespace simdjson { simdjson_inline simdjson_result document_reference::get_double() noexcept { return doc->get_root_value_iterator().get_root_double(false); } simdjson_inline simdjson_result document_reference::get_double_in_string() noexcept { return doc->get_root_value_iterator().get_root_double(false); } simdjson_inline simdjson_result document_reference::get_string(bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(false, allow_replacement); } + template + simdjson_inline error_code document_reference::get_string(string_type& receiver, bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(receiver, false, allow_replacement); } simdjson_inline simdjson_result document_reference::get_wobbly_string() noexcept { return doc->get_root_value_iterator().get_root_wobbly_string(false); } simdjson_inline simdjson_result document_reference::get_raw_json_string() noexcept { return doc->get_root_value_iterator().get_root_raw_json_string(false); } simdjson_inline simdjson_result document_reference::get_bool() noexcept { return doc->get_root_value_iterator().get_root_bool(false); } @@ -30300,1095 +42366,225 @@ namespace simdjson { simdjson_inline document_reference::operator document& () const noexcept { return *doc; } } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace fallback } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document_reference value, error_code error) - noexcept : implementation_simdjson_result_base(std::forward(value), error) {} + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::document_reference value, error_code error) + noexcept : implementation_simdjson_result_base(std::forward(value), error) {} - simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { if (error()) { return error(); } return first.count_elements(); } - simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { if (error()) { return error(); } return first.count_fields(); } - simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { if (error()) { return error(); } return first.at(index); } - simdjson_inline error_code simdjson_result::rewind() noexcept { + simdjson_inline error_code simdjson_result::rewind() noexcept { if (error()) { return error(); } first.rewind(); return SUCCESS; } - simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { if (error()) { return error(); } return first.begin(); } - simdjson_inline simdjson_result simdjson_result::end() & noexcept { + simdjson_inline simdjson_result simdjson_result::end() & noexcept { return {}; } - simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { if (error()) { return error(); } return first.find_field_unordered(key); } - simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { if (error()) { return error(); } return first.find_field_unordered(key); } - simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { if (error()) { return error(); } return first[key]; } - simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { if (error()) { return error(); } return first[key]; } - simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { if (error()) { return error(); } return first.find_field(key); } - simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { if (error()) { return error(); } return first.find_field(key); } - simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { if (error()) { return error(); } return first.get_array(); } - simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { if (error()) { return error(); } return first.get_object(); } - simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { if (error()) { return error(); } return first.get_uint64(); } - simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { if (error()) { return error(); } return first.get_uint64_in_string(); } - simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { if (error()) { return error(); } return first.get_int64(); } - simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { if (error()) { return error(); } return first.get_int64_in_string(); } - simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { if (error()) { return error(); } return first.get_double(); } - simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { if (error()) { return error(); } return first.get_double_in_string(); } - simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { if (error()) { return error(); } return first.get_string(allow_replacement); } - simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { if (error()) { return error(); } return first.get_wobbly_string(); } - simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { if (error()) { return error(); } return first.get_raw_json_string(); } - simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { if (error()) { return error(); } return first.get_bool(); } - simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { if (error()) { return error(); } return first.get_value(); } - simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { if (error()) { return error(); } return first.is_null(); } - simdjson_inline simdjson_result simdjson_result::type() noexcept { + simdjson_inline simdjson_result simdjson_result::type() noexcept { if (error()) { return error(); } return first.type(); } - simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { if (error()) { return error(); } return first.is_scalar(); } - simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { if (error()) { return error(); } return first.is_negative(); } - simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { if (error()) { return error(); } return first.is_integer(); } - simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { if (error()) { return error(); } return first.get_number_type(); } - simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { if (error()) { return error(); } return first.get_number(); } #if SIMDJSON_EXCEPTIONS - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array() & noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::array() & noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object() & noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::object() & noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator double() noexcept(false) { + simdjson_inline simdjson_result::operator double() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string() noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::raw_json_string() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator bool() noexcept(false) { + simdjson_inline simdjson_result::operator bool() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value() noexcept(false) { + simdjson_inline simdjson_result::operator fallback::ondemand::value() noexcept(false) { if (error()) { throw simdjson_error(error()); } return first; } #endif - simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { if (error()) { return error(); } return first.current_location(); } - simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { if (error()) { return error(); } return first.raw_json_token(); } - simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { if (error()) { return error(); } return first.at_pointer(json_pointer); } } // namespace simdjson -/* end file include/simdjson/generic/ondemand/document-inl.h */ -/* begin file include/simdjson/generic/ondemand/value-inl.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - simdjson_inline value::value(const value_iterator& _iter) noexcept - : iter{ _iter } - { - } - simdjson_inline value value::start(const value_iterator& iter) noexcept { - return iter; - } - simdjson_inline value value::resume(const value_iterator& iter) noexcept { - return iter; - } +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H +/* end file simdjson/generic/ondemand/document-inl.h for fallback */ +/* including simdjson/generic/ondemand/document_stream-inl.h for fallback: #include "simdjson/generic/ondemand/document_stream-inl.h" */ +/* begin file simdjson/generic/ondemand/document_stream-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H - simdjson_inline simdjson_result value::get_array() noexcept { - return array::start(iter); - } - simdjson_inline simdjson_result value::get_object() noexcept { - return object::start(iter); - } - simdjson_inline simdjson_result value::start_or_resume_object() noexcept { - if (iter.at_start()) { - return get_object(); - } - else { - return object::resume(iter); - } - } +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ - simdjson_inline simdjson_result value::get_raw_json_string() noexcept { - return iter.get_raw_json_string(); - } - simdjson_inline simdjson_result value::get_string(bool allow_replacement) noexcept { - return iter.get_string(allow_replacement); - } - simdjson_inline simdjson_result value::get_wobbly_string() noexcept { - return iter.get_wobbly_string(); - } - simdjson_inline simdjson_result value::get_double() noexcept { - return iter.get_double(); - } - simdjson_inline simdjson_result value::get_double_in_string() noexcept { - return iter.get_double_in_string(); - } - simdjson_inline simdjson_result value::get_uint64() noexcept { - return iter.get_uint64(); - } - simdjson_inline simdjson_result value::get_uint64_in_string() noexcept { - return iter.get_uint64_in_string(); - } - simdjson_inline simdjson_result value::get_int64() noexcept { - return iter.get_int64(); - } - simdjson_inline simdjson_result value::get_int64_in_string() noexcept { - return iter.get_int64_in_string(); - } - simdjson_inline simdjson_result value::get_bool() noexcept { - return iter.get_bool(); - } - simdjson_inline simdjson_result value::is_null() noexcept { - return iter.is_null(); - } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_array(); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_object(); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_raw_json_string(); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_string(false); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_number(); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_double(); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_uint64(); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_int64(); } - template<> simdjson_inline simdjson_result value::get() noexcept { return get_bool(); } - - template simdjson_inline error_code value::get(T& out) noexcept { - return get().get(out); - } - -#if SIMDJSON_EXCEPTIONS - simdjson_inline value::operator array() noexcept(false) { - return get_array(); - } - simdjson_inline value::operator object() noexcept(false) { - return get_object(); - } - simdjson_inline value::operator uint64_t() noexcept(false) { - return get_uint64(); - } - simdjson_inline value::operator int64_t() noexcept(false) { - return get_int64(); - } - simdjson_inline value::operator double() noexcept(false) { - return get_double(); - } - simdjson_inline value::operator std::string_view() noexcept(false) { - return get_string(false); - } - simdjson_inline value::operator raw_json_string() noexcept(false) { - return get_raw_json_string(); - } - simdjson_inline value::operator bool() noexcept(false) { - return get_bool(); - } -#endif - - simdjson_inline simdjson_result value::begin() & noexcept { - return get_array().begin(); - } - simdjson_inline simdjson_result value::end() & noexcept { - return {}; - } - simdjson_inline simdjson_result value::count_elements() & noexcept { - simdjson_result answer; - auto a = get_array(); - answer = a.count_elements(); - // count_elements leaves you pointing inside the array, at the first element. - // We need to move back so that the user can create a new array (which requires that - // we point at '['). - iter.move_at_start(); - return answer; - } - simdjson_inline simdjson_result value::count_fields() & noexcept { - simdjson_result answer; - auto a = get_object(); - answer = a.count_fields(); - iter.move_at_start(); - return answer; - } - simdjson_inline simdjson_result value::at(size_t index) noexcept { - auto a = get_array(); - return a.at(index); - } - - simdjson_inline simdjson_result value::find_field(std::string_view key) noexcept { - return start_or_resume_object().find_field(key); - } - simdjson_inline simdjson_result value::find_field(const char* key) noexcept { - return start_or_resume_object().find_field(key); - } - - simdjson_inline simdjson_result value::find_field_unordered(std::string_view key) noexcept { - return start_or_resume_object().find_field_unordered(key); - } - simdjson_inline simdjson_result value::find_field_unordered(const char* key) noexcept { - return start_or_resume_object().find_field_unordered(key); - } - - simdjson_inline simdjson_result value::operator[](std::string_view key) noexcept { - return start_or_resume_object()[key]; - } - simdjson_inline simdjson_result value::operator[](const char* key) noexcept { - return start_or_resume_object()[key]; - } - - simdjson_inline simdjson_result value::type() noexcept { - return iter.type(); - } - - simdjson_inline simdjson_result value::is_scalar() noexcept { - json_type this_type; - auto error = type().get(this_type); - if (error) { return error; } - return !((this_type == json_type::array) || (this_type == json_type::object)); - } - - simdjson_inline bool value::is_negative() noexcept { - return iter.is_negative(); - } - - simdjson_inline simdjson_result value::is_integer() noexcept { - return iter.is_integer(); - } - simdjson_warn_unused simdjson_inline simdjson_result value::get_number_type() noexcept { - return iter.get_number_type(); - } - simdjson_warn_unused simdjson_inline simdjson_result value::get_number() noexcept { - return iter.get_number(); - } - - simdjson_inline std::string_view value::raw_json_token() noexcept { - return std::string_view(reinterpret_cast(iter.peek_start()), iter.peek_start_length()); - } - - simdjson_inline simdjson_result value::current_location() noexcept { - return iter.json_iter().current_location(); - } - - simdjson_inline int32_t value::current_depth() const noexcept { - return iter.json_iter().depth(); - } - - simdjson_inline simdjson_result value::at_pointer(std::string_view json_pointer) noexcept { - json_type t; - SIMDJSON_TRY(type().get(t)); - switch (t) - { - case json_type::array: - return (*this).get_array().at_pointer(json_pointer); - case json_type::object: - return (*this).get_object().at_pointer(json_pointer); - default: - return INVALID_JSON_POINTER; - } - } - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - simdjson_inline simdjson_result::simdjson_result( - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value&& value - ) noexcept : - implementation_simdjson_result_base( - std::forward(value) - ) - { - } - simdjson_inline simdjson_result::simdjson_result( - error_code error - ) noexcept : - implementation_simdjson_result_base(error) - { - } - simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { - if (error()) { return error(); } - return first.count_elements(); - } - simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { - if (error()) { return error(); } - return first.count_fields(); - } - simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { - if (error()) { return error(); } - return first.at(index); - } - simdjson_inline simdjson_result simdjson_result::begin() & noexcept { - if (error()) { return error(); } - return first.begin(); - } - simdjson_inline simdjson_result simdjson_result::end() & noexcept { - if (error()) { return error(); } - return {}; - } - - simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) noexcept { - if (error()) { return error(); } - return first.find_field(key); - } - simdjson_inline simdjson_result simdjson_result::find_field(const char* key) noexcept { - if (error()) { return error(); } - return first.find_field(key); - } - - simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) noexcept { - if (error()) { return error(); } - return first.find_field_unordered(key); - } - simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) noexcept { - if (error()) { return error(); } - return first.find_field_unordered(key); - } - - simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) noexcept { - if (error()) { return error(); } - return first[key]; - } - simdjson_inline simdjson_result simdjson_result::operator[](const char* key) noexcept { - if (error()) { return error(); } - return first[key]; - } - - simdjson_inline simdjson_result simdjson_result::get_array() noexcept { - if (error()) { return error(); } - return first.get_array(); - } - simdjson_inline simdjson_result simdjson_result::get_object() noexcept { - if (error()) { return error(); } - return first.get_object(); - } - simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { - if (error()) { return error(); } - return first.get_uint64(); - } - simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { - if (error()) { return error(); } - return first.get_uint64_in_string(); - } - simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { - if (error()) { return error(); } - return first.get_int64(); - } - simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { - if (error()) { return error(); } - return first.get_int64_in_string(); - } - simdjson_inline simdjson_result simdjson_result::get_double() noexcept { - if (error()) { return error(); } - return first.get_double(); - } - simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { - if (error()) { return error(); } - return first.get_double_in_string(); - } - simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { - if (error()) { return error(); } - return first.get_string(allow_replacement); - } - simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { - if (error()) { return error(); } - return first.get_wobbly_string(); - } - simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { - if (error()) { return error(); } - return first.get_raw_json_string(); - } - simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { - if (error()) { return error(); } - return first.get_bool(); - } - simdjson_inline simdjson_result simdjson_result::is_null() noexcept { - if (error()) { return error(); } - return first.is_null(); - } - - template simdjson_inline simdjson_result simdjson_result::get() noexcept { - if (error()) { return error(); } - return first.get(); - } - template simdjson_inline error_code simdjson_result::get(T& out) noexcept { - if (error()) { return error(); } - return first.get(out); - } - - template<> simdjson_inline simdjson_result simdjson_result::get() noexcept { - if (error()) { return error(); } - return std::move(first); - } - template<> simdjson_inline error_code simdjson_result::get(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value& out) noexcept { - if (error()) { return error(); } - out = first; - return SUCCESS; - } - - simdjson_inline simdjson_result simdjson_result::type() noexcept { - if (error()) { return error(); } - return first.type(); - } - simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { - if (error()) { return error(); } - return first.is_scalar(); - } - simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { - if (error()) { return error(); } - return first.is_negative(); - } - simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { - if (error()) { return error(); } - return first.is_integer(); - } - simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { - if (error()) { return error(); } - return first.get_number_type(); - } - simdjson_inline simdjson_result simdjson_result::get_number() noexcept { - if (error()) { return error(); } - return first.get_number(); - } -#if SIMDJSON_EXCEPTIONS - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } - simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } - simdjson_inline simdjson_result::operator int64_t() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } - simdjson_inline simdjson_result::operator double() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } - simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } - simdjson_inline simdjson_result::operator SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::raw_json_string() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } - simdjson_inline simdjson_result::operator bool() noexcept(false) { - if (error()) { throw simdjson_error(error()); } - return first; - } -#endif - - simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { - if (error()) { return error(); } - return first.raw_json_token(); - } - - simdjson_inline simdjson_result simdjson_result::current_location() noexcept { - if (error()) { return error(); } - return first.current_location(); - } - - simdjson_inline simdjson_result simdjson_result::current_depth() const noexcept { - if (error()) { return error(); } - return first.current_depth(); - } - - simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { - if (error()) { return error(); } - return first.at_pointer(json_pointer); - } - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/value-inl.h */ -/* begin file include/simdjson/generic/ondemand/field-inl.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - // clang 6 doesn't think the default constructor can be noexcept, so we make it explicit - simdjson_inline field::field() noexcept : std::pair() {} - - simdjson_inline field::field(raw_json_string key, ondemand::value&& value) noexcept - : std::pair(key, std::forward(value)) - { - } - - simdjson_inline simdjson_result field::start(value_iterator& parent_iter) noexcept { - raw_json_string key; - SIMDJSON_TRY(parent_iter.field_key().get(key)); - SIMDJSON_TRY(parent_iter.field_value()); - return field::start(parent_iter, key); - } - - simdjson_inline simdjson_result field::start(const value_iterator& parent_iter, raw_json_string key) noexcept { - return field(key, parent_iter.child()); - } - - simdjson_inline simdjson_warn_unused simdjson_result field::unescaped_key(bool allow_replacement) noexcept { - SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() but Visual Studio won't let us. - simdjson_result answer = first.unescape(second.iter.json_iter(), allow_replacement); - first.consume(); - return answer; - } - - simdjson_inline raw_json_string field::key() const noexcept { - SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() by Visual Studio won't let us. - return first; - } - - simdjson_inline value& field::value() & noexcept { - return second; - } - - simdjson_inline value field::value() && noexcept { - return std::forward(*this).second; - } - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - simdjson_inline simdjson_result::simdjson_result( - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::field&& value - ) noexcept : - implementation_simdjson_result_base( - std::forward(value) - ) - { - } - simdjson_inline simdjson_result::simdjson_result( - error_code error - ) noexcept : - implementation_simdjson_result_base(error) - { - } - - simdjson_inline simdjson_result simdjson_result::key() noexcept { - if (error()) { return error(); } - return first.key(); - } - simdjson_inline simdjson_result simdjson_result::unescaped_key(bool allow_replacement) noexcept { - if (error()) { return error(); } - return first.unescaped_key(allow_replacement); - } - simdjson_inline simdjson_result simdjson_result::value() noexcept { - if (error()) { return error(); } - return std::move(first.value()); - } - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/field-inl.h */ -/* begin file include/simdjson/generic/ondemand/object-inl.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) & noexcept { - bool has_value; - SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); - if (!has_value) { return NO_SUCH_FIELD; } - return value(iter.child()); - } - simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) && noexcept { - bool has_value; - SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); - if (!has_value) { return NO_SUCH_FIELD; } - return value(iter.child()); - } - simdjson_inline simdjson_result object::operator[](const std::string_view key) & noexcept { - return find_field_unordered(key); - } - simdjson_inline simdjson_result object::operator[](const std::string_view key) && noexcept { - return std::forward(*this).find_field_unordered(key); - } - simdjson_inline simdjson_result object::find_field(const std::string_view key) & noexcept { - bool has_value; - SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); - if (!has_value) { return NO_SUCH_FIELD; } - return value(iter.child()); - } - simdjson_inline simdjson_result object::find_field(const std::string_view key) && noexcept { - bool has_value; - SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); - if (!has_value) { return NO_SUCH_FIELD; } - return value(iter.child()); - } - - simdjson_inline simdjson_result object::start(value_iterator& iter) noexcept { - SIMDJSON_TRY(iter.start_object().error()); - return object(iter); - } - simdjson_inline simdjson_result object::start_root(value_iterator& iter) noexcept { - SIMDJSON_TRY(iter.start_root_object().error()); - return object(iter); - } - simdjson_inline error_code object::consume() noexcept { - if (iter.is_at_key()) { - /** - * whenever you are pointing at a key, calling skip_child() is - * unsafe because you will hit a string and you will assume that - * it is string value, and this mistake will lead you to make bad - * depth computation. - */ - /** - * We want to 'consume' the key. We could really - * just do _json_iter->return_current_and_advance(); at this - * point, but, for clarity, we will use the high-level API to - * eat the key. We assume that the compiler optimizes away - * most of the work. - */ - simdjson_unused raw_json_string actual_key; - auto error = iter.field_key().get(actual_key); - if (error) { iter.abandon(); return error; }; - // Let us move to the value while we are at it. - if ((error = iter.field_value())) { iter.abandon(); return error; } - } - auto error_skip = iter.json_iter().skip_child(iter.depth() - 1); - if (error_skip) { iter.abandon(); } - return error_skip; - } - - simdjson_inline simdjson_result object::raw_json() noexcept { - const uint8_t* starting_point{ iter.peek_start() }; - auto error = consume(); - if (error) { return error; } - const uint8_t* final_point{ iter._json_iter->peek(0) }; - return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); - } - - simdjson_inline simdjson_result object::started(value_iterator& iter) noexcept { - SIMDJSON_TRY(iter.started_object().error()); - return object(iter); - } - - simdjson_inline object object::resume(const value_iterator& iter) noexcept { - return iter; - } - - simdjson_inline object::object(const value_iterator& _iter) noexcept - : iter{ _iter } - { - } - - simdjson_inline simdjson_result object::begin() noexcept { -#if SIMDJSON_DEVELOPMENT_CHECKS - if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } -#endif - return object_iterator(iter); - } - simdjson_inline simdjson_result object::end() noexcept { - return object_iterator(iter); - } - - inline simdjson_result object::at_pointer(std::string_view json_pointer) noexcept { - if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } - json_pointer = json_pointer.substr(1); - size_t slash = json_pointer.find('/'); - std::string_view key = json_pointer.substr(0, slash); - // Grab the child with the given key - simdjson_result child; - - // If there is an escape character in the key, unescape it and then get the child. - size_t escape = key.find('~'); - if (escape != std::string_view::npos) { - // Unescape the key - std::string unescaped(key); - do { - switch (unescaped[escape + 1]) { - case '0': - unescaped.replace(escape, 2, "~"); - break; - case '1': - unescaped.replace(escape, 2, "/"); - break; - default: - return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); - } - escape = unescaped.find('~', escape + 1); - } while (escape != std::string::npos); - child = find_field(unescaped); // Take note find_field does not unescape keys when matching - } - else { - child = find_field(key); - } - if (child.error()) { - return child; // we do not continue if there was an error - } - // If there is a /, we have to recurse and look up more of the path - if (slash != std::string_view::npos) { - child = child.at_pointer(json_pointer.substr(slash)); - } - return child; - } - - simdjson_inline simdjson_result object::count_fields() & noexcept { - size_t count{ 0 }; - // Important: we do not consume any of the values. - for (simdjson_unused auto v : *this) { count++; } - // The above loop will always succeed, but we want to report errors. - if (iter.error()) { return iter.error(); } - // We need to move back at the start because we expect users to iterate through - // the object after counting the number of elements. - iter.reset_object(); - return count; - } - - simdjson_inline simdjson_result object::is_empty() & noexcept { - bool is_not_empty; - auto error = iter.reset_object().get(is_not_empty); - if (error) { return error; } - return !is_not_empty; - } - - simdjson_inline simdjson_result object::reset() & noexcept { - return iter.reset_object(); - } - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object&& value) noexcept - : implementation_simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base(error) {} - - simdjson_inline simdjson_result simdjson_result::begin() noexcept { - if (error()) { return error(); } - return first.begin(); - } - simdjson_inline simdjson_result simdjson_result::end() noexcept { - if (error()) { return error(); } - return first.end(); - } - simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { - if (error()) { return error(); } - return first.find_field_unordered(key); - } - simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) && noexcept { - if (error()) { return error(); } - return std::forward(first).find_field_unordered(key); - } - simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { - if (error()) { return error(); } - return first[key]; - } - simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) && noexcept { - if (error()) { return error(); } - return std::forward(first)[key]; - } - simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { - if (error()) { return error(); } - return first.find_field(key); - } - simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) && noexcept { - if (error()) { return error(); } - return std::forward(first).find_field(key); - } - - simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { - if (error()) { return error(); } - return first.at_pointer(json_pointer); - } - - inline simdjson_result simdjson_result::reset() noexcept { - if (error()) { return error(); } - return first.reset(); - } - - inline simdjson_result simdjson_result::is_empty() noexcept { - if (error()) { return error(); } - return first.is_empty(); - } - - simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { - if (error()) { return error(); } - return first.count_fields(); - } - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/object-inl.h */ -/* begin file include/simdjson/generic/ondemand/parser-inl.h */ -namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { - namespace ondemand { - - simdjson_inline parser::parser(size_t max_capacity) noexcept - : _max_capacity{ max_capacity } { - } - - simdjson_warn_unused simdjson_inline error_code parser::allocate(size_t new_capacity, size_t new_max_depth) noexcept { - if (new_capacity > max_capacity()) { return CAPACITY; } - if (string_buf && new_capacity == capacity() && new_max_depth == max_depth()) { return SUCCESS; } - - // string_capacity copied from document::allocate - _capacity = 0; - size_t string_capacity = SIMDJSON_ROUNDUP_N(5 * new_capacity / 3 + SIMDJSON_PADDING, 64); - string_buf.reset(new (std::nothrow) uint8_t[string_capacity]); -#if SIMDJSON_DEVELOPMENT_CHECKS - start_positions.reset(new (std::nothrow) token_position[new_max_depth]); -#endif - if (implementation) { - SIMDJSON_TRY(implementation->set_capacity(new_capacity)); - SIMDJSON_TRY(implementation->set_max_depth(new_max_depth)); - } - else { - SIMDJSON_TRY(simdjson::get_active_implementation()->create_dom_parser_implementation(new_capacity, new_max_depth, implementation)); - } - _capacity = new_capacity; - _max_depth = new_max_depth; - return SUCCESS; - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(padded_string_view json) & noexcept { - if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } - - // Allocate if needed - if (capacity() < json.length() || !string_buf) { - SIMDJSON_TRY(allocate(json.length(), max_depth())); - } - - // Run stage 1. - SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); - return document::start({ reinterpret_cast(json.data()), this }); - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const char* json, size_t len, size_t allocated) & noexcept { - return iterate(padded_string_view(json, len, allocated)); - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const uint8_t* json, size_t len, size_t allocated) & noexcept { - return iterate(padded_string_view(json, len, allocated)); - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string_view json, size_t allocated) & noexcept { - return iterate(padded_string_view(json, allocated)); - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const std::string& json) & noexcept { - return iterate(padded_string_view(json)); - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { - // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception - SIMDJSON_TRY(result.error()); - padded_string_view json = result.value_unsafe(); - return iterate(json); - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { - // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception - SIMDJSON_TRY(result.error()); - const padded_string& json = result.value_unsafe(); - return iterate(json); - } - - simdjson_warn_unused simdjson_inline simdjson_result parser::iterate_raw(padded_string_view json) & noexcept { - if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } - - // Allocate if needed - if (capacity() < json.length()) { - SIMDJSON_TRY(allocate(json.length(), max_depth())); - } - - // Run stage 1. - SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); - return json_iterator(reinterpret_cast(json.data()), this); - } - - inline simdjson_result parser::iterate_many(const uint8_t* buf, size_t len, size_t batch_size) noexcept { - if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } - return document_stream(*this, buf, len, batch_size); - } - inline simdjson_result parser::iterate_many(const char* buf, size_t len, size_t batch_size) noexcept { - return iterate_many(reinterpret_cast(buf), len, batch_size); - } - inline simdjson_result parser::iterate_many(const std::string& s, size_t batch_size) noexcept { - return iterate_many(s.data(), s.length(), batch_size); - } - inline simdjson_result parser::iterate_many(const padded_string& s, size_t batch_size) noexcept { - return iterate_many(s.data(), s.length(), batch_size); - } - - simdjson_inline size_t parser::capacity() const noexcept { - return _capacity; - } - simdjson_inline size_t parser::max_capacity() const noexcept { - return _max_capacity; - } - simdjson_inline size_t parser::max_depth() const noexcept { - return _max_depth; - } - - simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { - if (max_capacity < dom::MINIMAL_DOCUMENT_CAPACITY) { - _max_capacity = max_capacity; - } - else { - _max_capacity = dom::MINIMAL_DOCUMENT_CAPACITY; - } - } - - simdjson_inline simdjson_warn_unused simdjson_result parser::unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement) const noexcept { - uint8_t* end = implementation->parse_string(in.buf, dst, allow_replacement); - if (!end) { return STRING_ERROR; } - std::string_view result(reinterpret_cast(dst), end - dst); - dst = end; - return result; - } - - simdjson_inline simdjson_warn_unused simdjson_result parser::unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept { - uint8_t* end = implementation->parse_wobbly_string(in.buf, dst); - if (!end) { return STRING_ERROR; } - std::string_view result(reinterpret_cast(dst), end - dst); - dst = end; - return result; - } - - } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION -} // namespace simdjson - -namespace simdjson { - - simdjson_inline simdjson_result::simdjson_result(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::parser&& value) noexcept - : implementation_simdjson_result_base(std::forward(value)) {} - simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept - : implementation_simdjson_result_base(error) {} - -} // namespace simdjson -/* end file include/simdjson/generic/ondemand/parser-inl.h */ -/* begin file include/simdjson/generic/ondemand/document_stream-inl.h */ #include -#include #include + namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace fallback { namespace ondemand { #ifdef SIMDJSON_THREADS_ENABLED @@ -31470,12 +42666,14 @@ namespace simdjson { ondemand::parser& _parser, const uint8_t* _buf, size_t _len, - size_t _batch_size + size_t _batch_size, + bool _allow_comma_separated ) noexcept : parser{ &_parser }, buf{ _buf }, len{ _len }, batch_size{ _batch_size <= MINIMAL_BATCH_SIZE ? MINIMAL_BATCH_SIZE : _batch_size }, + allow_comma_separated{ _allow_comma_separated }, error{ SUCCESS } #ifdef SIMDJSON_THREADS_ENABLED , use_thread(_parser.threaded) // we need to make a copy because _parser.threaded can change @@ -31493,6 +42691,7 @@ namespace simdjson { buf{ nullptr }, len{ 0 }, batch_size{ 0 }, + allow_comma_separated{ false }, error{ UNINITIALIZED } #ifdef SIMDJSON_THREADS_ENABLED , use_thread(false) @@ -31677,6 +42876,8 @@ namespace simdjson { if (error) { return; } // Always set depth=1 at the start of document doc.iter._depth = 1; + // consume comma if comma separated is allowed + if (allow_comma_separated) { doc.iter.consume_character(','); } // Resets the string buffer at the beginning, thus invalidating the strings. doc.iter._string_buf_loc = parser->string_buf.get(); doc.iter._root = doc.iter.position(); @@ -31772,30 +42973,1705 @@ namespace simdjson { #endif // SIMDJSON_THREADS_ENABLED } // namespace ondemand - } // namespace SIMDJSON_BUILTIN_IMPLEMENTATION + } // namespace fallback } // namespace simdjson namespace simdjson { - simdjson_inline simdjson_result::simdjson_result( + simdjson_inline simdjson_result::simdjson_result( error_code error ) noexcept : - implementation_simdjson_result_base(error) + implementation_simdjson_result_base(error) { } - simdjson_inline simdjson_result::simdjson_result( - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document_stream&& value + simdjson_inline simdjson_result::simdjson_result( + fallback::ondemand::document_stream&& value ) noexcept : - implementation_simdjson_result_base( - std::forward(value) + implementation_simdjson_result_base( + std::forward(value) ) { } } -/* end file include/simdjson/generic/ondemand/document_stream-inl.h */ -/* begin file include/simdjson/generic/ondemand/serialization-inl.h */ +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H +/* end file simdjson/generic/ondemand/document_stream-inl.h for fallback */ +/* including simdjson/generic/ondemand/field-inl.h for fallback: #include "simdjson/generic/ondemand/field-inl.h" */ +/* begin file simdjson/generic/ondemand/field-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + // clang 6 doesn't think the default constructor can be noexcept, so we make it explicit + simdjson_inline field::field() noexcept : std::pair() {} + + simdjson_inline field::field(raw_json_string key, ondemand::value&& value) noexcept + : std::pair(key, std::forward(value)) + { + } + + simdjson_inline simdjson_result field::start(value_iterator& parent_iter) noexcept { + raw_json_string key; + SIMDJSON_TRY(parent_iter.field_key().get(key)); + SIMDJSON_TRY(parent_iter.field_value()); + return field::start(parent_iter, key); + } + + simdjson_inline simdjson_result field::start(const value_iterator& parent_iter, raw_json_string key) noexcept { + return field(key, parent_iter.child()); + } + + simdjson_inline simdjson_warn_unused simdjson_result field::unescaped_key(bool allow_replacement) noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() but Visual Studio won't let us. + simdjson_result answer = first.unescape(second.iter.json_iter(), allow_replacement); + first.consume(); + return answer; + } + + simdjson_inline raw_json_string field::key() const noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() by Visual Studio won't let us. + return first; + } + + simdjson_inline value& field::value() & noexcept { + return second; + } + + simdjson_inline value field::value() && noexcept { + return std::forward(*this).second; + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + fallback::ondemand::field&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::key() noexcept { + if (error()) { return error(); } + return first.key(); + } + simdjson_inline simdjson_result simdjson_result::unescaped_key(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.unescaped_key(allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::value() noexcept { + if (error()) { return error(); } + return std::move(first.value()); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H +/* end file simdjson/generic/ondemand/field-inl.h for fallback */ +/* including simdjson/generic/ondemand/json_iterator-inl.h for fallback: #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/json_iterator-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + simdjson_inline json_iterator::json_iterator(json_iterator&& other) noexcept + : token(std::forward(other.token)), + parser{ other.parser }, + _string_buf_loc{ other._string_buf_loc }, + error{ other.error }, + _depth{ other._depth }, + _root{ other._root }, + _streaming{ other._streaming } + { + other.parser = nullptr; + } + simdjson_inline json_iterator& json_iterator::operator=(json_iterator&& other) noexcept { + token = other.token; + parser = other.parser; + _string_buf_loc = other._string_buf_loc; + error = other.error; + _depth = other._depth; + _root = other._root; + _streaming = other._streaming; + other.parser = nullptr; + return *this; + } + + simdjson_inline json_iterator::json_iterator(const uint8_t* buf, ondemand::parser* _parser) noexcept + : token(buf, &_parser->implementation->structural_indexes[0]), + parser{ _parser }, + _string_buf_loc{ parser->string_buf.get() }, + _depth{ 1 }, + _root{ parser->implementation->structural_indexes.get() }, + _streaming{ false } + + { + logger::log_headers(); +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif + } + + inline void json_iterator::rewind() noexcept { + token.set_position(root_position()); + logger::log_headers(); // We start again + _string_buf_loc = parser->string_buf.get(); + _depth = 1; + } + + inline bool json_iterator::balanced() const noexcept { + token_iterator ti(token); + int32_t count{ 0 }; + ti.set_position(root_position()); + while (ti.peek() <= peek_last()) { + switch (*ti.return_current_and_advance()) + { + case '[': case '{': + count++; + break; + case ']': case '}': + count--; + break; + default: + break; + } + } + return count == 0; + } + + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and parent_depth, which is a desired effect. The warning does not show up if the + // skip_child() function is not marked inline). + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline error_code json_iterator::skip_child(depth_t parent_depth) noexcept { + if (depth() <= parent_depth) { return SUCCESS; } + switch (*return_current_and_advance()) { + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + + // For the first open array/object in a value, we've already incremented depth, so keep it the same + // We never stop at colon, but if we did, it wouldn't affect depth + case '[': case '{': case ':': + logger::log_start_value(*this, "skip"); + break; + // If there is a comma, we have just finished a value in an array/object, and need to get back in + case ',': + logger::log_value(*this, "skip"); + break; + // ] or } means we just finished a value and need to jump out of the array/object + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } +#if SIMDJSON_CHECK_EOF + // If there are no more tokens, the parent is incomplete. + if (at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "Missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + break; + case '"': + if (*peek() == ':') { + // We are at a key!!! + // This might happen if you just started an object and you skip it immediately. + // Performance note: it would be nice to get rid of this check as it is somewhat + // expensive. + // https://github.com/simdjson/simdjson/issues/1742 + logger::log_value(*this, "key"); + return_current_and_advance(); // eat up the ':' + break; // important!!! + } + simdjson_fallthrough; + // Anything else must be a scalar value + default: + // For the first scalar, we will have incremented depth already, so we decrement it here. + logger::log_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + } + + // Now that we've considered the first value, we only increment/decrement for arrays/objects + while (position() < end_position()) { + switch (*return_current_and_advance()) { + case '[': case '{': + logger::log_start_value(*this, "skip"); + _depth++; + break; + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + default: + logger::log_value(*this, "skip", ""); + break; + } + } + + return report_error(TAPE_ERROR, "not enough close braces"); + } + + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool json_iterator::at_root() const noexcept { + return position() == root_position(); + } + + simdjson_inline bool json_iterator::is_single_token() const noexcept { + return parser->implementation->n_structural_indexes == 1; + } + + simdjson_inline bool json_iterator::streaming() const noexcept { + return _streaming; + } + + simdjson_inline token_position json_iterator::root_position() const noexcept { + return _root; + } + + simdjson_inline void json_iterator::assert_at_document_depth() const noexcept { + SIMDJSON_ASSUME(_depth == 1); + } + + simdjson_inline void json_iterator::assert_at_root() const noexcept { + SIMDJSON_ASSUME(_depth == 1); +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + // Under Visual Studio, the next SIMDJSON_ASSUME fails with: the argument + // has side effects that will be discarded. + SIMDJSON_ASSUME(token.position() == _root); +#endif + } + + simdjson_inline void json_iterator::assert_more_tokens(uint32_t required_tokens) const noexcept { + assert_valid_position(token._position + required_tokens - 1); + } + + simdjson_inline void json_iterator::assert_valid_position(token_position position) const noexcept { +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(position >= &parser->implementation->structural_indexes[0]); + SIMDJSON_ASSUME(position < &parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]); +#endif + } + + simdjson_inline bool json_iterator::at_end() const noexcept { + return position() == end_position(); + } + simdjson_inline token_position json_iterator::end_position() const noexcept { + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + return &parser->implementation->structural_indexes[n_structural_indexes]; + } + + inline std::string json_iterator::to_string() const noexcept { + if (!is_alive()) { return "dead json_iterator instance"; } + const char* current_structural = reinterpret_cast(token.peek()); + return std::string("json_iterator [ depth : ") + std::to_string(_depth) + + std::string(", structural : '") + std::string(current_structural, 1) + + std::string("', offset : ") + std::to_string(token.current_offset()) + + std::string("', error : ") + error_message(error) + + std::string(" ]"); + } + + inline simdjson_result json_iterator::current_location() const noexcept { + if (!is_alive()) { // Unrecoverable error + if (!at_root()) { + return reinterpret_cast(token.peek(-1)); + } + else { + return reinterpret_cast(token.peek()); + } + } + if (at_end()) { + return OUT_OF_BOUNDS; + } + return reinterpret_cast(token.peek()); + } + + simdjson_inline bool json_iterator::is_alive() const noexcept { + return parser; + } + + simdjson_inline void json_iterator::abandon() noexcept { + parser = nullptr; + _depth = 0; + } + + simdjson_inline const uint8_t* json_iterator::return_current_and_advance() noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif // SIMDJSON_CHECK_EOF + return token.return_current_and_advance(); + } + + simdjson_inline const uint8_t* json_iterator::unsafe_pointer() const noexcept { + // deliberately done without safety guard: + return token.peek(); + } + + simdjson_inline const uint8_t* json_iterator::peek(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // SIMDJSON_CHECK_EOF + return token.peek(delta); + } + + simdjson_inline uint32_t json_iterator::peek_length(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // #if SIMDJSON_CHECK_EOF + return token.peek_length(delta); + } + + simdjson_inline const uint8_t* json_iterator::peek(token_position position) const noexcept { + // todo: currently we require end-of-string buffering, but the following + // assert_valid_position should be turned on if/when we lift that condition. + // assert_valid_position(position); + // This is almost surely related to SIMDJSON_CHECK_EOF but given that SIMDJSON_CHECK_EOF + // is ON by default, we have no choice but to disable it for real with a comment. + return token.peek(position); + } + + simdjson_inline uint32_t json_iterator::peek_length(token_position position) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_valid_position(position); +#endif // SIMDJSON_CHECK_EOF + return token.peek_length(position); + } + + simdjson_inline token_position json_iterator::last_position() const noexcept { + // The following line fails under some compilers... + // SIMDJSON_ASSUME(parser->implementation->n_structural_indexes > 0); + // since it has side-effects. + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + SIMDJSON_ASSUME(n_structural_indexes > 0); + return &parser->implementation->structural_indexes[n_structural_indexes - 1]; + } + simdjson_inline const uint8_t* json_iterator::peek_last() const noexcept { + return token.peek(last_position()); + } + + simdjson_inline void json_iterator::ascend_to(depth_t parent_depth) noexcept { + SIMDJSON_ASSUME(parent_depth >= 0 && parent_depth < INT32_MAX - 1); + SIMDJSON_ASSUME(_depth == parent_depth + 1); + _depth = parent_depth; + } + + simdjson_inline void json_iterator::descend_to(depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); + _depth = child_depth; + } + + simdjson_inline depth_t json_iterator::depth() const noexcept { + return _depth; + } + + simdjson_inline uint8_t*& json_iterator::string_buf_loc() noexcept { + return _string_buf_loc; + } + + simdjson_inline error_code json_iterator::report_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error != SUCCESS && _error != UNINITIALIZED && _error != INCORRECT_TYPE && _error != NO_SUCH_FIELD); + logger::log_error(*this, message); + error = _error; + return error; + } + + simdjson_inline token_position json_iterator::position() const noexcept { + return token.position(); + } + + simdjson_inline simdjson_result json_iterator::unescape(raw_json_string in, bool allow_replacement) noexcept { + return parser->unescape(in, _string_buf_loc, allow_replacement); + } + + simdjson_inline simdjson_result json_iterator::unescape_wobbly(raw_json_string in) noexcept { + return parser->unescape_wobbly(in, _string_buf_loc); + } + + simdjson_inline void json_iterator::reenter_child(token_position position, depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); +#if SIMDJSON_DEVELOPMENT_CHECKS +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(size_t(child_depth) < parser->max_depth()); + SIMDJSON_ASSUME(position >= parser->start_positions[child_depth]); +#endif +#endif + token.set_position(position); + _depth = child_depth; + } + + simdjson_inline error_code json_iterator::consume_character(char c) noexcept { + if (*peek() == c) { + return_current_and_advance(); + return SUCCESS; + } + return TAPE_ERROR; + } + +#if SIMDJSON_DEVELOPMENT_CHECKS + + simdjson_inline token_position json_iterator::start_position(depth_t depth) const noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + return size_t(depth) < parser->max_depth() ? parser->start_positions[depth] : 0; + } + + simdjson_inline void json_iterator::set_start_position(depth_t depth, token_position position) noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + if (size_t(depth) < parser->max_depth()) { parser->start_positions[depth] = position; } + } + +#endif + + + simdjson_inline error_code json_iterator::optional_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error == INCORRECT_TYPE || _error == NO_SUCH_FIELD); + logger::log_error(*this, message); + return _error; + } + + + simdjson_warn_unused simdjson_inline bool json_iterator::copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept { + // This function is not expected to be called in performance-sensitive settings. + // Let us guard against silly cases: + if ((N < max_len) || (N == 0)) { return false; } + // Copy to the buffer. + std::memcpy(tmpbuf, json, max_len); + if (N > max_len) { // We pad whatever remains with ' '. + std::memset(tmpbuf + max_len, ' ', N - max_len); + } + return true; + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::json_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/json_iterator-inl.h for fallback */ +/* including simdjson/generic/ondemand/json_type-inl.h for fallback: #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* begin file simdjson/generic/ondemand/json_type-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept { + switch (type) { + case json_type::array: out << "array"; break; + case json_type::object: out << "object"; break; + case json_type::number: out << "number"; break; + case json_type::string: out << "string"; break; + case json_type::boolean: out << "boolean"; break; + case json_type::null: out << "null"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false) { + return out << type.value(); + } +#endif + + + + simdjson_inline number_type number::get_number_type() const noexcept { + return type; + } + + simdjson_inline bool number::is_uint64() const noexcept { + return get_number_type() == number_type::unsigned_integer; + } + + simdjson_inline uint64_t number::get_uint64() const noexcept { + return payload.unsigned_integer; + } + + simdjson_inline number::operator uint64_t() const noexcept { + return get_uint64(); + } + + + simdjson_inline bool number::is_int64() const noexcept { + return get_number_type() == number_type::signed_integer; + } + + simdjson_inline int64_t number::get_int64() const noexcept { + return payload.signed_integer; + } + + simdjson_inline number::operator int64_t() const noexcept { + return get_int64(); + } + + simdjson_inline bool number::is_double() const noexcept { + return get_number_type() == number_type::floating_point_number; + } + + simdjson_inline double number::get_double() const noexcept { + return payload.floating_point_number; + } + + simdjson_inline number::operator double() const noexcept { + return get_double(); + } + + simdjson_inline double number::as_double() const noexcept { + if (is_double()) { + return payload.floating_point_number; + } + if (is_int64()) { + return double(payload.signed_integer); + } + return double(payload.unsigned_integer); + } + + simdjson_inline void number::append_s64(int64_t value) noexcept { + payload.signed_integer = value; + type = number_type::signed_integer; + } + + simdjson_inline void number::append_u64(uint64_t value) noexcept { + payload.unsigned_integer = value; + type = number_type::unsigned_integer; + } + + simdjson_inline void number::append_double(double value) noexcept { + payload.floating_point_number = value; + type = number_type::floating_point_number; + } + + simdjson_inline void number::skip_double() noexcept { + type = number_type::floating_point_number; + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::json_type&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H +/* end file simdjson/generic/ondemand/json_type-inl.h for fallback */ +/* including simdjson/generic/ondemand/logger-inl.h for fallback: #include "simdjson/generic/ondemand/logger-inl.h" */ +/* begin file simdjson/generic/ondemand/logger-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace fallback { + namespace ondemand { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static int log_depth = 0; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + template + static inline std::string string_format(const std::string& format, const Args&... args) + { + SIMDJSON_PUSH_DISABLE_ALL_WARNINGS + int size_s = std::snprintf(nullptr, 0, format.c_str(), args...) + 1; + auto size = static_cast(size_s); + if (size <= 0) return std::string(); + std::unique_ptr buf(new char[size]); + std::snprintf(buf.get(), size, format.c_str(), args...); + SIMDJSON_POP_DISABLE_WARNINGS + return std::string(buf.get(), buf.get() + size - 1); + } + + static inline log_level get_log_level_from_env() + { + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe + char* lvl = getenv("SIMDJSON_LOG_LEVEL"); + SIMDJSON_POP_DISABLE_WARNINGS + if (lvl && simdjson_strcasecmp(lvl, "ERROR") == 0) { return log_level::error; } + return log_level::info; + } + + static inline log_level log_threshold() + { + static log_level threshold = get_log_level_from_env(); + return threshold; + } + + static inline bool should_log(log_level level) + { + return level >= log_threshold(); + } + + inline void log_event(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "", type, detail, log_level::info); + } + inline void log_value(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "+", type, detail, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + inline void log_start_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_line(iter, "+", type, "", delta, depth_delta, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + + inline void log_end_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + if (LOG_ENABLED) { log_depth--; } + log_line(iter, "-", type, "", delta, depth_delta, log_level::info); + } + + inline void log_error(const json_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_line(iter, "ERROR: ", error, detail, delta, depth_delta, log_level::error); + } + inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail) noexcept { + log_line(iter, index, depth, "ERROR: ", error, detail, log_level::error); + } + + inline void log_event(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_event(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_value(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_value(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_start_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_start_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_end_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_end_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_error(const value_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_error(iter.json_iter(), error, detail, delta, depth_delta); + } + + inline void log_headers() noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(log_level::info))) { + // Technically a static variable is not thread-safe, but if you are using threads and logging... well... + static bool displayed_hint{ false }; + log_depth = 0; + printf("\n"); + if (!displayed_hint) { + // We only print this helpful header once. + printf("# Logging provides the depth and position of the iterator user-visible steps:\n"); + printf("# +array says 'this is where we were when we discovered the start array'\n"); + printf( + "# -array says 'this is where we were when we ended the array'\n"); + printf("# skip says 'this is a structural or value I am skipping'\n"); + printf("# +/-skip says 'this is a start/end array or object I am skipping'\n"); + printf("#\n"); + printf("# The indentation of the terms (array, string,...) indicates the depth,\n"); + printf("# in addition to the depth being displayed.\n"); + printf("#\n"); + printf("# Every token in the document has a single depth determined by the tokens before it,\n"); + printf("# and is not affected by what the token actually is.\n"); + printf("#\n"); + printf("# Not all structural elements are presented as tokens in the logs.\n"); + printf("#\n"); + printf("# We never give control to the user within an empty array or an empty object.\n"); + printf("#\n"); + printf("# Inside an array, having a depth greater than the array's depth means that\n"); + printf("# we are pointing inside a value.\n"); + printf("# Having a depth equal to the array means that we are pointing right before a value.\n"); + printf("# Having a depth smaller than the array means that we have moved beyond the array.\n"); + displayed_hint = true; + } + printf("\n"); + printf("| %-*s ", LOG_EVENT_LEN, "Event"); + printf("| %-*s ", LOG_BUFFER_LEN, "Buffer"); + printf("| %-*s ", LOG_SMALL_BUFFER_LEN, "Next"); + // printf("| %-*s ", 5, "Next#"); + printf("| %-*s ", 5, "Depth"); + printf("| Detail "); + printf("|\n"); + + printf("|%.*s", LOG_EVENT_LEN + 2, DASHES); + printf("|%.*s", LOG_BUFFER_LEN + 2, DASHES); + printf("|%.*s", LOG_SMALL_BUFFER_LEN + 2, DASHES); + // printf("|%.*s", 5+2, DASHES); + printf("|%.*s", 5 + 2, DASHES); + printf("|--------"); + printf("|\n"); + fflush(stdout); + } + } + } + + template + inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, log_level level, Args&&... args) noexcept { + log_line(iter, iter.position() + delta, depth_t(iter.depth() + depth_delta), title_prefix, title, detail, level, std::forward(args)...); + } + + template + inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, log_level level, Args&&... args) noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(level))) { + const int indent = depth * 2; + const auto buf = iter.token.buf; + auto msg = string_format(title, std::forward(args)...); + printf("| %*s%s%-*s ", indent, "", title_prefix, + LOG_EVENT_LEN - indent - int(strlen(title_prefix)), msg.c_str()); + { + // Print the current structural. + printf("| "); + // Before we begin, the index might point right before the document. + // This could be unsafe, see https://github.com/simdjson/simdjson/discussions/1938 + if (index < iter._root) { + printf("%*s", LOG_BUFFER_LEN, ""); + } + else { + auto current_structural = &buf[*index]; + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current_structural[i])); + } + } + printf(" "); + } + { + // Print the next structural. + printf("| "); + auto next_structural = &buf[*(index + 1)]; + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next_structural[i])); + } + printf(" "); + } + // printf("| %5u ", *(index+1)); + printf("| %5i ", depth); + printf("| %6.*s ", int(detail.size()), detail.data()); + printf("|\n"); + fflush(stdout); + } + } + } + + } // namespace logger + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H +/* end file simdjson/generic/ondemand/logger-inl.h for fallback */ +/* including simdjson/generic/ondemand/object-inl.h for fallback: #include "simdjson/generic/ondemand/object-inl.h" */ +/* begin file simdjson/generic/ondemand/object-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) & noexcept { + return find_field_unordered(key); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) && noexcept { + return std::forward(*this).find_field_unordered(key); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + + simdjson_inline simdjson_result object::start(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_object().error()); + return object(iter); + } + simdjson_inline simdjson_result object::start_root(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_root_object().error()); + return object(iter); + } + simdjson_inline error_code object::consume() noexcept { + if (iter.is_at_key()) { + /** + * whenever you are pointing at a key, calling skip_child() is + * unsafe because you will hit a string and you will assume that + * it is string value, and this mistake will lead you to make bad + * depth computation. + */ + /** + * We want to 'consume' the key. We could really + * just do _json_iter->return_current_and_advance(); at this + * point, but, for clarity, we will use the high-level API to + * eat the key. We assume that the compiler optimizes away + * most of the work. + */ + simdjson_unused raw_json_string actual_key; + auto error = iter.field_key().get(actual_key); + if (error) { iter.abandon(); return error; }; + // Let us move to the value while we are at it. + if ((error = iter.field_value())) { iter.abandon(); return error; } + } + auto error_skip = iter.json_iter().skip_child(iter.depth() - 1); + if (error_skip) { iter.abandon(); } + return error_skip; + } + + simdjson_inline simdjson_result object::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + const uint8_t* final_point{ iter._json_iter->peek() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result object::started(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.started_object().error()); + return object(iter); + } + + simdjson_inline object object::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline object::object(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result object::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return object_iterator(iter); + } + simdjson_inline simdjson_result object::end() noexcept { + return object_iterator(iter); + } + + inline simdjson_result object::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + size_t slash = json_pointer.find('/'); + std::string_view key = json_pointer.substr(0, slash); + // Grab the child with the given key + simdjson_result child; + + // If there is an escape character in the key, unescape it and then get the child. + size_t escape = key.find('~'); + if (escape != std::string_view::npos) { + // Unescape the key + std::string unescaped(key); + do { + switch (unescaped[escape + 1]) { + case '0': + unescaped.replace(escape, 2, "~"); + break; + case '1': + unescaped.replace(escape, 2, "/"); + break; + default: + return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); + } + escape = unescaped.find('~', escape + 1); + } while (escape != std::string::npos); + child = find_field(unescaped); // Take note find_field does not unescape keys when matching + } + else { + child = find_field(key); + } + if (child.error()) { + return child; // we do not continue if there was an error + } + // If there is a /, we have to recurse and look up more of the path + if (slash != std::string_view::npos) { + child = child.at_pointer(json_pointer.substr(slash)); + } + return child; + } + + simdjson_inline simdjson_result object::count_fields() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the object after counting the number of elements. + iter.reset_object(); + return count; + } + + simdjson_inline simdjson_result object::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_object().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + simdjson_inline simdjson_result object::reset() & noexcept { + return iter.reset_object(); + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::object&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first)[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + inline simdjson_result simdjson_result::reset() noexcept { + if (error()) { return error(); } + return first.reset(); + } + + inline simdjson_result simdjson_result::is_empty() noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H +/* end file simdjson/generic/ondemand/object-inl.h for fallback */ +/* including simdjson/generic/ondemand/object_iterator-inl.h for fallback: #include "simdjson/generic/ondemand/object_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/object_iterator-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + // + // object_iterator + // + + simdjson_inline object_iterator::object_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result object_iterator::operator*() noexcept { + error_code error = iter.error(); + if (error) { iter.abandon(); return error; } + auto result = field::start(iter); + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (result.error()) { iter.abandon(); } + return result; + } + simdjson_inline bool object_iterator::operator==(const object_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool object_iterator::operator!=(const object_iterator&) const noexcept { + return iter.is_open(); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline object_iterator& object_iterator::operator++() noexcept { + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (!iter.is_open()) { return *this; } // Iterator will be released if there is an error + + simdjson_unused error_code error; + if ((error = iter.skip_child())) { return *this; } + + simdjson_unused bool has_value; + if ((error = iter.has_next_field().get(has_value))) { return *this; }; + return *this; + } + SIMDJSON_POP_DISABLE_WARNINGS + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter.depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the object is first found and the iterator is just past the {. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the , or } before the next value. In this state, + // depth == iter.depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter.depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter.depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the object iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet field may be missing or not be an + // object--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter.depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between fields, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter.depth == depth, and at_start == false. + // + // Errors that occur while reading a field to give to the user (such as when the key is not a + // string or the field is missing a colon) are yielded immediately. Depth is then decremented, + // moving to the Finished state without transitioning through an Error state at all. + // + // ## Terminal State + // + // The terminal state has iter.depth < depth. at_start is always false. + // + // - Finished: When we have reached a }, we are finished. We signal this by decrementing depth. + // In this state, iter.depth < depth, at_start == false, and error == SUCCESS. + // + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + fallback::ondemand::object_iterator&& value + ) noexcept + : implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + // Checks for ']' and ',' + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++first; + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/object_iterator-inl.h for fallback */ +/* including simdjson/generic/ondemand/parser-inl.h for fallback: #include "simdjson/generic/ondemand/parser-inl.h" */ +/* begin file simdjson/generic/ondemand/parser-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string_view.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/dom/base.h" // for MINIMAL_DOCUMENT_CAPACITY */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + simdjson_inline parser::parser(size_t max_capacity) noexcept + : _max_capacity{ max_capacity } { + } + + simdjson_warn_unused simdjson_inline error_code parser::allocate(size_t new_capacity, size_t new_max_depth) noexcept { + if (new_capacity > max_capacity()) { return CAPACITY; } + if (string_buf && new_capacity == capacity() && new_max_depth == max_depth()) { return SUCCESS; } + + // string_capacity copied from document::allocate + _capacity = 0; + size_t string_capacity = SIMDJSON_ROUNDUP_N(5 * new_capacity / 3 + SIMDJSON_PADDING, 64); + string_buf.reset(new (std::nothrow) uint8_t[string_capacity]); +#if SIMDJSON_DEVELOPMENT_CHECKS + start_positions.reset(new (std::nothrow) token_position[new_max_depth]); +#endif + if (implementation) { + SIMDJSON_TRY(implementation->set_capacity(new_capacity)); + SIMDJSON_TRY(implementation->set_max_depth(new_max_depth)); + } + else { + SIMDJSON_TRY(simdjson::get_active_implementation()->create_dom_parser_implementation(new_capacity, new_max_depth, implementation)); + } + _capacity = new_capacity; + _max_depth = new_max_depth; + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length() || !string_buf) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return document::start({ reinterpret_cast(json.data()), this }); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const char* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const uint8_t* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string_view json, size_t allocated) & noexcept { + return iterate(padded_string_view(json, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string& json) & noexcept { + if (json.capacity() - json.size() < SIMDJSON_PADDING) { + json.reserve(json.size() + SIMDJSON_PADDING); + } + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const std::string& json) & noexcept { + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + padded_string_view json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + const padded_string& json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate_raw(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length()) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return json_iterator(reinterpret_cast(json.data()), this); + } + + inline simdjson_result parser::iterate_many(const uint8_t* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + if (allow_comma_separated && batch_size < len) { batch_size = len; } + return document_stream(*this, buf, len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const char* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(reinterpret_cast(buf), len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const std::string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const padded_string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + + simdjson_inline size_t parser::capacity() const noexcept { + return _capacity; + } + simdjson_inline size_t parser::max_capacity() const noexcept { + return _max_capacity; + } + simdjson_inline size_t parser::max_depth() const noexcept { + return _max_depth; + } + + simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { + if (max_capacity < dom::MINIMAL_DOCUMENT_CAPACITY) { + _max_capacity = max_capacity; + } + else { + _max_capacity = dom::MINIMAL_DOCUMENT_CAPACITY; + } + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement) const noexcept { + uint8_t* end = implementation->parse_string(in.buf, dst, allow_replacement); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept { + uint8_t* end = implementation->parse_wobbly_string(in.buf, dst); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::parser&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H +/* end file simdjson/generic/ondemand/parser-inl.h for fallback */ +/* including simdjson/generic/ondemand/raw_json_string-inl.h for fallback: #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + namespace fallback { + namespace ondemand { + + simdjson_inline raw_json_string::raw_json_string(const uint8_t* _buf) noexcept : buf{ _buf } {} + + simdjson_inline const char* raw_json_string::raw() const noexcept { return reinterpret_cast(buf); } + + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(std::string_view target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; pos < target.size() && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(const char* target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; target[pos] && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; target[pos]; pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(size_t length, std::string_view target) const noexcept { + // If we are going to call memcmp, then we must know something about the length of the raw_json_string. + return (length >= target.size()) && (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + + simdjson_inline bool raw_json_string::unsafe_is_equal(std::string_view target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + if (target.size() <= SIMDJSON_PADDING) { + return (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + const char* r{ raw() }; + size_t pos{ 0 }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(std::string_view target) const noexcept { + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(const char* target) const noexcept { + // Assumptions: 'target' does not contain unescaped quote characters, is null terminated and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(const char* target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept { + return a.unsafe_is_equal(c); + } + + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept { + return a == c; + } + + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept { + return !(a == c); + } + + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept { + return !(a == c); + } + + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape(json_iterator& iter, bool allow_replacement) const noexcept { + return iter.unescape(*this, allow_replacement); + } + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape_wobbly(json_iterator& iter) const noexcept { + return iter.unescape_wobbly(*this); + } + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream& out, const raw_json_string& str) noexcept { + bool in_escape = false; + const char* s = str.raw(); + while (true) { + switch (*s) { + case '\\': in_escape = !in_escape; break; + case '"': if (in_escape) { in_escape = false; } + else { return out; } break; + default: if (in_escape) { in_escape = false; } + } + out << *s; + s++; + } + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::raw_json_string&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::raw() const noexcept { + if (error()) { return error(); } + return first.raw(); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape(fallback::ondemand::json_iterator& iter, bool allow_replacement) const noexcept { + if (error()) { return error(); } + return first.unescape(iter, allow_replacement); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape_wobbly(fallback::ondemand::json_iterator& iter) const noexcept { + if (error()) { return error(); } + return first.unescape_wobbly(iter); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H +/* end file simdjson/generic/ondemand/raw_json_string-inl.h for fallback */ +/* including simdjson/generic/ondemand/serialization-inl.h for fallback: #include "simdjson/generic/ondemand/serialization-inl.h" */ +/* begin file simdjson/generic/ondemand/serialization-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/serialization.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ namespace simdjson { @@ -31810,43 +44686,43 @@ namespace simdjson { } - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document& x) noexcept { + inline simdjson_result to_json_string(fallback::ondemand::document& x) noexcept { std::string_view v; auto error = x.raw_json().get(v); if (error) { return error; } return trim(v); } - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document_reference& x) noexcept { + inline simdjson_result to_json_string(fallback::ondemand::document_reference& x) noexcept { std::string_view v; auto error = x.raw_json().get(v); if (error) { return error; } return trim(v); } - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value& x) noexcept { + inline simdjson_result to_json_string(fallback::ondemand::value& x) noexcept { /** * If we somehow receive a value that has already been consumed, * then the following code could be in trouble. E.g., we create * an array as needed, but if an array was already created, then * it could be bad. */ - using namespace SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand; - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::json_type t; + using namespace fallback::ondemand; + fallback::ondemand::json_type t; auto error = x.type().get(t); if (error != SUCCESS) { return error; } switch (t) { case json_type::array: { - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array array; + fallback::ondemand::array array; error = x.get_array().get(array); if (error) { return error; } return to_json_string(array); } case json_type::object: { - SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object object; + fallback::ondemand::object object; error = x.get_object().get(object); if (error) { return error; } return to_json_string(object); @@ -31856,52 +44732,52 @@ namespace simdjson { } } - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object& x) noexcept { + inline simdjson_result to_json_string(fallback::ondemand::object& x) noexcept { std::string_view v; auto error = x.raw_json().get(v); if (error) { return error; } return trim(v); } - inline simdjson_result to_json_string(SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array& x) noexcept { + inline simdjson_result to_json_string(fallback::ondemand::array& x) noexcept { std::string_view v; auto error = x.raw_json().get(v); if (error) { return error; } return trim(v); } - inline simdjson_result to_json_string(simdjson_result x) { + inline simdjson_result to_json_string(simdjson_result x) { if (x.error()) { return x.error(); } return to_json_string(x.value_unsafe()); } - inline simdjson_result to_json_string(simdjson_result x) { + inline simdjson_result to_json_string(simdjson_result x) { if (x.error()) { return x.error(); } return to_json_string(x.value_unsafe()); } - inline simdjson_result to_json_string(simdjson_result x) { + inline simdjson_result to_json_string(simdjson_result x) { if (x.error()) { return x.error(); } return to_json_string(x.value_unsafe()); } - inline simdjson_result to_json_string(simdjson_result x) { + inline simdjson_result to_json_string(simdjson_result x) { if (x.error()) { return x.error(); } return to_json_string(x.value_unsafe()); } - inline simdjson_result to_json_string(simdjson_result x) { + inline simdjson_result to_json_string(simdjson_result x) { if (x.error()) { return x.error(); } return to_json_string(x.value_unsafe()); } } // namespace simdjson namespace simdjson { - namespace SIMDJSON_BUILTIN_IMPLEMENTATION { + namespace fallback { namespace ondemand { #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value x) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::value x) { std::string_view v; auto error = simdjson::to_json_string(x).get(v); if (error == simdjson::SUCCESS) { @@ -31911,12 +44787,12 @@ namespace simdjson { throw simdjson::simdjson_error(error); } } - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { if (x.error()) { throw simdjson::simdjson_error(x.error()); } return (out << x.value()); } #else - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::value x) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::value x) { std::string_view v; auto error = simdjson::to_json_string(x).get(v); if (error == simdjson::SUCCESS) { @@ -31929,7 +44805,7 @@ namespace simdjson { #endif #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array value) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::array value) { std::string_view v; auto error = simdjson::to_json_string(value).get(v); if (error == simdjson::SUCCESS) { @@ -31939,12 +44815,12 @@ namespace simdjson { throw simdjson::simdjson_error(error); } } - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { if (x.error()) { throw simdjson::simdjson_error(x.error()); } return (out << x.value()); } #else - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::array value) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::array value) { std::string_view v; auto error = simdjson::to_json_string(value).get(v); if (error == simdjson::SUCCESS) { @@ -31957,7 +44833,7 @@ namespace simdjson { #endif #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document& value) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::document& value) { std::string_view v; auto error = simdjson::to_json_string(value).get(v); if (error == simdjson::SUCCESS) { @@ -31967,7 +44843,7 @@ namespace simdjson { throw simdjson::simdjson_error(error); } } - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document_reference& value) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::document_reference& value) { std::string_view v; auto error = simdjson::to_json_string(value).get(v); if (error == simdjson::SUCCESS) { @@ -31977,16 +44853,16 @@ namespace simdjson { throw simdjson::simdjson_error(error); } } - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { if (x.error()) { throw simdjson::simdjson_error(x.error()); } return (out << x.value()); } - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { if (x.error()) { throw simdjson::simdjson_error(x.error()); } return (out << x.value()); } #else - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::document& value) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::document& value) { std::string_view v; auto error = simdjson::to_json_string(value).get(v); if (error == simdjson::SUCCESS) { @@ -31999,7 +44875,7 @@ namespace simdjson { #endif #if SIMDJSON_EXCEPTIONS - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object value) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::object value) { std::string_view v; auto error = simdjson::to_json_string(value).get(v); if (error == simdjson::SUCCESS) { @@ -32009,12 +44885,12 @@ namespace simdjson { throw simdjson::simdjson_error(error); } } - inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { if (x.error()) { throw simdjson::simdjson_error(x.error()); } return (out << x.value()); } #else - inline std::ostream& operator<<(std::ostream& out, simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand::object value) { + inline std::ostream& operator<<(std::ostream& out, simdjson::fallback::ondemand::object value) { std::string_view v; auto error = simdjson::to_json_string(value).get(v); if (error == simdjson::SUCCESS) { @@ -32027,38 +44903,44079 @@ namespace simdjson { #endif } } -} // namespace simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand -/* end file include/simdjson/generic/ondemand/serialization-inl.h */ -/* end file include/simdjson/generic/ondemand-inl.h */ +} // namespace simdjson::fallback::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H +/* end file simdjson/generic/ondemand/serialization-inl.h for fallback */ +/* including simdjson/generic/ondemand/token_iterator-inl.h for fallback: #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/token_iterator-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + simdjson_inline token_iterator::token_iterator( + const uint8_t* _buf, + token_position position + ) noexcept : buf{ _buf }, _position{ position } + { + } + + simdjson_inline uint32_t token_iterator::current_offset() const noexcept { + return *(_position); + } + + + simdjson_inline const uint8_t* token_iterator::return_current_and_advance() noexcept { + return &buf[*(_position++)]; + } + + simdjson_inline const uint8_t* token_iterator::peek(token_position position) const noexcept { + return &buf[*position]; + } + simdjson_inline uint32_t token_iterator::peek_index(token_position position) const noexcept { + return *position; + } + simdjson_inline uint32_t token_iterator::peek_length(token_position position) const noexcept { + return *(position + 1) - *position; + } + + simdjson_inline const uint8_t* token_iterator::peek(int32_t delta) const noexcept { + return &buf[*(_position + delta)]; + } + simdjson_inline uint32_t token_iterator::peek_index(int32_t delta) const noexcept { + return *(_position + delta); + } + simdjson_inline uint32_t token_iterator::peek_length(int32_t delta) const noexcept { + return *(_position + delta + 1) - *(_position + delta); + } + + simdjson_inline token_position token_iterator::position() const noexcept { + return _position; + } + simdjson_inline void token_iterator::set_position(token_position target_position) noexcept { + _position = target_position; + } + + simdjson_inline bool token_iterator::operator==(const token_iterator& other) const noexcept { + return _position == other._position; + } + simdjson_inline bool token_iterator::operator!=(const token_iterator& other) const noexcept { + return _position != other._position; + } + simdjson_inline bool token_iterator::operator>(const token_iterator& other) const noexcept { + return _position > other._position; + } + simdjson_inline bool token_iterator::operator>=(const token_iterator& other) const noexcept { + return _position >= other._position; + } + simdjson_inline bool token_iterator::operator<(const token_iterator& other) const noexcept { + return _position < other._position; + } + simdjson_inline bool token_iterator::operator<=(const token_iterator& other) const noexcept { + return _position <= other._position; + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::token_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/token_iterator-inl.h for fallback */ +/* including simdjson/generic/ondemand/value-inl.h for fallback: #include "simdjson/generic/ondemand/value-inl.h" */ +/* begin file simdjson/generic/ondemand/value-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + simdjson_inline value::value(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + simdjson_inline value value::start(const value_iterator& iter) noexcept { + return iter; + } + simdjson_inline value value::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline simdjson_result value::get_array() noexcept { + return array::start(iter); + } + simdjson_inline simdjson_result value::get_object() noexcept { + return object::start(iter); + } + simdjson_inline simdjson_result value::start_or_resume_object() noexcept { + if (iter.at_start()) { + return get_object(); + } + else { + return object::resume(iter); + } + } + + simdjson_inline simdjson_result value::get_raw_json_string() noexcept { + return iter.get_raw_json_string(); + } + simdjson_inline simdjson_result value::get_string(bool allow_replacement) noexcept { + return iter.get_string(allow_replacement); + } + template + simdjson_inline error_code value::get_string(string_type& receiver, bool allow_replacement) noexcept { + return iter.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result value::get_wobbly_string() noexcept { + return iter.get_wobbly_string(); + } + simdjson_inline simdjson_result value::get_double() noexcept { + return iter.get_double(); + } + simdjson_inline simdjson_result value::get_double_in_string() noexcept { + return iter.get_double_in_string(); + } + simdjson_inline simdjson_result value::get_uint64() noexcept { + return iter.get_uint64(); + } + simdjson_inline simdjson_result value::get_uint64_in_string() noexcept { + return iter.get_uint64_in_string(); + } + simdjson_inline simdjson_result value::get_int64() noexcept { + return iter.get_int64(); + } + simdjson_inline simdjson_result value::get_int64_in_string() noexcept { + return iter.get_int64_in_string(); + } + simdjson_inline simdjson_result value::get_bool() noexcept { + return iter.get_bool(); + } + simdjson_inline simdjson_result value::is_null() noexcept { + return iter.is_null(); + } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_array(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_object(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_number(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_double(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_bool(); } + + template simdjson_inline error_code value::get(T& out) noexcept { + return get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline value::operator array() noexcept(false) { + return get_array(); + } + simdjson_inline value::operator object() noexcept(false) { + return get_object(); + } + simdjson_inline value::operator uint64_t() noexcept(false) { + return get_uint64(); + } + simdjson_inline value::operator int64_t() noexcept(false) { + return get_int64(); + } + simdjson_inline value::operator double() noexcept(false) { + return get_double(); + } + simdjson_inline value::operator std::string_view() noexcept(false) { + return get_string(false); + } + simdjson_inline value::operator raw_json_string() noexcept(false) { + return get_raw_json_string(); + } + simdjson_inline value::operator bool() noexcept(false) { + return get_bool(); + } +#endif + + simdjson_inline simdjson_result value::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result value::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result value::count_elements() & noexcept { + simdjson_result answer; + auto a = get_array(); + answer = a.count_elements(); + // count_elements leaves you pointing inside the array, at the first element. + // We need to move back so that the user can create a new array (which requires that + // we point at '['). + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::count_fields() & noexcept { + simdjson_result answer; + auto a = get_object(); + answer = a.count_fields(); + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::at(size_t index) noexcept { + auto a = get_array(); + return a.at(index); + } + + simdjson_inline simdjson_result value::find_field(std::string_view key) noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result value::find_field(const char* key) noexcept { + return start_or_resume_object().find_field(key); + } + + simdjson_inline simdjson_result value::find_field_unordered(std::string_view key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result value::find_field_unordered(const char* key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + + simdjson_inline simdjson_result value::operator[](std::string_view key) noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result value::operator[](const char* key) noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline simdjson_result value::type() noexcept { + return iter.type(); + } + + simdjson_inline simdjson_result value::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool value::is_negative() noexcept { + return iter.is_negative(); + } + + simdjson_inline simdjson_result value::is_integer() noexcept { + return iter.is_integer(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number_type() noexcept { + return iter.get_number_type(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number() noexcept { + return iter.get_number(); + } + + simdjson_inline std::string_view value::raw_json_token() noexcept { + return std::string_view(reinterpret_cast(iter.peek_start()), iter.peek_start_length()); + } + + simdjson_inline simdjson_result value::raw_json() noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: { + ondemand::array array; + SIMDJSON_TRY(get_array().get(array)); + return array.raw_json(); + } + case json_type::object: { + ondemand::object object; + SIMDJSON_TRY(get_object().get(object)); + return object.raw_json(); + } + default: + return raw_json_token(); + } + } + + simdjson_inline simdjson_result value::current_location() noexcept { + return iter.json_iter().current_location(); + } + + simdjson_inline int32_t value::current_depth() const noexcept { + return iter.json_iter().depth(); + } + + simdjson_inline simdjson_result value::at_pointer(std::string_view json_pointer) noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + fallback::ondemand::value&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + if (error()) { return error(); } + return {}; + } + + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) noexcept { + if (error()) { return error(); } + return first[key]; + } + + simdjson_inline simdjson_result simdjson_result::get_array() noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return first.get(); + } + template simdjson_inline error_code simdjson_result::get(T& out) noexcept { + if (error()) { return error(); } + return first.get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return std::move(first); + } + template<> simdjson_inline error_code simdjson_result::get(fallback::ondemand::value& out) noexcept { + if (error()) { return error(); } + out = first; + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator fallback::ondemand::array() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator fallback::ondemand::object() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator fallback::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H +/* end file simdjson/generic/ondemand/value-inl.h for fallback */ +/* including simdjson/generic/ondemand/value_iterator-inl.h for fallback: #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/value_iterator-inl.h for fallback */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/atomparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace fallback { + namespace ondemand { + + simdjson_inline value_iterator::value_iterator( + json_iterator* json_iter, + depth_t depth, + token_position start_position + ) noexcept : _json_iter{ json_iter }, _depth{ depth }, _start_position{ start_position } + { + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_root_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_object() noexcept { + assert_at_container_start(); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + if (*_json_iter->peek() == '}') { + logger::log_value(*_json_iter, "empty object"); + _json_iter->return_current_and_advance(); + end_container(); + return false; + } + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_object() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // object: e.g., `{"a":2} foo }`. Users concerned with garbage content should + // call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != '}') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing } at end"); + } + // If the last character is } *and* the first gibberish character is also '}' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == '}') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed object. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_object() noexcept { + auto error = check_root_object(); + if (error) { return error; } + return started_object(); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::end_container() noexcept { +#if SIMDJSON_CHECK_EOF + if (depth() > 1 && at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing parent ] or }"); } + // if (depth() <= 1 && !at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + _json_iter->ascend_to(depth() - 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_field() noexcept { + assert_at_next(); + + // It's illegal to call this unless there are more tokens: anything that ends in } or ] is + // obligated to verify there are more tokens if they are not the top level. + switch (*_json_iter->return_current_and_advance()) { + case '}': + logger::log_end_value(*_json_iter, "object"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between object fields"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_raw(const std::string_view key) noexcept { + error_code error; + bool has_value; + // + // Initially, the object can be in one of a few different places: + // + // 1. The start of the object, at the first field: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + if (at_first_field()) { + has_value = true; + + // + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + return false; + + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + if ((error = skip_child())) { abandon(); return error; } + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + while (has_value) { + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + //if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); // Skip the value entirely + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + + // If the loop ended, we're out of fields to look at. + return false; + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_unordered_raw(const std::string_view key) noexcept { + /** + * When find_field_unordered_raw is called, we can either be pointing at the + * first key, pointing outside (at the closing brace) or if a key was matched + * we can be either pointing right afterthe ':' right before the value (that we need skip), + * or we may have consumed the value and we might be at a comma or at the + * final brace (ready for a call to has_next_field()). + */ + error_code error; + bool has_value; + + // First, we scan from that point to the end. + // If we don't find a match, we may loop back around, and scan from the beginning to that point. + token_position search_start = _json_iter->position(); + + // We want to know whether we need to go back to the beginning. + bool at_first = at_first_field(); + /////////////// + // Initially, the object can be in one of a few different places: + // + // 1. At the first key: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + // + if (at_first) { + has_value = true; + + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { + +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + SIMDJSON_TRY(reset_object().get(has_value)); + at_first = true; + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + // If someone queried a key but they not did access the value, then we are left pointing + // at the ':' and we need to move forward through the value... If the value was + // processed then skip_child() does not move the iterator (but may adjust the depth). + if ((error = skip_child())) { abandon(); return error; } + search_start = _json_iter->position(); + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + + // After initial processing, we will be in one of two states: + // + // ``` + // // At the beginning of a field + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // At the end of the object + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // ``` + // + // Next, we find a match starting from the current position. + while (has_value) { + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + // Performance note: it maybe wasteful to rewind to the beginning when there might be + // no other query following. Indeed, it would require reskipping the whole object. + // Instead, you can just stay where you are. If there is a new query, there is always time + // to rewind. + if (at_first) { return false; } + + // If we reach the end without finding a match, search the rest of the fields starting at the + // beginning of the object. + // (We have already run through the object before, so we've already validated its structure. We + // don't check errors in this bit.) + SIMDJSON_TRY(reset_object().get(has_value)); + while (true) { + SIMDJSON_ASSUME(has_value); // we should reach search_start before ever reaching the end of the object + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + error = field_key().get(actual_key); SIMDJSON_ASSUME(!error); + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + error = field_value(); SIMDJSON_ASSUME(!error); + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // If we reached the end of the key-value pair we started from, then we know + // that the key is not there so we return false. We are either right before + // the next comma or the final brace. + if (_json_iter->position() == search_start) { return false; } + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + error = has_next_field().get(has_value); SIMDJSON_ASSUME(!error); + // If we make the mistake of exiting here, then we could be left pointing at a key + // in the middle of an object. That's not an allowable state. + } + // If the loop ended, we're out of fields to look at. The program should + // never reach this point. + return false; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::field_key() noexcept { + assert_at_next(); + + const uint8_t* key = _json_iter->return_current_and_advance(); + if (*(key++) != '"') { return report_error(TAPE_ERROR, "Object key is not a string"); } + return raw_json_string(key); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::field_value() noexcept { + assert_at_next(); + + if (*_json_iter->return_current_and_advance() != ':') { return report_error(TAPE_ERROR, "Missing colon in object field"); } + _json_iter->descend_to(depth() + 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_root_array(); + } + + inline std::string value_iterator::to_string() const noexcept { + auto answer = std::string("value_iterator [ depth : ") + std::to_string(_depth) + std::string(", "); + if (_json_iter != nullptr) { answer += _json_iter->to_string(); } + answer += std::string(" ]"); + return answer; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_array() noexcept { + assert_at_container_start(); + if (*_json_iter->peek() == ']') { + logger::log_value(*_json_iter, "empty array"); + _json_iter->return_current_and_advance(); + SIMDJSON_TRY(end_container()); + return false; + } + _json_iter->descend_to(depth() + 1); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_array() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // array: e.g., `[1, 2] foo]`. Users concerned with garbage content should + // also call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != ']') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing ] at end"); + } + // If the last character is ] *and* the first gibberish character is also ']' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == ']') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed array. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_array() noexcept { + auto error = check_root_array(); + if (error) { return error; } + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_element() noexcept { + assert_at_next(); + + logger::log_event(*this, "has_next_element"); + switch (*_json_iter->return_current_and_advance()) { + case ']': + logger::log_end_value(*_json_iter, "array"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + _json_iter->descend_to(depth() + 1); + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between array elements"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_bool(const uint8_t* json) const noexcept { + auto not_true = atomparsing::str4ncmp(json, "true"); + auto not_false = atomparsing::str4ncmp(json, "fals") | (json[4] ^ 'e'); + bool error = (not_true && not_false) || jsoncharutils::is_not_structural_or_whitespace(json[not_true ? 5 : 4]); + if (error) { return incorrect_type_error("Not a boolean"); } + return simdjson_result(!not_true); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_null(const uint8_t* json) const noexcept { + bool is_null_string = !atomparsing::str4ncmp(json, "null") && jsoncharutils::is_structural_or_whitespace(json[4]); + // if we start with 'n', we must be a null + if (!is_null_string && json[0] == 'n') { return incorrect_type_error("Not a null but starts with n"); } + return is_null_string; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_string(bool allow_replacement) noexcept { + return get_raw_json_string().unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_string(string_type& receiver, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_string(allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_wobbly_string() noexcept { + return get_raw_json_string().unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_raw_json_string() noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64() noexcept { + auto result = numberparsing::parse_unsigned(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64_in_string() noexcept { + auto result = numberparsing::parse_unsigned_in_string(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64() noexcept { + auto result = numberparsing::parse_integer(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64_in_string() noexcept { + auto result = numberparsing::parse_integer_in_string(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double() noexcept { + auto result = numberparsing::parse_double(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double_in_string() noexcept { + auto result = numberparsing::parse_double_in_string(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_bool() noexcept { + auto result = parse_bool(peek_non_root_scalar("bool")); + if (result.error() == SUCCESS) { advance_non_root_scalar("bool"); } + return result; + } + simdjson_inline simdjson_result value_iterator::is_null() noexcept { + bool is_null_value; + SIMDJSON_TRY(parse_null(peek_non_root_scalar("null")).get(is_null_value)); + if (is_null_value) { advance_non_root_scalar("null"); } + return is_null_value; + } + simdjson_inline bool value_iterator::is_negative() noexcept { + return numberparsing::is_negative(peek_non_root_scalar("numbersign")); + } + simdjson_inline bool value_iterator::is_root_negative() noexcept { + return numberparsing::is_negative(peek_root_scalar("numbersign")); + } + simdjson_inline simdjson_result value_iterator::is_integer() noexcept { + return numberparsing::is_integer(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number_type() noexcept { + return numberparsing::get_number_type(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number() noexcept { + number num; + error_code error = numberparsing::parse_number(peek_non_root_scalar("number"), num); + if (error) { return error; } + return num; + } + + simdjson_inline simdjson_result value_iterator::is_root_integer(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("is_root_integer"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + return false; // if there are more than 20 characters, it cannot be represented as an integer. + } + auto answer = numberparsing::is_integer(tmpbuf); + // If the parsing was a success, we must still check that it is + // a single scalar. Note that we parse first because of cases like '[]' where + // getting TRAILING_CONTENT is wrong. + if (check_trailing && (answer.error() == SUCCESS) && (!_json_iter->is_single_token())) { return TRAILING_CONTENT; } + return answer; + } + + simdjson_inline simdjson_result value_iterator::get_root_number_type(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto answer = numberparsing::get_number_type(tmpbuf); + if (check_trailing && (answer.error() == SUCCESS) && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + return answer; + } + simdjson_inline simdjson_result value_iterator::get_root_number(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + number num; + error_code error = numberparsing::parse_number(tmpbuf, num); + if (error) { return error; } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("number"); + return num; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_string(bool check_trailing, bool allow_replacement) noexcept { + return get_root_raw_json_string(check_trailing).unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_root_string(check_trailing, allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_wobbly_string(bool check_trailing) noexcept { + return get_root_raw_json_string(check_trailing).unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_raw_json_string(bool check_trailing) noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_bool(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("bool"); + uint8_t tmpbuf[5 + 1 + 1]; // +1 for null termination + tmpbuf[5 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 5 + 1)) { return incorrect_type_error("Not a boolean"); } + auto result = parse_bool(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("bool"); + } + return result; + } + simdjson_inline simdjson_result value_iterator::is_root_null(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("null"); + bool result = (max_len >= 4 && !atomparsing::str4ncmp(json, "null") && + (max_len == 4 || jsoncharutils::is_structural_or_whitespace(json[4]))); + if (result) { // we have something that looks like a null. + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("null"); + } + return result; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::skip_child() noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth >= _depth); + + return _json_iter->skip_child(depth()); + } + + simdjson_inline value_iterator value_iterator::child() const noexcept { + assert_at_child(); + return { _json_iter, depth() + 1, _json_iter->token.position() }; + } + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and iterator depth, which is a desired effect. It does not happen if is_open is + // marked non-inline. + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline bool value_iterator::is_open() const noexcept { + return _json_iter->depth() >= depth(); + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool value_iterator::at_end() const noexcept { + return _json_iter->at_end(); + } + + simdjson_inline bool value_iterator::at_start() const noexcept { + return _json_iter->token.position() == start_position(); + } + + simdjson_inline bool value_iterator::at_first_field() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + return _json_iter->token.position() == start_position() + 1; + } + + simdjson_inline void value_iterator::abandon() noexcept { + _json_iter->abandon(); + } + + simdjson_warn_unused simdjson_inline depth_t value_iterator::depth() const noexcept { + return _depth; + } + simdjson_warn_unused simdjson_inline error_code value_iterator::error() const noexcept { + return _json_iter->error; + } + simdjson_warn_unused simdjson_inline uint8_t*& value_iterator::string_buf_loc() noexcept { + return _json_iter->string_buf_loc(); + } + simdjson_warn_unused simdjson_inline const json_iterator& value_iterator::json_iter() const noexcept { + return *_json_iter; + } + simdjson_warn_unused simdjson_inline json_iterator& value_iterator::json_iter() noexcept { + return *_json_iter; + } + + simdjson_inline const uint8_t* value_iterator::peek_start() const noexcept { + return _json_iter->peek(start_position()); + } + simdjson_inline uint32_t value_iterator::peek_start_length() const noexcept { + return _json_iter->peek_length(start_position()); + } + + simdjson_inline const uint8_t* value_iterator::peek_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return peek_start(); } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return; } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept { + logger::log_start_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + const uint8_t* json; + if (!is_at_start()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + json = peek_start(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + } + else { + assert_at_start(); + /** + * We should be prudent. Let us peek. If it is not the right type, we + * return an error. Only once we have determined that we have the right + * type are we allowed to advance! + */ + json = _json_iter->peek(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + _json_iter->return_current_and_advance(); + } + + + return SUCCESS; + } + + + simdjson_inline const uint8_t* value_iterator::peek_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_root(); + return _json_iter->peek(); + } + simdjson_inline const uint8_t* value_iterator::peek_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_non_root_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_root(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + simdjson_inline void value_iterator::advance_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_non_root_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::incorrect_type_error(const char* message) const noexcept { + logger::log_error(*_json_iter, start_position(), depth(), message); + return INCORRECT_TYPE; + } + + simdjson_inline bool value_iterator::is_at_start() const noexcept { + return position() == start_position(); + } + + simdjson_inline bool value_iterator::is_at_key() const noexcept { + // Keys are at the same depth as the object. + // Note here that we could be safer and check that we are within an object, + // but we do not. + return _depth == _json_iter->_depth && *_json_iter->peek() == '"'; + } + + simdjson_inline bool value_iterator::is_at_iterator_start() const noexcept { + // We can legitimately be either at the first value ([1]), or after the array if it's empty ([]). + auto delta = position() - start_position(); + return delta == 1 || delta == 2; + } + + inline void value_iterator::assert_at_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_container_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position + 1); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_next() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + simdjson_inline void value_iterator::move_at_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position); + } + + simdjson_inline void value_iterator::move_at_container_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position + 1); + } + + simdjson_inline simdjson_result value_iterator::reset_array() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_array(); + } + + simdjson_inline simdjson_result value_iterator::reset_object() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_object(); + } + + inline void value_iterator::assert_at_child() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth + 1); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_root() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth == 1); + } + + inline void value_iterator::assert_at_non_root_start() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth > 1); + } + + inline void value_iterator::assert_is_valid() const noexcept { + SIMDJSON_ASSUME(_json_iter != nullptr); + } + + simdjson_inline bool value_iterator::is_valid() const noexcept { + return _json_iter != nullptr; + } + + simdjson_inline simdjson_result value_iterator::type() const noexcept { + switch (*peek_start()) { + case '{': + return json_type::object; + case '[': + return json_type::array; + case '"': + return json_type::string; + case 'n': + return json_type::null; + case 't': case 'f': + return json_type::boolean; + case '-': + case '0': case '1': case '2': case '3': case '4': + case '5': case '6': case '7': case '8': case '9': + return json_type::number; + default: + return TAPE_ERROR; + } + } + + simdjson_inline token_position value_iterator::start_position() const noexcept { + return _start_position; + } + + simdjson_inline token_position value_iterator::position() const noexcept { + return _json_iter->position(); + } + + simdjson_inline token_position value_iterator::end_position() const noexcept { + return _json_iter->end_position(); + } + + simdjson_inline token_position value_iterator::last_position() const noexcept { + return _json_iter->last_position(); + } + + simdjson_inline error_code value_iterator::report_error(error_code error, const char* message) noexcept { + return _json_iter->report_error(error, message); + } + + } // namespace ondemand + } // namespace fallback +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(fallback::ondemand::value_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/value_iterator-inl.h for fallback */ +/* end file simdjson/generic/ondemand/amalgamated.h for fallback */ +/* including simdjson/fallback/end.h: #include "simdjson/fallback/end.h" */ +/* begin file simdjson/fallback/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/fallback/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* undefining SIMDJSON_IMPLEMENTATION from "fallback" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/fallback/end.h */ + +#endif // SIMDJSON_FALLBACK_ONDEMAND_H +/* end file simdjson/fallback/ondemand.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(haswell) +/* including simdjson/haswell/ondemand.h: #include "simdjson/haswell/ondemand.h" */ +/* begin file simdjson/haswell/ondemand.h */ +#ifndef SIMDJSON_HASWELL_ONDEMAND_H +#define SIMDJSON_HASWELL_ONDEMAND_H + +/* including simdjson/haswell/begin.h: #include "simdjson/haswell/begin.h" */ +/* begin file simdjson/haswell/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "haswell" */ +#define SIMDJSON_IMPLEMENTATION haswell + +/* including simdjson/haswell/base.h: #include "simdjson/haswell/base.h" */ +/* begin file simdjson/haswell/base.h */ +#ifndef SIMDJSON_HASWELL_BASE_H +#define SIMDJSON_HASWELL_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_HASWELL +namespace simdjson { + /** + * Implementation for Haswell (Intel AVX2). + */ + namespace haswell { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BASE_H +/* end file simdjson/haswell/base.h */ +/* including simdjson/haswell/intrinsics.h: #include "simdjson/haswell/intrinsics.h" */ +/* begin file simdjson/haswell/intrinsics.h */ +#ifndef SIMDJSON_HASWELL_INTRINSICS_H +#define SIMDJSON_HASWELL_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + * e.g., if __AVX2__ is set... in turn, we normally set these + * macros by compiling against the corresponding architecture + * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole + * software with these advanced instructions. In simdjson, we + * want to compile the whole program for a generic target, + * and only target our specific kernels. As a workaround, + * we directly include the needed headers. These headers would + * normally guard against such usage, but we carefully included + * (or ) before, so the headers + * are fooled. + */ +#include // for _blsr_u64 +#include // for __lzcnt64 +#include // for most things (AVX2, AVX512, _popcnt64) +#include +#include +#include +#include +#include // for _mm_clmulepi64_si128 + // unfortunately, we may not get _blsr_u64, but, thankfully, clang + // has it as a macro. +#ifndef _blsr_u64 +// we roll our own +#define _blsr_u64(n) ((n - 1) & n) +#endif // _blsr_u64 +#endif // SIMDJSON_CLANG_VISUAL_STUDIO + +static_assert(sizeof(__m256i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for haswell kernel."); + +#endif // SIMDJSON_HASWELL_INTRINSICS_H +/* end file simdjson/haswell/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_TARGET_REGION("avx2,bmi,pclmul,lzcnt,popcnt") +#endif + +/* including simdjson/haswell/bitmanipulation.h: #include "simdjson/haswell/bitmanipulation.h" */ +/* begin file simdjson/haswell/bitmanipulation.h */ +#ifndef SIMDJSON_HASWELL_BITMANIPULATION_H +#define SIMDJSON_HASWELL_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmask.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return (int)_tzcnt_u64(input_num); +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + //////// + // You might expect the next line to be equivalent to + // return (int)_tzcnt_u64(input_num); + // but the generated code differs and might be less efficient? + //////// + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return _blsr_u64(input_num); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { + return int(_lzcnt_u64(input_num)); + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BITMANIPULATION_H +/* end file simdjson/haswell/bitmanipulation.h */ +/* including simdjson/haswell/bitmask.h: #include "simdjson/haswell/bitmask.h" */ +/* begin file simdjson/haswell/bitmask.h */ +#ifndef SIMDJSON_HASWELL_BITMASK_H +#define SIMDJSON_HASWELL_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processor supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_BITMASK_H +/* end file simdjson/haswell/bitmask.h */ +/* including simdjson/haswell/numberparsing_defs.h: #include "simdjson/haswell/numberparsing_defs.h" */ +/* begin file simdjson/haswell/numberparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +#define SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace haswell +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_HASWELL_NUMBERPARSING_DEFS_H +/* end file simdjson/haswell/numberparsing_defs.h */ +/* including simdjson/haswell/simd.h: #include "simdjson/haswell/simd.h" */ +/* begin file simdjson/haswell/simd.h */ +#ifndef SIMDJSON_HASWELL_SIMD_H +#define SIMDJSON_HASWELL_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + namespace simd { + + // Forward-declared so they can be used by splat and friends. + template + struct base { + __m256i value; + + // Zero constructor + simdjson_inline base() : value{ __m256i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m256i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m256i& () const { return this->value; } + simdjson_inline operator __m256i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm256_or_si256(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm256_and_si256(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm256_xor_si256(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm256_andnot_si256(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + // Forward-declared so they can be used by splat and friends. + template + struct simd8; + + template> + struct base8 : base> { + typedef uint32_t bitmask_t; + typedef uint64_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m256i _value) : base>(_value) {} + + friend simdjson_really_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm256_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm256_alignr_epi8(*this, _mm256_permute2x128_si256(prev_chunk, *this, 0x21), 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm256_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m256i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm256_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm256_testz_si256(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm256_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm256_setzero_si256(); } + static simdjson_inline simd8 load(const T values[32]) { + return _mm256_loadu_si256(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m256i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[32]) const { return _mm256_storeu_si256(reinterpret_cast<__m256i*>(dst), *this); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm256_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm256_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm256_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint32_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in four steps, first 8 bytes and then second 8 bytes... + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // second least significant 8 bits + uint8_t mask3 = uint8_t(mask >> 16); // ... + uint8_t mask4 = uint8_t(mask >> 24); // ... + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m256i shufmask = _mm256_set_epi64x(thintable_epi8[mask4], thintable_epi8[mask3], + thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask and so forth + shufmask = + _mm256_add_epi8(shufmask, _mm256_set_epi32(0x18181818, 0x18181818, + 0x10101010, 0x10101010, 0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m256i pruned = _mm256_shuffle_epi8(*this, shufmask); + // we still need to put the pieces back together. + // we compute the popcount of the first words: + int pop1 = BitsSetTable256mul2[mask1]; + int pop3 = BitsSetTable256mul2[mask3]; + + // then load the corresponding mask + // could be done with _mm256_loadu2_m128i but many standard libraries omit this intrinsic. + __m256i v256 = _mm256_castsi128_si256( + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8))); + __m256i compactmask = _mm256_insertf128_si256(v256, + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop3 * 8)), 1); + __m256i almostthere = _mm256_shuffle_epi8(pruned, compactmask); + // We just need to write out the result. + // This is the tricky bit that is hard to do + // if we want to return a SIMD register, since there + // is no single-instruction approach to recombine + // the two 128-bit lanes with an offset. + __m128i v128; + v128 = _mm256_castsi256_si128(almostthere); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), v128); + v128 = _mm256_extractf128_si256(almostthere, 1); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output + 16 - count_ones(mask & 0xFFFF)), v128); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m256i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t values[32]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, + int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, + int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31 + ) : simd8(_mm256_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v16, v17, v18, v19, v20, v21, v22, v23, + v24, v25, v26, v27, v28, v29, v30, v31 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm256_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm256_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm256_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm256_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m256i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[32]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, + uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, + uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31 + ) : simd8(_mm256_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v16, v17, v18, v19, v20, v21, v22, v23, + v24, v25, v26, v27, v28, v29, v30, v31 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm256_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm256_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm256_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm256_min_epu8(other, *this); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm256_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm256_testz_si256(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm256_testz_si256(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm256_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm256_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm256_movemask_epi8(_mm256_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 2, "Haswell kernel should use two registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 32) } {} + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + uint32_t mask1 = uint32_t(mask); + uint32_t mask2 = uint32_t(mask >> 32); + this->chunks[0].compress(mask1, output); + this->chunks[1].compress(mask2, output + 32 - count_ones(mask1)); + return 64 - count_ones(mask); + } + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r_lo = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r_hi = this->chunks[1].to_bitmask(); + return r_lo | (r_hi << 32); + } + + simdjson_inline simd8 reduce_or() const { + return this->chunks[0] | this->chunks[1]; + } + + simdjson_inline simd8x64 bit_or(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] | mask, + this->chunks[1] | mask + ); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_SIMD_H +/* end file simdjson/haswell/simd.h */ +/* including simdjson/haswell/stringparsing_defs.h: #include "simdjson/haswell/stringparsing_defs.h" */ +/* begin file simdjson/haswell/stringparsing_defs.h */ +#ifndef SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +#define SIMDJSON_HASWELL_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast((v == '\\').to_bitmask()), // bs_bits + static_cast((v == '"').to_bitmask()), // quote_bits + }; + } + + } // unnamed namespace + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_HASWELL_STRINGPARSING_DEFS_H +/* end file simdjson/haswell/stringparsing_defs.h */ +/* end file simdjson/haswell/begin.h */ +/* including simdjson/generic/ondemand/amalgamated.h for haswell: #include "simdjson/generic/ondemand/amalgamated.h" */ +/* begin file simdjson/generic/ondemand/amalgamated.h for haswell */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H) +#error simdjson/generic/ondemand/dependencies.h must be included before simdjson/generic/ondemand/amalgamated.h! +#endif + +// Stuff other things depend on +/* including simdjson/generic/ondemand/base.h for haswell: #include "simdjson/generic/ondemand/base.h" */ +/* begin file simdjson/generic/ondemand/base.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + /** + * A fast, simple, DOM-like interface that parses JSON as you use it. + * + * Designed for maximum speed and a lower memory profile. + */ + namespace ondemand { + + /** Represents the depth of a JSON value (number of nested arrays/objects). */ + using depth_t = int32_t; + + /** @copydoc simdjson::haswell::number_type */ + using number_type = simdjson::haswell::number_type; + + /** @private Position in the JSON buffer indexes */ + using token_position = const uint32_t*; + + class array; + class array_iterator; + class document; + class document_reference; + class document_stream; + class field; + class json_iterator; + enum class json_type; + struct number; + class object; + class object_iterator; + class parser; + class raw_json_string; + class token_iterator; + class value; + class value_iterator; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_BASE_H +/* end file simdjson/generic/ondemand/base.h for haswell */ +/* including simdjson/generic/ondemand/value_iterator.h for haswell: #include "simdjson/generic/ondemand/value_iterator.h" */ +/* begin file simdjson/generic/ondemand/value_iterator.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * Iterates through a single JSON value at a particular depth. + * + * Does not keep track of the type of value: provides methods for objects, arrays and scalars and expects + * the caller to call the right ones. + * + * @private This is not intended for external use. + */ + class value_iterator { + protected: + /** The underlying JSON iterator */ + json_iterator* _json_iter{}; + /** The depth of this value */ + depth_t _depth{}; + /** + * The starting token index for this value + */ + token_position _start_position{}; + + public: + simdjson_inline value_iterator() noexcept = default; + + /** + * Denote that we're starting a document. + */ + simdjson_inline void start_document() noexcept; + + /** + * Skips a non-iterated or partially-iterated JSON value, whether it is a scalar, array or object. + * + * Optimized for scalars. + */ + simdjson_warn_unused simdjson_inline error_code skip_child() noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is at the start of the value + */ + simdjson_inline bool at_start() const noexcept; + + /** + * Tell whether the value is open--if the value has not been used, or the array/object is still open. + */ + simdjson_inline bool is_open() const noexcept; + + /** + * Tell whether the value is at an object's first field (just after the {). + */ + simdjson_inline bool at_first_field() const noexcept; + + /** + * Abandon all iteration. + */ + simdjson_inline void abandon() noexcept; + + /** + * Get the child value as a value_iterator. + */ + simdjson_inline value_iterator child_value() const noexcept; + + /** + * Get the depth of this value. + */ + simdjson_inline int32_t depth() const noexcept; + + /** + * Get the JSON type of this value. + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() const noexcept; + + /** + * @addtogroup object Object iteration + * + * Methods to iterate and find object fields. These methods generally *assume* the value is + * actually an object; the caller is responsible for keeping track of that fact. + * + * @{ + */ + + /** + * Start an object iteration. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + */ + simdjson_warn_unused simdjson_inline simdjson_result start_object() noexcept; + /** + * Start an object iteration from the root. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_object() noexcept; + /** + * Checks whether an object could be started from the root. May be called by start_root_object. + * + * @returns SUCCESS if it is possible to safely start an object from the root (document level). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_object() noexcept; + /** + * Start an object iteration after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_object() noexcept; + /** + * Start an object iteration from the root, after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_object() noexcept; + + /** + * Moves to the next field in an object. + * + * Looks for , and }. If } is found, the object is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return whether there is another field in the object. + * @error TAPE_ERROR If there is a comma missing between fields. + * @error TAPE_ERROR If there is a comma, but not enough tokens remaining to have a key, :, and value. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_field() noexcept; + + /** + * Get the current field's key. + */ + simdjson_warn_unused simdjson_inline simdjson_result field_key() noexcept; + + /** + * Pass the : in the field and move to its value. + */ + simdjson_warn_unused simdjson_inline error_code field_value() noexcept; + + /** + * Find the next field with the given key. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline error_code find_field(const std::string_view key) noexcept; + + /** + * Find the next field with the given key, *without* unescaping. This assumes object order: it + * will not find the field if it was already passed when looking for some *other* field. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_raw(const std::string_view key) noexcept; + + /** + * Find the field with the given key without regard to order, and *without* unescaping. + * + * This is an unordered object lookup: if the field is not found initially, it will cycle around and scan from the beginning. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_unordered_raw(const std::string_view key) noexcept; + + /** @} */ + + /** + * @addtogroup array Array iteration + * Methods to iterate over array elements. These methods generally *assume* the value is actually + * an object; the caller is responsible for keeping track of that fact. + * @{ + */ + + /** + * Check for an opening [ and start an array iteration. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + */ + simdjson_warn_unused simdjson_inline simdjson_result start_array() noexcept; + /** + * Check for an opening [ and start an array iteration while at the root. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_array() noexcept; + /** + * Checks whether an array could be started from the root. May be called by start_root_array. + * + * @returns SUCCESS if it is possible to safely start an array from the root (document level). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_array() noexcept; + /** + * Start an array iteration, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_array() noexcept; + /** + * Start an array iteration from the root, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_array() noexcept; + + /** + * Moves to the next element in an array. + * + * Looks for , and ]. If ] is found, the array is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return Whether there is another element in the array. + * @error TAPE_ERROR If there is a comma missing between elements. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_element() noexcept; + + /** + * Get a child value iterator. + */ + simdjson_warn_unused simdjson_inline value_iterator child() const noexcept; + + /** @} */ + + /** + * @defgroup scalar Scalar values + * @addtogroup scalar + * @{ + */ + + simdjson_warn_unused simdjson_inline simdjson_result get_string(bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_bool() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_null() noexcept; + simdjson_warn_unused simdjson_inline bool is_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_integer() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + simdjson_warn_unused simdjson_inline simdjson_result get_root_string(bool check_trailing, bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_wobbly_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_raw_json_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_bool(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline bool is_root_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_integer(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number_type(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_null(bool check_trailing) noexcept; + + simdjson_inline error_code error() const noexcept; + simdjson_inline uint8_t*& string_buf_loc() noexcept; + simdjson_inline const json_iterator& json_iter() const noexcept; + simdjson_inline json_iterator& json_iter() noexcept; + + simdjson_inline void assert_is_valid() const noexcept; + simdjson_inline bool is_valid() const noexcept; + + /** @} */ + protected: + /** + * Restarts an array iteration. + * @returns Whether the array has any elements (returns false for empty). + */ + simdjson_inline simdjson_result reset_array() noexcept; + /** + * Restarts an object iteration. + * @returns Whether the object has any fields (returns false for empty). + */ + simdjson_inline simdjson_result reset_object() noexcept; + /** + * move_at_start(): moves us so that we are pointing at the beginning of + * the container. It updates the index so that at_start() is true and it + * syncs the depth. The user can then create a new container instance. + * + * Usage: used with value::count_elements(). + **/ + simdjson_inline void move_at_start() noexcept; + + /** + * move_at_container_start(): moves us so that we are pointing at the beginning of + * the container so that assert_at_container_start() passes. + * + * Usage: used with reset_array() and reset_object(). + **/ + simdjson_inline void move_at_container_start() noexcept; + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + simdjson_inline value_iterator(json_iterator* json_iter, depth_t depth, token_position start_index) noexcept; + + simdjson_inline simdjson_result parse_null(const uint8_t* json) const noexcept; + simdjson_inline simdjson_result parse_bool(const uint8_t* json) const noexcept; + simdjson_inline const uint8_t* peek_start() const noexcept; + simdjson_inline uint32_t peek_start_length() const noexcept; + + /** + * The general idea of the advance_... methods and the peek_* methods + * is that you first peek and check that you have desired type. If you do, + * and only if you do, then you advance. + * + * We used to unconditionally advance. But this made reasoning about our + * current state difficult. + * Suppose you always advance. Look at the 'value' matching the key + * "shadowable" in the following example... + * + * ({"globals":{"a":{"shadowable":[}}}}) + * + * If the user thinks it is a Boolean and asks for it, then we check the '[', + * decide it is not a Boolean, but still move into the next character ('}'). Now + * we are left pointing at '}' right after a '['. And we have not yet reported + * an error, only that we do not have a Boolean. + * + * If, instead, you just stand your ground until it is content that you know, then + * you will only even move beyond the '[' if the user tells you that you have an + * array. So you will be at the '}' character inside the array and, hopefully, you + * will then catch the error because an array cannot start with '}', but the code + * processing Boolean values does not know this. + * + * So the contract is: first call 'peek_...' and then call 'advance_...' only + * if you have determined that it is a type you can handle. + * + * Unfortunately, it makes the code more verbose, longer and maybe more error prone. + */ + + simdjson_inline void advance_scalar(const char* type) noexcept; + simdjson_inline void advance_root_scalar(const char* type) noexcept; + simdjson_inline void advance_non_root_scalar(const char* type) noexcept; + + simdjson_inline const uint8_t* peek_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_root_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_non_root_scalar(const char* type) noexcept; + + + simdjson_inline error_code start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept; + simdjson_inline error_code end_container() noexcept; + + /** + * Advance to a place expecting a value (increasing depth). + * + * @return The current token (the one left behind). + * @error TAPE_ERROR If the document ended early. + */ + simdjson_inline simdjson_result advance_to_value() noexcept; + + simdjson_inline error_code incorrect_type_error(const char* message) const noexcept; + simdjson_inline error_code error_unless_more_tokens(uint32_t tokens = 1) const noexcept; + + simdjson_inline bool is_at_start() const noexcept; + /** + * is_at_iterator_start() returns true on an array or object after it has just been + * created, whether the instance is empty or not. + * + * Usage: used by array::begin() in debug mode (SIMDJSON_DEVELOPMENT_CHECKS) + */ + simdjson_inline bool is_at_iterator_start() const noexcept; + + /** + * Assuming that we are within an object, this returns true if we + * are pointing at a key. + * + * Usage: the skip_child() method should never be used while we are pointing + * at a key inside an object. + */ + simdjson_inline bool is_at_key() const noexcept; + + inline void assert_at_start() const noexcept; + inline void assert_at_container_start() const noexcept; + inline void assert_at_root() const noexcept; + inline void assert_at_child() const noexcept; + inline void assert_at_next() const noexcept; + inline void assert_at_non_root_start() const noexcept; + + /** Get the starting position of this value */ + simdjson_inline token_position start_position() const noexcept; + + /** @copydoc error_code json_iterator::position() const noexcept; */ + simdjson_inline token_position position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position last_position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position end_position() const noexcept; + /** @copydoc error_code json_iterator::report_error(error_code error, const char *message) noexcept; */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + friend class document; + friend class object; + friend class array; + friend class value; + }; // value_iterator + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::value_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H +/* end file simdjson/generic/ondemand/value_iterator.h for haswell */ +/* including simdjson/generic/ondemand/value.h for haswell: #include "simdjson/generic/ondemand/value.h" */ +/* begin file simdjson/generic/ondemand/value.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * An ephemeral JSON value returned during iteration. It is only valid for as long as you do + * not access more data in the JSON document. + */ + class value { + public: + /** + * Create a new invalid value. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline value() noexcept = default; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) noexcept; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() noexcept; + + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() noexcept; + + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + + /** + * Cast this JSON value (inside string) to a unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + + /** + * Cast this JSON value to a "wobbly" string. + * + * The string is may not be a valid UTF-8 string. + * See https://simonsapin.github.io/wtf-8/ + * + * Important: a value should be consumed once. Calling get_wobbly_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); +#endif + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + * + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * Performance hint: You should only call count_elements() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method on the object instance. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @return The type of JSON value (json_type::array, json_type::object, json_type::string, + * json_type::number, json_type::boolean, or json_type::null). + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the value is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the value is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the value is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * Performance note: if you call this function systematically + * before parsing a number, you may have fallen for a performance + * anti-pattern. + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + * + * Performance note: this is designed with performance in mind. When + * calling 'get_number()', you scan the number string only once, determining + * efficiently the type and storing it in an efficient manner. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. However, if this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view is guaranteed to be + * a non-space token. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + * + * See also value::raw_json(). + */ + simdjson_inline std::string_view raw_json_token() noexcept; + + /** + * Get a string_view pointing at this value in the JSON document. + * If this element is an array or an object, it consumes the array or the object + * and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + * If this element is a scalar (string, number, Boolean, null), it returns what + * raw_json_token() would return. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + simdjson_inline simdjson_result current_location() noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. + * + * Calling at_pointer() on non-document instances (e.g., arrays and objects) is not + * standardized (by RFC 6901). We provide some experimental support for JSON pointers + * on non-document instances. Yet it is not the case when calling at_pointer on an array + * or an object instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + protected: + /** + * Create a value. + */ + simdjson_inline value(const value_iterator& iter) noexcept; + + /** + * Skip this value, allowing iteration to continue. + */ + simdjson_inline void skip() noexcept; + + /** + * Start a value at the current position. + * + * (It should already be started; this is just a self-documentation method.) + */ + static simdjson_inline value start(const value_iterator& iter) noexcept; + + /** + * Resume a value. + */ + static simdjson_inline value resume(const value_iterator& iter) noexcept; + + /** + * Get the object, starting or resuming it as necessary + */ + simdjson_inline simdjson_result start_or_resume_object() noexcept; + + // simdjson_inline void log_value(const char *type) const noexcept; + // simdjson_inline void log_error(const char *message) const noexcept; + + value_iterator iter{}; + + friend class document; + friend class array_iterator; + friend class field; + friend class object; + friend struct simdjson_result; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::value&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result get_array() noexcept; + simdjson_inline simdjson_result get_object() noexcept; + + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() noexcept; + + template simdjson_inline error_code get(T& out) noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator haswell::ondemand::array() noexcept(false); + simdjson_inline operator haswell::ondemand::object() noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator haswell::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + */ + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + + /** @copydoc simdjson_inline std::string_view value::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + /** @copydoc simdjson_inline simdjson_result current_location() noexcept */ + simdjson_inline simdjson_result current_location() noexcept; + /** @copydoc simdjson_inline int32_t current_depth() const noexcept */ + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_H +/* end file simdjson/generic/ondemand/value.h for haswell */ +/* including simdjson/generic/ondemand/logger.h for haswell: #include "simdjson/generic/ondemand/logger.h" */ +/* begin file simdjson/generic/ondemand/logger.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + // Logging should be free unless SIMDJSON_VERBOSE_LOGGING is set. Importantly, it is critical + // that the call to the log functions be side-effect free. Thus, for example, you should not + // create temporary std::string instances. + namespace logger { + + enum class log_level : int32_t { + info = 0, + error = 1 + }; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + + // We do not want these functions to be 'really inlined' since real inlining is + // for performance purposes and if you are using the loggers, you do not care about + // performance (or should not). + static inline void log_headers() noexcept; + // If args are provided, title will be treated as format string + template + static inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + template + static inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + static inline void log_event(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_value(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_start_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail = "") noexcept; + static inline void log_error(const json_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_event(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_error(const value_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + } // namespace logger + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_H +/* end file simdjson/generic/ondemand/logger.h for haswell */ +/* including simdjson/generic/ondemand/token_iterator.h for haswell: #include "simdjson/generic/ondemand/token_iterator.h" */ +/* begin file simdjson/generic/ondemand/token_iterator.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * Iterates through JSON tokens (`{` `}` `[` `]` `,` `:` `""` `123` `true` `false` `null`) + * detected by stage 1. + * + * @private This is not intended for external use. + */ + class token_iterator { + public: + /** + * Create a new invalid token_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline token_iterator() noexcept = default; + simdjson_inline token_iterator(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator& operator=(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator(const token_iterator& other) noexcept = default; + simdjson_inline token_iterator& operator=(const token_iterator& other) noexcept = default; + + /** + * Advance to the next token (returning the current one). + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + /** + * Reports the current offset in bytes from the start of the underlying buffer. + */ + simdjson_inline uint32_t current_offset() const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + + /** + * Return the current index. + */ + simdjson_inline token_position position() const noexcept; + /** + * Reset to a previously saved index. + */ + simdjson_inline void set_position(token_position target_position) noexcept; + + // NOTE: we don't support a full C++ iterator interface, because we expect people to make + // different calls to advance the iterator based on *their own* state. + + simdjson_inline bool operator==(const token_iterator& other) const noexcept; + simdjson_inline bool operator!=(const token_iterator& other) const noexcept; + simdjson_inline bool operator>(const token_iterator& other) const noexcept; + simdjson_inline bool operator>=(const token_iterator& other) const noexcept; + simdjson_inline bool operator<(const token_iterator& other) const noexcept; + simdjson_inline bool operator<=(const token_iterator& other) const noexcept; + + protected: + simdjson_inline token_iterator(const uint8_t* buf, token_position position) noexcept; + + /** + * Get the index of the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_index(int32_t delta = 0) const noexcept; + /** + * Get the index of the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline uint32_t peek_index(token_position position) const noexcept; + + const uint8_t* buf{}; + token_position _position{}; + + friend class json_iterator; + friend class value_iterator; + friend class object; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::token_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H +/* end file simdjson/generic/ondemand/token_iterator.h for haswell */ +/* including simdjson/generic/ondemand/json_iterator.h for haswell: #include "simdjson/generic/ondemand/json_iterator.h" */ +/* begin file simdjson/generic/ondemand/json_iterator.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * Iterates through JSON tokens, keeping track of depth and string buffer. + * + * @private This is not intended for external use. + */ + class json_iterator { + protected: + token_iterator token{}; + ondemand::parser* parser{}; + /** + * Next free location in the string buffer. + * + * Used by raw_json_string::unescape() to have a place to unescape strings to. + */ + uint8_t* _string_buf_loc{}; + /** + * JSON error, if there is one. + * + * INCORRECT_TYPE and NO_SUCH_FIELD are *not* stored here, ever. + * + * PERF NOTE: we *hope* this will be elided into control flow, as it is only used (a) in the first + * iteration of the loop, or (b) for the final iteration after a missing comma is found in ++. If + * this is not elided, we should make sure it's at least not using up a register. Failing that, + * we should store it in document so there's only one of them. + */ + error_code error{ SUCCESS }; + /** + * Depth of the current token in the JSON. + * + * - 0 = finished with document + * - 1 = document root value (could be [ or {, not yet known) + * - 2 = , or } inside root array/object + * - 3 = key or value inside root array/object. + */ + depth_t _depth{}; + /** + * Beginning of the document indexes. + * Normally we have root == parser->implementation->structural_indexes.get() + * but this may differ, especially in streaming mode (where we have several + * documents); + */ + token_position _root{}; + /** + * Normally, a json_iterator operates over a single document, but in + * some cases, we may have a stream of documents. This attribute is meant + * as meta-data: the json_iterator works the same irrespective of the + * value of this attribute. + */ + bool _streaming{ false }; + + public: + simdjson_inline json_iterator() noexcept = default; + simdjson_inline json_iterator(json_iterator&& other) noexcept; + simdjson_inline json_iterator& operator=(json_iterator&& other) noexcept; + simdjson_inline explicit json_iterator(const json_iterator& other) noexcept = default; + simdjson_inline json_iterator& operator=(const json_iterator& other) noexcept = default; + /** + * Skips a JSON value, whether it is a scalar, array or object. + */ + simdjson_warn_unused simdjson_inline error_code skip_child(depth_t parent_depth) noexcept; + + /** + * Tell whether the iterator is still at the start + */ + simdjson_inline bool at_root() const noexcept; + + /** + * Tell whether we should be expected to run in streaming + * mode (iterating over many documents). It is pure metadata + * that does not affect how the iterator works. It is used by + * start_root_array() and start_root_object(). + */ + simdjson_inline bool streaming() const noexcept; + + /** + * Get the root value iterator + */ + simdjson_inline token_position root_position() const noexcept; + /** + * Assert that we are at the document depth (== 1) + */ + simdjson_inline void assert_at_document_depth() const noexcept; + /** + * Assert that we are at the root of the document + */ + simdjson_inline void assert_at_root() const noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is live (has not been moved). + */ + simdjson_inline bool is_alive() const noexcept; + + /** + * Abandon this iterator, setting depth to 0 (as if the document is finished). + */ + simdjson_inline void abandon() noexcept; + + /** + * Advance the current token without modifying depth. + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + + /** + * Returns true if there is a single token in the index (i.e., it is + * a JSON with a scalar value such as a single number). + * + * @return whether there is a single token + */ + simdjson_inline bool is_single_token() const noexcept; + + /** + * Assert that there are at least the given number of tokens left. + * + * Has no effect in release builds. + */ + simdjson_inline void assert_more_tokens(uint32_t required_tokens = 1) const noexcept; + /** + * Assert that the given position addresses an actual token (is within bounds). + * + * Has no effect in release builds. + */ + simdjson_inline void assert_valid_position(token_position position) const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + /** + * Get a pointer to the current location in the input buffer. + * + * This is not null-terminated; it is a view into the JSON. + * + * You may be pointing outside of the input buffer: it is not generally + * safe to dereference this pointer. + */ + simdjson_inline const uint8_t* unsafe_pointer() const noexcept; + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token to retrieve. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token to retrieve. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + /** + * Get the JSON text for the last token in the document. + * + * This is not null-terminated; it is a view into the JSON. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek_last() const noexcept; + + /** + * Ascend one level. + * + * Validates that the depth - 1 == parent_depth. + * + * @param parent_depth the expected parent depth. + */ + simdjson_inline void ascend_to(depth_t parent_depth) noexcept; + + /** + * Descend one level. + * + * Validates that the new depth == child_depth. + * + * @param child_depth the expected child depth. + */ + simdjson_inline void descend_to(depth_t child_depth) noexcept; + simdjson_inline void descend_to(depth_t child_depth, int32_t delta) noexcept; + + /** + * Get current depth. + */ + simdjson_inline depth_t depth() const noexcept; + + /** + * Get current (writeable) location in the string buffer. + */ + simdjson_inline uint8_t*& string_buf_loc() noexcept; + + /** + * Report an unrecoverable error, preventing further iteration. + * + * @param error The error to report. Must not be SUCCESS, UNINITIALIZED, INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + /** + * Log error, but don't stop iteration. + * @param error The error to report. Must be INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code optional_error(error_code error, const char* message) noexcept; + + /** + * Take an input in json containing max_len characters and attempt to copy it over to tmpbuf, a buffer with + * N bytes of capacity. It will return false if N is too small (smaller than max_len) of if it is zero. + * The buffer (tmpbuf) is padded with space characters. + */ + simdjson_warn_unused simdjson_inline bool copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept; + + simdjson_inline token_position position() const noexcept; + /** + * Write the raw_json_string to the string buffer and return a string_view. + * Each raw_json_string should be unescaped once, or else the string buffer might + * overflow. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, bool allow_replacement) noexcept; + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in) noexcept; + + simdjson_inline void reenter_child(token_position position, depth_t child_depth) noexcept; + + simdjson_inline error_code consume_character(char c) noexcept; +#if SIMDJSON_DEVELOPMENT_CHECKS + simdjson_inline token_position start_position(depth_t depth) const noexcept; + simdjson_inline void set_start_position(depth_t depth, token_position position) noexcept; +#endif + + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Updates this json iterator so that it is back at the beginning of the document, + * as if it had just been created. + */ + inline void rewind() noexcept; + /** + * This checks whether the {,},[,] are balanced so that the document + * ends with proper zero depth. This requires scanning the whole document + * and it may be expensive. It is expected that it will be rarely called. + * It does not attempt to match { with } and [ with ]. + */ + inline bool balanced() const noexcept; + protected: + simdjson_inline json_iterator(const uint8_t* buf, ondemand::parser* parser) noexcept; + /// The last token before the end + simdjson_inline token_position last_position() const noexcept; + /// The token *at* the end. This points at gibberish and should only be used for comparison. + simdjson_inline token_position end_position() const noexcept; + /// The end of the buffer. + simdjson_inline token_position end() const noexcept; + + friend class document; + friend class document_stream; + friend class object; + friend class array; + friend class value; + friend class raw_json_string; + friend class parser; + friend class value_iterator; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; // json_iterator + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::json_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H +/* end file simdjson/generic/ondemand/json_iterator.h for haswell */ +/* including simdjson/generic/ondemand/json_type.h for haswell: #include "simdjson/generic/ondemand/json_type.h" */ +/* begin file simdjson/generic/ondemand/json_type.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * The type of a JSON value. + */ + enum class json_type { + // Start at 1 to catch uninitialized / default values more easily + array = 1, ///< A JSON array ( [ 1, 2, 3 ... ] ) + object, ///< A JSON object ( { "a": 1, "b" 2, ... } ) + number, ///< A JSON number ( 1 or -2.3 or 4.5e6 ...) + string, ///< A JSON string ( "a" or "hello world\n" ...) + boolean, ///< A JSON boolean (true or false) + null ///< A JSON null (null) + }; + + /** + * A type representing a JSON number. + * The design of the struct is deliberately straight-forward. All + * functions return standard values with no error check. + */ + struct number { + + /** + * return the automatically determined type of + * the number: number_type::floating_point_number, + * number_type::signed_integer or number_type::unsigned_integer. + * + * enum class number_type { + * floating_point_number=1, /// a binary64 number + * signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + * unsigned_integer /// a positive integer larger or equal to 1<<63 + * }; + */ + simdjson_inline ondemand::number_type get_number_type() const noexcept; + /** + * return true if the automatically determined type of + * the number is number_type::unsigned_integer. + */ + simdjson_inline bool is_uint64() const noexcept; + /** + * return the value as a uint64_t, only valid if is_uint64() is true. + */ + simdjson_inline uint64_t get_uint64() const noexcept; + simdjson_inline operator uint64_t() const noexcept; + + /** + * return true if the automatically determined type of + * the number is number_type::signed_integer. + */ + simdjson_inline bool is_int64() const noexcept; + /** + * return the value as a int64_t, only valid if is_int64() is true. + */ + simdjson_inline int64_t get_int64() const noexcept; + simdjson_inline operator int64_t() const noexcept; + + + /** + * return true if the automatically determined type of + * the number is number_type::floating_point_number. + */ + simdjson_inline bool is_double() const noexcept; + /** + * return the value as a double, only valid if is_double() is true. + */ + simdjson_inline double get_double() const noexcept; + simdjson_inline operator double() const noexcept; + + /** + * Convert the number to a double. Though it always succeed, the conversion + * may be lossy if the number cannot be represented exactly. + */ + simdjson_inline double as_double() const noexcept; + + + protected: + /** + * The next block of declaration is designed so that we can call the number parsing + * functions on a number type. They are protected and should never be used outside + * of the core simdjson library. + */ + friend class value_iterator; + template + friend error_code numberparsing::slow_float_parsing(simdjson_unused const uint8_t* src, W writer); + template + friend error_code numberparsing::write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer); + template + friend error_code numberparsing::parse_number(const uint8_t* const src, W& writer); + /** Store a signed 64-bit value to the number. */ + simdjson_inline void append_s64(int64_t value) noexcept; + /** Store an unsigned 64-bit value to the number. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + /** Store a double value to the number. */ + simdjson_inline void append_double(double value) noexcept; + /** Specifies that the value is a double, but leave it undefined. */ + simdjson_inline void skip_double() noexcept; + /** + * End of friend declarations. + */ + + /** + * Our attributes are a union type (size = 64 bits) + * followed by a type indicator. + */ + union { + double floating_point_number; + int64_t signed_integer; + uint64_t unsigned_integer; + } payload{ 0 }; + number_type type{ number_type::signed_integer }; + }; + + /** + * Write the JSON type to the output stream + * + * @param out The output stream. + * @param type The json_type. + */ + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Send JSON type to an output stream. + * + * @param out The output stream. + * @param type The json_type. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false); +#endif + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::json_type&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H +/* end file simdjson/generic/ondemand/json_type.h for haswell */ +/* including simdjson/generic/ondemand/raw_json_string.h for haswell: #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * A string escaped per JSON rules, terminated with quote ("). They are used to represent + * unescaped keys inside JSON documents. + * + * (In other words, a pointer to the beginning of a string, just after the start quote, inside a + * JSON file.) + * + * This class is deliberately simplistic and has little functionality. You can + * compare a raw_json_string instance with an unescaped C string, but + * that is nearly all you can do. + * + * The raw_json_string is unescaped. If you wish to write an unescaped version of it to your own + * buffer, you may do so using the parser.unescape(string, buff) method, using an ondemand::parser + * instance. Doing so requires you to have a sufficiently large buffer. + * + * The raw_json_string instances originate typically from field instance which in turn represent + * key-value pairs from object instances. From a field instance, you get the raw_json_string + * instance by calling key(). You can, if you want a more usable string_view instance, call + * the unescaped_key() method on the field instance. You may also create a raw_json_string from + * any other string value, with the value.get_raw_json_string() method. Again, you can get + * a more usable string_view instance by calling get_string(). + * + */ + class raw_json_string { + public: + /** + * Create a new invalid raw_json_string. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline raw_json_string() noexcept = default; + + /** + * Create a new invalid raw_json_string pointed at the given location in the JSON. + * + * The given location must be just *after* the beginning quote (") in the JSON file. + * + * It *must* be terminated by a ", and be a valid JSON string. + */ + simdjson_inline raw_json_string(const uint8_t* _buf) noexcept; + /** + * Get the raw pointer to the beginning of the string in the JSON (just after the "). + * + * It is possible for this function to return a null pointer if the instance + * has outlived its existence. + */ + simdjson_inline const char* raw() const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done) on target.size() characters, + * and if the raw_json_string instance has a quote character at byte index target.size(). + * We never read more than length + 1 bytes in the raw_json_string instance. + * If length is smaller than target.size(), this will return false. + * + * The std::string_view instance may contain any characters. However, the caller + * is responsible for setting length so that length bytes may be read in the + * raw_json_string. + * + * Performance: the comparison may be done using memcmp which may be efficient + * for long strings. + */ + simdjson_inline bool unsafe_is_equal(size_t length, std::string_view target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The std::string_view instance should not contain unescaped quote characters: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * Performance: the comparison is done byte-by-byte which might be inefficient for + * long strings. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The provided C string should not contain an unescaped quote character: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(const char* target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(const char* target) const noexcept; + + /** + * Returns true if target is free from unescaped quote. If target is known at + * compile-time, we might expect the computation to happen at compile time with + * many compilers (not all!). + */ + static simdjson_inline bool is_free_from_unescaped_quote(std::string_view target) noexcept; + static simdjson_inline bool is_free_from_unescaped_quote(const char* target) noexcept; + + private: + + + /** + * This will set the inner pointer to zero, effectively making + * this instance unusable. + */ + simdjson_inline void consume() noexcept { buf = nullptr; } + + /** + * Checks whether the inner pointer is non-null and thus usable. + */ + simdjson_inline simdjson_warn_unused bool alive() const noexcept { return buf != nullptr; } + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result will be a valid UTF-8. + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + * @param allow_replacement Whether we allow replacement of invalid surrogate pairs. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape(json_iterator& iter, bool allow_replacement) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result may not be a valid UTF-8. https://simonsapin.github.io/wtf-8/ + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(json_iterator& iter) const noexcept; + const uint8_t* buf{}; + friend class object; + friend class field; + friend class parser; + friend struct simdjson_result; + }; + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream&, const raw_json_string&) noexcept; + + /** + * Comparisons between raw_json_string and std::string_view instances are potentially unsafe: the user is responsible + * for providing a string with no unescaped quote. Note that unescaped quotes cannot be present in valid JSON strings. + */ + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept; + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept; + + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::raw_json_string&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + + simdjson_inline simdjson_result raw() const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape(haswell::ondemand::json_iterator& iter, bool allow_replacement) const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(haswell::ondemand::json_iterator& iter) const noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H +/* end file simdjson/generic/ondemand/raw_json_string.h for haswell */ +/* including simdjson/generic/ondemand/parser.h for haswell: #include "simdjson/generic/ondemand/parser.h" */ +/* begin file simdjson/generic/ondemand/parser.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * The default batch size for document_stream instances for this On Demand kernel. + * Note that different On Demand kernel may use a different DEFAULT_BATCH_SIZE value + * in the future. + */ + static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; + /** + * Some adversary might try to set the batch size to 0 or 1, which might cause problems. + * We set a minimum of 32B since anything else is highly likely to be an error. In practice, + * most users will want a much larger batch size. + * + * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON + * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. + */ + static constexpr size_t MINIMAL_BATCH_SIZE = 32; + + /** + * A JSON fragment iterator. + * + * This holds the actual iterator as well as the buffer for writing strings. + */ + class parser { + public: + /** + * Create a JSON parser. + * + * The new parser will have zero capacity. + */ + inline explicit parser(size_t max_capacity = SIMDJSON_MAXSIZE_BYTES) noexcept; + + inline parser(parser&& other) noexcept = default; + simdjson_inline parser(const parser& other) = delete; + simdjson_inline parser& operator=(const parser& other) = delete; + simdjson_inline parser& operator=(parser&& other) noexcept = default; + + /** Deallocate the JSON parser. */ + inline ~parser() noexcept = default; + + /** + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * document doc = parser.iterate(json); + * + * It is expected that the content is a valid UTF-8 file, containing a valid JSON document. + * Otherwise the iterate method may return an error. In particular, the whole input should be + * valid: we do not attempt to tolerate incorrect content either before or after a JSON + * document. If there is a UTF-8 BOM, the parser skips it. + * + * ### IMPORTANT: Validate what you use + * + * Calling iterate on an invalid JSON document may not immediately trigger an error. The call to + * iterate does not parse and validate the whole document. + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * @param len The length of the JSON. + * @param capacity The number of bytes allocated in the JSON (must be at least len+SIMDJSON_PADDING). + * + * @return The document, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate(padded_string_view json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const char* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const uint8_t* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string_view json, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(padded_string&& json) & noexcept = delete; + + /** + * @private + * + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * json_iterator doc = parser.iterate(json); + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * The ondemand::document instance holds the iterator. The document must remain in scope + * while you are accessing instances of ondemand::value, ondemand::object, ondemand::array. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * + * @return The iterator, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate_raw(padded_string_view json) & noexcept; + + + /** + * Parse a buffer containing many JSON documents. + * + * auto json = R"({ "foo": 1 } { "foo": 2 } { "foo": 3 } )"_padded; + * ondemand::parser parser; + * ondemand::document_stream docs = parser.iterate_many(json); + * for (auto & doc : docs) { + * std::cout << doc["foo"] << std::endl; + * } + * // Prints 1 2 3 + * + * No copy of the input buffer is made. + * + * The function is lazy: it may be that no more than one JSON document at a time is parsed. + * + * The caller is responsabile to ensure that the input string data remains unchanged and is + * not deleted during the loop. + * + * ### Format + * + * The buffer must contain a series of one or more JSON documents, concatenated into a single + * buffer, separated by ASCII whitespace. It effectively parses until it has a fully valid document, + * then starts parsing the next document at that point. (It does this with more parallelism and + * lookahead than you might think, though.) + * + * documents that consist of an object or array may omit the whitespace between them, concatenating + * with no separator. Documents that consist of a single primitive (i.e. documents that are not + * arrays or objects) MUST be separated with ASCII whitespace. + * + * The characters inside a JSON document, and between JSON documents, must be valid Unicode (UTF-8). + * If there is a UTF-8 BOM, the parser skips it. + * + * The documents must not exceed batch_size bytes (by default 1MB) or they will fail to parse. + * Setting batch_size to excessively large or excessively small values may impact negatively the + * performance. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * ### Threads + * + * When compiled with SIMDJSON_THREADS_ENABLED, this method will use a single thread under the + * hood to do some lookahead. + * + * ### Parser Capacity + * + * If the parser's current capacity is less than batch_size, it will allocate enough capacity + * to handle it (up to max_capacity). + * + * @param buf The concatenated JSON to parse. + * @param len The length of the concatenated JSON. + * @param batch_size The batch size to use. MUST be larger than the largest document. The sweet + * spot is cache-related: small enough to fit in cache, yet big enough to + * parse as many documents as possible in one tight loop. + * Defaults to 10MB, which has been a reasonable sweet spot in our tests. + * @param allow_comma_separated (defaults on false) This allows a mode where the documents are + * separated by commas instead of whitespace. It comes with a performance + * penalty because the entire document is indexed at once (and the document must be + * less than 4 GB), and there is no multithreading. In this mode, the batch_size parameter + * is effectively ignored, as it is set to at least the document size. + * @return The stream, or an error. An empty input will yield 0 documents rather than an EMPTY error. Errors: + * - MEMALLOC if the parser does not have enough capacity and memory allocation fails + * - CAPACITY if the parser does not have enough capacity and batch_size > max_capacity. + * - other json errors if parsing fails. You should not rely on these errors to always the same for the + * same document: they may vary under runtime dispatch (so they may vary depending on your system and hardware). + */ + inline simdjson_result iterate_many(const uint8_t* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const char* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const std::string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const std::string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const padded_string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const padded_string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + + /** @private We do not want to allow implicit conversion from C string to std::string. */ + simdjson_result iterate_many(const char* buf, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept = delete; + + /** The capacity of this parser (the largest document it can process). */ + simdjson_inline size_t capacity() const noexcept; + /** The maximum capacity of this parser (the largest document it is allowed to process). */ + simdjson_inline size_t max_capacity() const noexcept; + simdjson_inline void set_max_capacity(size_t max_capacity) noexcept; + /** + * The maximum depth of this parser (the most deeply nested objects and arrays it can process). + * This parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + */ + simdjson_inline size_t max_depth() const noexcept; + + /** + * Ensure this parser has enough memory to process JSON documents up to `capacity` bytes in length + * and `max_depth` depth. + * + * The max_depth parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. Defaults to DEFAULT_MAX_DEPTH. + * @return The error, if there is one. + */ + simdjson_warn_unused error_code allocate(size_t capacity, size_t max_depth = DEFAULT_MAX_DEPTH) noexcept; + +#ifdef SIMDJSON_THREADS_ENABLED + /** + * The parser instance can use threads when they are available to speed up some + * operations. It is enabled by default. Changing this attribute will change the + * behavior of the parser for future operations. + */ + bool threaded{ true }; +#endif + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result must be valid UTF-8. + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @param allow_replacement Whether we allow a replacement if the input string contains unmatched surrogate pairs. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement = false) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result may not be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept; + + private: + /** @private [for benchmarking access] The implementation to use */ + std::unique_ptr implementation{}; + size_t _capacity{ 0 }; + size_t _max_capacity; + size_t _max_depth{ DEFAULT_MAX_DEPTH }; + std::unique_ptr string_buf{}; +#if SIMDJSON_DEVELOPMENT_CHECKS + std::unique_ptr start_positions{}; +#endif + + friend class json_iterator; + friend class document_stream; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::parser&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_H +/* end file simdjson/generic/ondemand/parser.h for haswell */ + +// All other declarations +/* including simdjson/generic/ondemand/array.h for haswell: #include "simdjson/generic/ondemand/array.h" */ +/* begin file simdjson/generic/ondemand/array.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * A forward-only JSON array. + */ + class array { + public: + /** + * Create a new invalid array. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline array() noexcept = default; + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an array is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the beginning of the array and checks whether the + * array is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result is_empty() & noexcept; + /** + * Reset the iterator so that we are pointing back at the + * beginning of the array. You should still consume values only once even if you + * can iterate through the array more than once. If you unescape a string + * within the array more than once, you have unsafe code. Note that rewinding + * an array means that you may need to reparse it anew: it is not a free + * operation. + * + * @returns true if the array contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"([ { "foo": { "a": [ 10, 20, 30 ] }} ])"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/0/foo/a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an array + * instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the array and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Get the value at the given index. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + protected: + /** + * Go to the end of the array, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + + /** + * Begin array iteration. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + */ + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + /** + * Begin array iteration from the root. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + * @error TAPE_ERROR if there is no closing ] at the end of the document. + */ + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + /** + * Begin array iteration. + * + * This version of the method should be called after the initial [ has been verified, and is + * intended for use by switch statements that check the type of a value. + * + * @param iter The iterator. Must be after the initial [. Will be *moved* into the resulting array. + */ + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + + /** + * Create an array at the given Internal array creation. Call array::start() or array::started() instead of this. + * + * @param iter The iterator. Must either be at the start of the first element with iter.is_alive() + * == true, or past the [] with is_alive() == false if the array is empty. Will be *moved* + * into the resulting array. + */ + simdjson_inline array(const value_iterator& iter) noexcept; + + /** + * Iterator marking current position. + * + * iter.is_alive() == false indicates iteration is complete. + */ + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + friend struct simdjson_result; + friend class array_iterator; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::array&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + inline simdjson_result count_elements() & noexcept; + inline simdjson_result is_empty() & noexcept; + inline simdjson_result reset() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_H +/* end file simdjson/generic/ondemand/array.h for haswell */ +/* including simdjson/generic/ondemand/array_iterator.h for haswell: #include "simdjson/generic/ondemand/array_iterator.h" */ +/* begin file simdjson/generic/ondemand/array_iterator.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * A forward-only JSON array. + * + * This is an input_iterator, meaning: + * - It is forward-only + * - * must be called exactly once per element. + * - ++ must be called exactly once in between each * (*, ++, *, ++, * ...) + */ + class array_iterator { + public: + /** Create a new, invalid array iterator. */ + simdjson_inline array_iterator() noexcept = default; + + // + // Iterator interface + // + + /** + * Get the current element. + * + * Part of the std::iterator interface. + */ + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + /** + * Check if we are at the end of the JSON. + * + * Part of the std::iterator interface. + * + * @return true if there are no more elements in the JSON array. + */ + simdjson_inline bool operator==(const array_iterator&) const noexcept; + /** + * Check if there are more elements in the JSON array. + * + * Part of the std::iterator interface. + * + * @return true if there are more elements in the JSON array. + */ + simdjson_inline bool operator!=(const array_iterator&) const noexcept; + /** + * Move to the next element. + * + * Part of the std::iterator interface. + */ + simdjson_inline array_iterator& operator++() noexcept; + + private: + value_iterator iter{}; + + simdjson_inline array_iterator(const value_iterator& iter) noexcept; + + friend class array; + friend class value; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::array_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H +/* end file simdjson/generic/ondemand/array_iterator.h for haswell */ +/* including simdjson/generic/ondemand/document.h for haswell: #include "simdjson/generic/ondemand/document.h" */ +/* begin file simdjson/generic/ondemand/document.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * A JSON document. It holds a json_iterator instance. + * + * Used by tokens to get text, and string buffer location. + * + * You must keep the document around during iteration. + */ + class document { + public: + /** + * Create a new invalid document. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline document() noexcept = default; + simdjson_inline document(const document& other) noexcept = delete; // pass your documents by reference, not by copy + simdjson_inline document(document&& other) noexcept = default; + simdjson_inline document& operator=(const document& other) noexcept = delete; + simdjson_inline document& operator=(document&& other) noexcept = default; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() & noexcept; + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() & noexcept; + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + /** + * Cast this JSON value (inside string) to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: Calling get_string() twice on the same document is an error. + * + * @param Whether to allow a replacement character for unmatched surrogate pairs. + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + /** + * Cast this JSON value to a string. + * + * The string is not guaranteed to be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * + * Important: Calling get_wobbly_string() twice on the same document is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is set to 1 (which is the case when building in Debug mode + * by default), and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value if a JSON array or object cannot be found. + * @returns SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result get_value() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() & noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + /** @overload template simdjson_result get() & noexcept */ + template simdjson_inline simdjson_result get() && noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool, value + * + * Be mindful that the document instance must remain in scope while you are accessing object, array and value instances. + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) & noexcept; + /** @overload template error_code get(T &out) & noexcept */ + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() & noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() & noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is defined, and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value value if a JSON array or object cannot be found. + * @exception SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline operator value() noexcept(false); +#endif + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) & noexcept; + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to + * a key a single time. Doing object["mykey"].to_string()and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the document is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the document is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the document is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. If this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view may be the padded buffer. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + /** + * Reset the iterator inside the document instance so we are pointing back at the + * beginning of the document, as if it had just been created. It invalidates all + * values, objects and arrays that you have created so far (including unescaped strings). + */ + inline void rewind() noexcept; + /** + * Returns debugging information. + */ + inline std::string to_debug_string() noexcept; + /** + * Some unrecoverable error conditions may render the document instance unusable. + * The is_alive() method returns true when the document is still suitable. + */ + inline bool is_alive() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Returns true if this document has been fully parsed. + * If you have consumed the whole document and at_end() returns + * false, then there may be trailing content. + */ + inline bool at_end() const noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() automatically calls rewind between each call. Thus + * all values, objects and arrays that you have created so far (including unescaped strings) + * are invalidated. After calling at_pointer, you need to consume the result: string values + * should be stored in your own variables, arrays should be decoded and stored in your own array-like + * structures and so forth. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + * - SCALAR_DOCUMENT_AS_VALUE if the json_pointer is empty and the document is not a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the document and returns a string_view instance corresponding to the + * document as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + protected: + /** + * Consumes the document. + */ + simdjson_inline error_code consume() noexcept; + + simdjson_inline document(ondemand::json_iterator&& iter) noexcept; + simdjson_inline const uint8_t* text(uint32_t idx) const noexcept; + + simdjson_inline value_iterator resume_value_iterator() noexcept; + simdjson_inline value_iterator get_root_value_iterator() noexcept; + simdjson_inline simdjson_result start_or_resume_object() noexcept; + static simdjson_inline document start(ondemand::json_iterator&& iter) noexcept; + + // + // Fields + // + json_iterator iter{}; ///< Current position in the document + static constexpr depth_t DOCUMENT_DEPTH = 0; ///< document depth is always 0 + + friend class array_iterator; + friend class value; + friend class ondemand::parser; + friend class object; + friend class array; + friend class field; + friend class token; + friend class document_stream; + friend class document_reference; + }; + + + /** + * A document_reference is a thin wrapper around a document reference instance. + */ + class document_reference { + public: + simdjson_inline document_reference() noexcept; + simdjson_inline document_reference(document& d) noexcept; + simdjson_inline document_reference(const document_reference& other) noexcept = default; + simdjson_inline document_reference& operator=(const document_reference& other) noexcept = default; + simdjson_inline void rewind() noexcept; + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + + simdjson_inline simdjson_result is_null() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + simdjson_inline operator document& () const noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator array() & noexcept(false); + simdjson_inline operator object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + private: + document* doc{ nullptr }; + }; + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::document&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() & noexcept; + template simdjson_inline simdjson_result get() && noexcept; + + template simdjson_inline error_code get(T& out) & noexcept; + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator haswell::ondemand::array() & noexcept(false); + simdjson_inline operator haswell::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator haswell::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator haswell::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool at_end() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + + + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::document_reference value, error_code error) noexcept; + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator haswell::ondemand::array() & noexcept(false); + simdjson_inline operator haswell::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator haswell::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator haswell::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document_reference::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H +/* end file simdjson/generic/ondemand/document.h for haswell */ +/* including simdjson/generic/ondemand/document_stream.h for haswell: #include "simdjson/generic/ondemand/document_stream.h" */ +/* begin file simdjson/generic/ondemand/document_stream.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#ifdef SIMDJSON_THREADS_ENABLED +#include +#include +#include +#endif + +namespace simdjson { + namespace haswell { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + /** @private Custom worker class **/ + struct stage1_worker { + stage1_worker() noexcept = default; + stage1_worker(const stage1_worker&) = delete; + stage1_worker(stage1_worker&&) = delete; + stage1_worker operator=(const stage1_worker&) = delete; + ~stage1_worker(); + /** + * We only start the thread when it is needed, not at object construction, this may throw. + * You should only call this once. + **/ + void start_thread(); + /** + * Start a stage 1 job. You should first call 'run', then 'finish'. + * You must call start_thread once before. + */ + void run(document_stream* ds, parser* stage1, size_t next_batch_start); + /** Wait for the run to finish (blocking). You should first call 'run', then 'finish'. **/ + void finish(); + + private: + + /** + * Normally, we would never stop the thread. But we do in the destructor. + * This function is only safe assuming that you are not waiting for results. You + * should have called run, then finish, and be done. + **/ + void stop_thread(); + + std::thread thread{}; + /** These three variables define the work done by the thread. **/ + ondemand::parser* stage1_thread_parser{}; + size_t _next_batch_start{}; + document_stream* owner{}; + /** + * We have two state variables. This could be streamlined to one variable in the future but + * we use two for clarity. + */ + bool has_work{ false }; + bool can_work{ true }; + + /** + * We lock using a mutex. + */ + std::mutex locking_mutex{}; + std::condition_variable cond_var{}; + + friend class document_stream; + }; +#endif // SIMDJSON_THREADS_ENABLED + + /** + * A forward-only stream of documents. + * + * Produced by parser::iterate_many. + * + */ + class document_stream { + public: + /** + * Construct an uninitialized document_stream. + * + * ```c++ + * document_stream docs; + * auto error = parser.iterate_many(json).get(docs); + * ``` + */ + simdjson_inline document_stream() noexcept; + /** Move one document_stream to another. */ + simdjson_inline document_stream(document_stream&& other) noexcept = default; + /** Move one document_stream to another. */ + simdjson_inline document_stream& operator=(document_stream&& other) noexcept = default; + + simdjson_inline ~document_stream() noexcept; + + /** + * Returns the input size in bytes. + */ + inline size_t size_in_bytes() const noexcept; + + /** + * After iterating through the stream, this method + * returns the number of bytes that were not parsed at the end + * of the stream. If truncated_bytes() differs from zero, + * then the input was truncated maybe because incomplete JSON + * documents were found at the end of the stream. You + * may need to process the bytes in the interval [size_in_bytes()-truncated_bytes(), size_in_bytes()). + * + * You should only call truncated_bytes() after streaming through all + * documents, like so: + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto & doc : stream) { + * // do something with doc + * } + * size_t truncated = stream.truncated_bytes(); + * + */ + inline size_t truncated_bytes() const noexcept; + + class iterator { + public: + using value_type = simdjson_result; + using reference = value_type; + + using difference_type = std::ptrdiff_t; + + using iterator_category = std::input_iterator_tag; + + /** + * Default constructor. + */ + simdjson_inline iterator() noexcept; + /** + * Get the current document (or error). + */ + simdjson_inline simdjson_result operator*() noexcept; + /** + * Advance to the next document (prefix). + */ + inline iterator& operator++() noexcept; + /** + * Check if we're at the end yet. + * @param other the end iterator to compare to. + */ + simdjson_inline bool operator!=(const iterator& other) const noexcept; + /** + * @private + * + * Gives the current index in the input document in bytes. + * + * document_stream stream = parser.parse_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * auto doc = *i; + * size_t index = i.current_index(); + * } + * + * This function (current_index()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + */ + simdjson_inline size_t current_index() const noexcept; + + /** + * @private + * + * Gives a view of the current document at the current position. + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * std::string_view v = i.source(); + * } + * + * The returned string_view instance is simply a map to the (unparsed) + * source string: it may thus include white-space characters and all manner + * of padding. + * + * This function (source()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + * + */ + simdjson_inline std::string_view source() const noexcept; + + /** + * Returns error of the stream (if any). + */ + inline error_code error() const noexcept; + + private: + simdjson_inline iterator(document_stream* s, bool finished) noexcept; + /** The document_stream we're iterating through. */ + document_stream* stream; + /** Whether we're finished or not. */ + bool finished; + + friend class document; + friend class document_stream; + friend class json_iterator; + }; + + /** + * Start iterating the documents in the stream. + */ + simdjson_inline iterator begin() noexcept; + /** + * The end of the stream, for iterator comparison purposes. + */ + simdjson_inline iterator end() noexcept; + + private: + + document_stream& operator=(const document_stream&) = delete; // Disallow copying + document_stream(const document_stream& other) = delete; // Disallow copying + + /** + * Construct a document_stream. Does not allocate or parse anything until the iterator is + * used. + * + * @param parser is a reference to the parser instance used to generate this document_stream + * @param buf is the raw byte buffer we need to process + * @param len is the length of the raw byte buffer in bytes + * @param batch_size is the size of the windows (must be strictly greater or equal to the largest JSON document) + */ + simdjson_inline document_stream( + ondemand::parser& parser, + const uint8_t* buf, + size_t len, + size_t batch_size, + bool allow_comma_separated + ) noexcept; + + /** + * Parse the first document in the buffer. Used by begin(), to handle allocation and + * initialization. + */ + inline void start() noexcept; + + /** + * Parse the next document found in the buffer previously given to document_stream. + * + * The content should be a valid JSON document encoded as UTF-8. If there is a + * UTF-8 BOM, the parser skips it. + * + * You do NOT need to pre-allocate a parser. This function takes care of + * pre-allocating a capacity defined by the batch_size defined when creating the + * document_stream object. + * + * The function returns simdjson::EMPTY if there is no more data to be parsed. + * + * The function returns simdjson::SUCCESS (as integer = 0) in case of success + * and indicates that the buffer has successfully been parsed to the end. + * Every document it contained has been parsed without error. + * + * The function returns an error code from simdjson/simdjson.h in case of failure + * such as simdjson::CAPACITY, simdjson::MEMALLOC, simdjson::DEPTH_ERROR and so forth; + * the simdjson::error_message function converts these error codes into a string). + * + * You can also check validity by calling parser.is_valid(). The same parser can + * and should be reused for the other documents in the buffer. + */ + inline void next() noexcept; + + /** Move the json_iterator of the document to the location of the next document in the stream. */ + inline void next_document() noexcept; + + /** Get the next document index. */ + inline size_t next_batch_start() const noexcept; + + /** Pass the next batch through stage 1 with the given parser. */ + inline error_code run_stage1(ondemand::parser& p, size_t batch_start) noexcept; + + // Fields + ondemand::parser* parser; + const uint8_t* buf; + size_t len; + size_t batch_size; + bool allow_comma_separated; + /** + * We are going to use just one document instance. The document owns + * the json_iterator. It implies that we only ever pass a reference + * to the document to the users. + */ + document doc{}; + /** The error (or lack thereof) from the current document. */ + error_code error; + size_t batch_start{ 0 }; + size_t doc_index{}; + +#ifdef SIMDJSON_THREADS_ENABLED + /** Indicates whether we use threads. Note that this needs to be a constant during the execution of the parsing. */ + bool use_thread; + + inline void load_from_stage1_thread() noexcept; + + /** Start a thread to run stage 1 on the next batch. */ + inline void start_stage1_thread() noexcept; + + /** Wait for the stage 1 thread to finish and capture the results. */ + inline void finish_stage1_thread() noexcept; + + /** The error returned from the stage 1 thread. */ + error_code stage1_thread_error{ UNINITIALIZED }; + /** The thread used to run stage 1 against the next batch in the background. */ + std::unique_ptr worker{ new(std::nothrow) stage1_worker() }; + /** + * The parser used to run stage 1 in the background. Will be swapped + * with the regular parser when finished. + */ + ondemand::parser stage1_thread_parser{}; + + friend struct stage1_worker; +#endif // SIMDJSON_THREADS_ENABLED + + friend class parser; + friend class document; + friend class json_iterator; + friend struct simdjson_result; + friend struct internal::simdjson_result_base; + }; // document_stream + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::document_stream&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H +/* end file simdjson/generic/ondemand/document_stream.h for haswell */ +/* including simdjson/generic/ondemand/field.h for haswell: #include "simdjson/generic/ondemand/field.h" */ +/* begin file simdjson/generic/ondemand/field.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * A JSON field (key/value pair) in an object. + * + * Returned from object iteration. + * + * Extends from std::pair so you can use C++ algorithms that rely on pairs. + */ + class field : public std::pair { + public: + /** + * Create a new invalid field. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline field() noexcept; + + /** + * Get the key as a string_view (for higher speed, consider raw_key). + * We deliberately use a more cumbersome name (unescaped_key) to force users + * to think twice about using it. + * + * This consumes the key: once you have called unescaped_key(), you cannot + * call it again nor can you call key(). + */ + simdjson_inline simdjson_warn_unused simdjson_result unescaped_key(bool allow_replacement) noexcept; + /** + * Get the key as a raw_json_string. Can be used for direct comparison with + * an unescaped C string: e.g., key() == "test". + */ + simdjson_inline raw_json_string key() const noexcept; + /** + * Get the field value. + */ + simdjson_inline ondemand::value& value() & noexcept; + /** + * @overload ondemand::value &ondemand::value() & noexcept + */ + simdjson_inline ondemand::value value() && noexcept; + + protected: + simdjson_inline field(raw_json_string key, ondemand::value&& value) noexcept; + static simdjson_inline simdjson_result start(value_iterator& parent_iter) noexcept; + static simdjson_inline simdjson_result start(const value_iterator& parent_iter, raw_json_string key) noexcept; + friend struct simdjson_result; + friend class object_iterator; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::field&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result unescaped_key(bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result key() noexcept; + simdjson_inline simdjson_result value() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_H +/* end file simdjson/generic/ondemand/field.h for haswell */ +/* including simdjson/generic/ondemand/object.h for haswell: #include "simdjson/generic/ondemand/object.h" */ +/* begin file simdjson/generic/ondemand/object.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * A forward-only JSON object field iterator. + */ + class object { + public: + /** + * Create a new invalid object. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a + * key a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an object + * instance: there is no rewind and no invalidation. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + /** + * Reset the iterator so that we are pointing back at the + * beginning of the object. You should still consume values only once even if you + * can iterate through the object more than once. If you unescape a string within + * the object more than once, you have unsafe code. Note that rewinding an object + * means that you may need to reparse it anew: it is not a free operation. + * + * @returns true if the object contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * This method scans the beginning of the object and checks whether the + * object is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + inline simdjson_result is_empty() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Consumes the object and returns a string_view instance corresponding to the + * object as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + protected: + /** + * Go to the end of the object, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + static simdjson_inline object resume(const value_iterator& iter) noexcept; + simdjson_inline object(const value_iterator& iter) noexcept; + + simdjson_warn_unused simdjson_inline error_code find_field_raw(const std::string_view key) noexcept; + + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::object&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + inline simdjson_result reset() noexcept; + inline simdjson_result is_empty() noexcept; + inline simdjson_result count_fields() & noexcept; + inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_H +/* end file simdjson/generic/ondemand/object.h for haswell */ +/* including simdjson/generic/ondemand/object_iterator.h for haswell: #include "simdjson/generic/ondemand/object_iterator.h" */ +/* begin file simdjson/generic/ondemand/object_iterator.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + class object_iterator { + public: + /** + * Create a new invalid object_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object_iterator() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline simdjson_result operator*() noexcept; + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const object_iterator&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const object_iterator&) const noexcept; + // Checks for ']' and ',' + simdjson_inline object_iterator& operator++() noexcept; + + private: + /** + * The underlying JSON iterator. + * + * PERF NOTE: expected to be elided in favor of the parent document: this is set when the object + * is first used, and never changes afterwards. + */ + value_iterator iter{}; + + simdjson_inline object_iterator(const value_iterator& iter) noexcept; + friend struct simdjson_result; + friend class object; + }; + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public haswell::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(haswell::ondemand::object_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + // Checks for ']' and ',' + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H +/* end file simdjson/generic/ondemand/object_iterator.h for haswell */ +/* including simdjson/generic/ondemand/serialization.h for haswell: #include "simdjson/generic/ondemand/serialization.h" */ +/* begin file simdjson/generic/ondemand/serialization.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + namespace simdjson { /** - * Represents the best statically linked simdjson implementation that can be used by the compiling - * program. - * - * Detects what options the program is compiled against, and picks the minimum implementation that - * will work on any computer that can run the program. For example, if you compile with g++ - * -march=westmere, it will pick the westmere implementation. The haswell implementation will - * still be available, and can be selected at runtime, but the builtin implementation (and any - * code that uses it) will use westmere. + * Create a string-view instance out of a document instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. */ - namespace builtin = SIMDJSON_BUILTIN_IMPLEMENTATION; + inline simdjson_result to_json_string(haswell::ondemand::document& x) noexcept; + /** + * Create a string-view instance out of a value instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. The value must + * not have been accessed previously. It does not + * validate the content. + */ + inline simdjson_result to_json_string(haswell::ondemand::value& x) noexcept; + /** + * Create a string-view instance out of an object instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(haswell::ondemand::object& x) noexcept; + /** + * Create a string-view instance out of an array instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(haswell::ondemand::array& x) noexcept; + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); +} // namespace simdjson + +/** + * We want to support argument-dependent lookup (ADL). + * Hence we should define operator<< in the namespace + * where the argument (here value, object, etc.) resides. + * Credit: @madhur4127 + * See https://github.com/simdjson/simdjson/issues/1768 + */ +namespace simdjson { + namespace haswell { + namespace ondemand { + + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The element. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::value x); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::array value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::document& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::document_reference& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The object. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::object value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + } + } +} // namespace simdjson::haswell::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H +/* end file simdjson/generic/ondemand/serialization.h for haswell */ + +// Inline definitions +/* including simdjson/generic/ondemand/array-inl.h for haswell: #include "simdjson/generic/ondemand/array-inl.h" */ +/* begin file simdjson/generic/ondemand/array-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter->depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the array is first found and the iterator is just past the `{`. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the `,` before the next value (or `]`). In this state, + // depth == iter->depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter->depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter->depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the array iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet element may be missing or not be an + // array--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter->depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between elements, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter->depth == depth, and at_start == false. + // + // ## Terminal State + // + // The terminal state has iter->depth < depth. at_start is always false. + // + // - Finished: When we have reached a `]` or have reported an error, we are finished. We signal this + // by decrementing depth. In this state, iter->depth < depth, at_start == false, and + // error == SUCCESS. + // + + simdjson_inline array::array(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result array::start(value_iterator& iter) noexcept { + // We don't need to know if the array is empty to start iteration, but we do want to know if there + // is an error--thus `simdjson_unused`. + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::start_root(value_iterator& iter) noexcept { + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_root_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::started(value_iterator& iter) noexcept { + bool has_value; + SIMDJSON_TRY(iter.started_array().get(has_value)); + return array(iter); + } + + simdjson_inline simdjson_result array::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return array_iterator(iter); + } + simdjson_inline simdjson_result array::end() noexcept { + return array_iterator(iter); + } + simdjson_inline error_code array::consume() noexcept { + auto error = iter.json_iter().skip_child(iter.depth() - 1); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result array::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter._json_iter->unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline simdjson_result array::count_elements() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the array after counting the number of elements. + iter.reset_array(); + return count; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline simdjson_result array::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_array().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + inline simdjson_result array::reset() & noexcept { + return iter.reset_array(); + } + + inline simdjson_result array::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + // - means "the append position" or "the element after the end of the array" + // We don't support this, because we're returning a real element, not a position. + if (json_pointer == "-") { return INDEX_OUT_OF_BOUNDS; } + + // Read the array index + size_t array_index = 0; + size_t i; + for (i = 0; i < json_pointer.length() && json_pointer[i] != '/'; i++) { + uint8_t digit = uint8_t(json_pointer[i] - '0'); + // Check for non-digit in array index. If it's there, we're trying to get a field in an object + if (digit > 9) { return INCORRECT_TYPE; } + array_index = array_index * 10 + digit; + } + + // 0 followed by other digits is invalid + if (i > 1 && json_pointer[0] == '0') { return INVALID_JSON_POINTER; } // "JSON pointer array index has other characters after 0" + + // Empty string is invalid; so is a "/" with no digits before it + if (i == 0) { return INVALID_JSON_POINTER; } // "Empty string in JSON pointer array index" + // Get the child + auto child = at(array_index); + // If there is an error, it ends here + if (child.error()) { + return child; + } + + // If there is a /, we're not done yet, call recursively. + if (i < json_pointer.length()) { + child = child.at_pointer(json_pointer.substr(i)); + } + return child; + } + + simdjson_inline simdjson_result array::at(size_t index) noexcept { + size_t i = 0; + for (auto value : *this) { + if (i == index) { return value; } + i++; + } + return INDEX_OUT_OF_BOUNDS; + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + haswell::ondemand::array&& value + ) noexcept + : implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept + : implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::is_empty() & noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H +/* end file simdjson/generic/ondemand/array-inl.h for haswell */ +/* including simdjson/generic/ondemand/array_iterator-inl.h for haswell: #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/array_iterator-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline array_iterator::array_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result array_iterator::operator*() noexcept { + if (iter.error()) { iter.abandon(); return iter.error(); } + return value(iter.child()); + } + simdjson_inline bool array_iterator::operator==(const array_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool array_iterator::operator!=(const array_iterator&) const noexcept { + return iter.is_open(); + } + simdjson_inline array_iterator& array_iterator::operator++() noexcept { + error_code error; + // PERF NOTE this is a safety rail ... users should exit loops as soon as they receive an error, so we'll never get here. + // However, it does not seem to make a perf difference, so we add it out of an abundance of caution. + if ((error = iter.error())) { return *this; } + if ((error = iter.skip_child())) { return *this; } + if ((error = iter.has_next_element().error())) { return *this; } + return *this; + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + haswell::ondemand::array_iterator&& value + ) noexcept + : haswell::implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : haswell::implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++(first); + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/array_iterator-inl.h for haswell */ +/* including simdjson/generic/ondemand/document-inl.h for haswell: #include "simdjson/generic/ondemand/document-inl.h" */ +/* begin file simdjson/generic/ondemand/document-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline document::document(ondemand::json_iterator&& _iter) noexcept + : iter{ std::forward(_iter) } + { + logger::log_start_value(iter, "document"); + } + + simdjson_inline document document::start(json_iterator&& iter) noexcept { + return document(std::forward(iter)); + } + + inline void document::rewind() noexcept { + iter.rewind(); + } + + inline std::string document::to_debug_string() noexcept { + return iter.to_string(); + } + + inline simdjson_result document::current_location() const noexcept { + return iter.current_location(); + } + + inline int32_t document::current_depth() const noexcept { + return iter.depth(); + } + + inline bool document::at_end() const noexcept { + return iter.at_end(); + } + + + inline bool document::is_alive() noexcept { + return iter.is_alive(); + } + simdjson_inline value_iterator document::resume_value_iterator() noexcept { + return value_iterator(&iter, 1, iter.root_position()); + } + simdjson_inline value_iterator document::get_root_value_iterator() noexcept { + return resume_value_iterator(); + } + simdjson_inline simdjson_result document::start_or_resume_object() noexcept { + if (iter.at_root()) { + return get_object(); + } + else { + return object::resume(resume_value_iterator()); + } + } + simdjson_inline simdjson_result document::get_value() noexcept { + // Make sure we start any arrays or objects before returning, so that start_root_() + // gets called. + + // It is the convention throughout the code that the macro `SIMDJSON_DEVELOPMENT_CHECKS` determines whether + // we check for OUT_OF_ORDER_ITERATION. Proper on::demand code should never trigger this error. +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.at_root()) { return OUT_OF_ORDER_ITERATION; } +#endif + // assert_at_root() serves two purposes: in Debug mode, whether or not + // SIMDJSON_DEVELOPMENT_CHECKS is set or not, it checks that we are at the root of + // the document (this will typically be redundant). In release mode, it generates + // SIMDJSON_ASSUME statements to allow the compiler to make assumptions. + iter.assert_at_root(); + switch (*iter.peek()) { + case '[': { + // The following lines check that the document ends with ]. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_array(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + case '{': { + // The following lines would check that the document ends with }. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_object(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + default: + // Unfortunately, scalar documents are a special case in simdjson and they cannot + // be safely converted to value instances. + return SCALAR_DOCUMENT_AS_VALUE; + } + } + simdjson_inline simdjson_result document::get_array() & noexcept { + auto value = get_root_value_iterator(); + return array::start_root(value); + } + simdjson_inline simdjson_result document::get_object() & noexcept { + auto value = get_root_value_iterator(); + return object::start_root(value); + } + + /** + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. We want to disallow trailing + * content. + * Thus, in several implementations below, we pass a 'true' parameter value to + * a get_root_value_iterator() method: this indicates that we disallow trailing content. + */ + + simdjson_inline simdjson_result document::get_uint64() noexcept { + return get_root_value_iterator().get_root_uint64(true); + } + simdjson_inline simdjson_result document::get_uint64_in_string() noexcept { + return get_root_value_iterator().get_root_uint64_in_string(true); + } + simdjson_inline simdjson_result document::get_int64() noexcept { + return get_root_value_iterator().get_root_int64(true); + } + simdjson_inline simdjson_result document::get_int64_in_string() noexcept { + return get_root_value_iterator().get_root_int64_in_string(true); + } + simdjson_inline simdjson_result document::get_double() noexcept { + return get_root_value_iterator().get_root_double(true); + } + simdjson_inline simdjson_result document::get_double_in_string() noexcept { + return get_root_value_iterator().get_root_double_in_string(true); + } + simdjson_inline simdjson_result document::get_string(bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(true, allow_replacement); + } + template + simdjson_inline error_code document::get_string(string_type& receiver, bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(receiver, true, allow_replacement); + } + simdjson_inline simdjson_result document::get_wobbly_string() noexcept { + return get_root_value_iterator().get_root_wobbly_string(true); + } + simdjson_inline simdjson_result document::get_raw_json_string() noexcept { + return get_root_value_iterator().get_root_raw_json_string(true); + } + simdjson_inline simdjson_result document::get_bool() noexcept { + return get_root_value_iterator().get_root_bool(true); + } + simdjson_inline simdjson_result document::is_null() noexcept { + return get_root_value_iterator().is_root_null(true); + } + + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_array(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_object(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_double(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_bool(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_value(); } + + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_double(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_uint64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_int64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_bool(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_value(); } + + template simdjson_inline error_code document::get(T& out) & noexcept { + return get().get(out); + } + template simdjson_inline error_code document::get(T& out) && noexcept { + return std::forward(*this).get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document::operator array() & noexcept(false) { return get_array(); } + simdjson_inline document::operator object() & noexcept(false) { return get_object(); } + simdjson_inline document::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document::operator double() noexcept(false) { return get_double(); } + simdjson_inline document::operator std::string_view() noexcept(false) { return get_string(false); } + simdjson_inline document::operator raw_json_string() noexcept(false) { return get_raw_json_string(); } + simdjson_inline document::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document::operator value() noexcept(false) { return get_value(); } + +#endif + simdjson_inline simdjson_result document::count_elements() & noexcept { + auto a = get_array(); + simdjson_result answer = a.count_elements(); + /* If there was an array, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::count_fields() & noexcept { + auto a = get_object(); + simdjson_result answer = a.count_fields(); + /* If there was an object, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::at(size_t index) & noexcept { + auto a = get_array(); + return a.at(index); + } + simdjson_inline simdjson_result document::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result document::end() & noexcept { + return {}; + } + + simdjson_inline simdjson_result document::find_field(std::string_view key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field(const char* key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field_unordered(std::string_view key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::find_field_unordered(const char* key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::operator[](std::string_view key) & noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result document::operator[](const char* key) & noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline error_code document::consume() noexcept { + auto error = iter.skip_child(0); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result document::raw_json() noexcept { + auto _iter = get_root_value_iterator(); + const uint8_t* starting_point{ _iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter.unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result document::type() noexcept { + return get_root_value_iterator().type(); + } + + simdjson_inline simdjson_result document::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool document::is_negative() noexcept { + return get_root_value_iterator().is_root_negative(); + } + + simdjson_inline simdjson_result document::is_integer() noexcept { + return get_root_value_iterator().is_root_integer(true); + } + + simdjson_inline simdjson_result document::get_number_type() noexcept { + return get_root_value_iterator().get_root_number_type(true); + } + + simdjson_inline simdjson_result document::get_number() noexcept { + return get_root_value_iterator().get_root_number(true); + } + + + simdjson_inline simdjson_result document::raw_json_token() noexcept { + auto _iter = get_root_value_iterator(); + return std::string_view(reinterpret_cast(_iter.peek_start()), _iter.peek_start_length()); + } + + simdjson_inline simdjson_result document::at_pointer(std::string_view json_pointer) noexcept { + rewind(); // Rewind the document each time at_pointer is called + if (json_pointer.empty()) { + return this->get_value(); + } + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + haswell::ondemand::document&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base( + error + ) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template + simdjson_inline simdjson_result simdjson_result::get() & noexcept { + if (error()) { return error(); } + return first.get(); + } + template + simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first).get(); + } + template + simdjson_inline error_code simdjson_result::get(T& out) & noexcept { + if (error()) { return error(); } + return first.get(out); + } + template + simdjson_inline error_code simdjson_result::get(T& out) && noexcept { + if (error()) { return error(); } + return std::forward(first).get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() & noexcept = delete; + template<> simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first); + } + template<> simdjson_inline error_code simdjson_result::get(haswell::ondemand::document& out) & noexcept = delete; + template<> simdjson_inline error_code simdjson_result::get(haswell::ondemand::document& out) && noexcept { + if (error()) { return error(); } + out = std::forward(first); + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + + + simdjson_inline bool simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } + + +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator haswell::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline bool simdjson_result::at_end() const noexcept { + if (error()) { return error(); } + return first.at_end(); + } + + + simdjson_inline int32_t simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline document_reference::document_reference() noexcept : doc{ nullptr } {} + simdjson_inline document_reference::document_reference(document& d) noexcept : doc(&d) {} + simdjson_inline void document_reference::rewind() noexcept { doc->rewind(); } + simdjson_inline simdjson_result document_reference::get_array() & noexcept { return doc->get_array(); } + simdjson_inline simdjson_result document_reference::get_object() & noexcept { return doc->get_object(); } + /** + * The document_reference instances are used primarily/solely for streams of JSON + * documents. + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. + * + * However, for streams of JSON documents, we want to be able to start from + * "321" "321" "321" + * and parse it successfully as a stream of JSON documents, calling get_uint64_in_string() + * successfully each time. + * + * To achieve this result, we pass a 'false' to a get_root_value_iterator() method: + * this indicates that we allow trailing content. + */ + simdjson_inline simdjson_result document_reference::get_uint64() noexcept { return doc->get_root_value_iterator().get_root_uint64(false); } + simdjson_inline simdjson_result document_reference::get_uint64_in_string() noexcept { return doc->get_root_value_iterator().get_root_uint64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_int64() noexcept { return doc->get_root_value_iterator().get_root_int64(false); } + simdjson_inline simdjson_result document_reference::get_int64_in_string() noexcept { return doc->get_root_value_iterator().get_root_int64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_double() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_double_in_string() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_string(bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(false, allow_replacement); } + template + simdjson_inline error_code document_reference::get_string(string_type& receiver, bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(receiver, false, allow_replacement); } + simdjson_inline simdjson_result document_reference::get_wobbly_string() noexcept { return doc->get_root_value_iterator().get_root_wobbly_string(false); } + simdjson_inline simdjson_result document_reference::get_raw_json_string() noexcept { return doc->get_root_value_iterator().get_root_raw_json_string(false); } + simdjson_inline simdjson_result document_reference::get_bool() noexcept { return doc->get_root_value_iterator().get_root_bool(false); } + simdjson_inline simdjson_result document_reference::get_value() noexcept { return doc->get_value(); } + simdjson_inline simdjson_result document_reference::is_null() noexcept { return doc->get_root_value_iterator().is_root_null(false); } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document_reference::operator array() & noexcept(false) { return array(*doc); } + simdjson_inline document_reference::operator object() & noexcept(false) { return object(*doc); } + simdjson_inline document_reference::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document_reference::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document_reference::operator double() noexcept(false) { return get_double(); } + simdjson_inline document_reference::operator std::string_view() noexcept(false) { return std::string_view(*doc); } + simdjson_inline document_reference::operator raw_json_string() noexcept(false) { return raw_json_string(*doc); } + simdjson_inline document_reference::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document_reference::operator value() noexcept(false) { return value(*doc); } +#endif + simdjson_inline simdjson_result document_reference::count_elements() & noexcept { return doc->count_elements(); } + simdjson_inline simdjson_result document_reference::count_fields() & noexcept { return doc->count_fields(); } + simdjson_inline simdjson_result document_reference::at(size_t index) & noexcept { return doc->at(index); } + simdjson_inline simdjson_result document_reference::begin() & noexcept { return doc->begin(); } + simdjson_inline simdjson_result document_reference::end() & noexcept { return doc->end(); } + simdjson_inline simdjson_result document_reference::find_field(std::string_view key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::find_field(const char* key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::operator[](std::string_view key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::operator[](const char* key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::find_field_unordered(std::string_view key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::find_field_unordered(const char* key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::type() noexcept { return doc->type(); } + simdjson_inline simdjson_result document_reference::is_scalar() noexcept { return doc->is_scalar(); } + simdjson_inline simdjson_result document_reference::current_location() noexcept { return doc->current_location(); } + simdjson_inline int32_t document_reference::current_depth() const noexcept { return doc->current_depth(); } + simdjson_inline bool document_reference::is_negative() noexcept { return doc->is_negative(); } + simdjson_inline simdjson_result document_reference::is_integer() noexcept { return doc->get_root_value_iterator().is_root_integer(false); } + simdjson_inline simdjson_result document_reference::get_number_type() noexcept { return doc->get_root_value_iterator().get_root_number_type(false); } + simdjson_inline simdjson_result document_reference::get_number() noexcept { return doc->get_root_value_iterator().get_root_number(false); } + simdjson_inline simdjson_result document_reference::raw_json_token() noexcept { return doc->raw_json_token(); } + simdjson_inline simdjson_result document_reference::at_pointer(std::string_view json_pointer) noexcept { return doc->at_pointer(json_pointer); } + simdjson_inline simdjson_result document_reference::raw_json() noexcept { return doc->raw_json(); } + simdjson_inline document_reference::operator document& () const noexcept { return *doc; } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + + + +namespace simdjson { + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::document_reference value, error_code error) + noexcept : implementation_simdjson_result_base(std::forward(value), error) {} + + + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator haswell::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H +/* end file simdjson/generic/ondemand/document-inl.h for haswell */ +/* including simdjson/generic/ondemand/document_stream-inl.h for haswell: #include "simdjson/generic/ondemand/document_stream-inl.h" */ +/* begin file simdjson/generic/ondemand/document_stream-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace haswell { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void stage1_worker::finish() { + // After calling "run" someone would call finish() to wait + // for the end of the processing. + // This function will wait until either the thread has done + // the processing or, else, the destructor has been called. + std::unique_lock lock(locking_mutex); + cond_var.wait(lock, [this] {return has_work == false; }); + } + + inline stage1_worker::~stage1_worker() { + // The thread may never outlive the stage1_worker instance + // and will always be stopped/joined before the stage1_worker + // instance is gone. + stop_thread(); + } + + inline void stage1_worker::start_thread() { + std::unique_lock lock(locking_mutex); + if (thread.joinable()) { + return; // This should never happen but we never want to create more than one thread. + } + thread = std::thread([this] { + while (true) { + std::unique_lock thread_lock(locking_mutex); + // We wait for either "run" or "stop_thread" to be called. + cond_var.wait(thread_lock, [this] {return has_work || !can_work; }); + // If, for some reason, the stop_thread() method was called (i.e., the + // destructor of stage1_worker is called, then we want to immediately destroy + // the thread (and not do any more processing). + if (!can_work) { + break; + } + this->owner->stage1_thread_error = this->owner->run_stage1(*this->stage1_thread_parser, + this->_next_batch_start); + this->has_work = false; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify "finish" + thread_lock.unlock(); + } + } + ); + } + + + inline void stage1_worker::stop_thread() { + std::unique_lock lock(locking_mutex); + // We have to make sure that all locks can be released. + can_work = false; + has_work = false; + cond_var.notify_all(); + lock.unlock(); + if (thread.joinable()) { + thread.join(); + } + } + + inline void stage1_worker::run(document_stream* ds, parser* stage1, size_t next_batch_start) { + std::unique_lock lock(locking_mutex); + owner = ds; + _next_batch_start = next_batch_start; + stage1_thread_parser = stage1; + has_work = true; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify the thread lock that we have work + lock.unlock(); + } + +#endif // SIMDJSON_THREADS_ENABLED + + simdjson_inline document_stream::document_stream( + ondemand::parser& _parser, + const uint8_t* _buf, + size_t _len, + size_t _batch_size, + bool _allow_comma_separated + ) noexcept + : parser{ &_parser }, + buf{ _buf }, + len{ _len }, + batch_size{ _batch_size <= MINIMAL_BATCH_SIZE ? MINIMAL_BATCH_SIZE : _batch_size }, + allow_comma_separated{ _allow_comma_separated }, + error{ SUCCESS } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(_parser.threaded) // we need to make a copy because _parser.threaded can change +#endif + { +#ifdef SIMDJSON_THREADS_ENABLED + if (worker.get() == nullptr) { + error = MEMALLOC; + } +#endif + } + + simdjson_inline document_stream::document_stream() noexcept + : parser{ nullptr }, + buf{ nullptr }, + len{ 0 }, + batch_size{ 0 }, + allow_comma_separated{ false }, + error{ UNINITIALIZED } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(false) +#endif + { + } + + simdjson_inline document_stream::~document_stream() noexcept + { +#ifdef SIMDJSON_THREADS_ENABLED + worker.reset(); +#endif + } + + inline size_t document_stream::size_in_bytes() const noexcept { + return len; + } + + inline size_t document_stream::truncated_bytes() const noexcept { + if (error == CAPACITY) { return len - batch_start; } + return parser->implementation->structural_indexes[parser->implementation->n_structural_indexes] - parser->implementation->structural_indexes[parser->implementation->n_structural_indexes + 1]; + } + + simdjson_inline document_stream::iterator::iterator() noexcept + : stream{ nullptr }, finished{ true } { + } + + simdjson_inline document_stream::iterator::iterator(document_stream* _stream, bool is_end) noexcept + : stream{ _stream }, finished{ is_end } { + } + + simdjson_inline simdjson_result document_stream::iterator::operator*() noexcept { + //if(stream->error) { return stream->error; } + return simdjson_result(stream->doc, stream->error); + } + + simdjson_inline document_stream::iterator& document_stream::iterator::operator++() noexcept { + // If there is an error, then we want the iterator + // to be finished, no matter what. (E.g., we do not + // keep generating documents with errors, or go beyond + // a document with errors.) + // + // Users do not have to call "operator*()" when they use operator++, + // so we need to end the stream in the operator++ function. + // + // Note that setting finished = true is essential otherwise + // we would enter an infinite loop. + if (stream->error) { finished = true; } + // Note that stream->error() is guarded against error conditions + // (it will immediately return if stream->error casts to false). + // In effect, this next function does nothing when (stream->error) + // is true (hence the risk of an infinite loop). + stream->next(); + // If that was the last document, we're finished. + // It is the only type of error we do not want to appear + // in operator*. + if (stream->error == EMPTY) { finished = true; } + // If we had any other kind of error (not EMPTY) then we want + // to pass it along to the operator* and we cannot mark the result + // as "finished" just yet. + return *this; + } + + simdjson_inline bool document_stream::iterator::operator!=(const document_stream::iterator& other) const noexcept { + return finished != other.finished; + } + + simdjson_inline document_stream::iterator document_stream::begin() noexcept { + start(); + // If there are no documents, we're finished. + return iterator(this, error == EMPTY); + } + + simdjson_inline document_stream::iterator document_stream::end() noexcept { + return iterator(this, true); + } + + inline void document_stream::start() noexcept { + if (error) { return; } + error = parser->allocate(batch_size); + if (error) { return; } + // Always run the first stage 1 parse immediately + batch_start = 0; + error = run_stage1(*parser, batch_start); + while (error == EMPTY) { + // In exceptional cases, we may start with an empty block + batch_start = next_batch_start(); + if (batch_start >= len) { return; } + error = run_stage1(*parser, batch_start); + } + if (error) { return; } + doc_index = batch_start; + doc = document(json_iterator(&buf[batch_start], parser)); + doc.iter._streaming = true; + +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread && next_batch_start() < len) { + // Kick off the first thread on next batch if needed + error = stage1_thread_parser.allocate(batch_size); + if (error) { return; } + worker->start_thread(); + start_stage1_thread(); + if (error) { return; } + } +#endif // SIMDJSON_THREADS_ENABLED + } + + inline void document_stream::next() noexcept { + // We always enter at once once in an error condition. + if (error) { return; } + next_document(); + if (error) { return; } + auto cur_struct_index = doc.iter._root - parser->implementation->structural_indexes.get(); + doc_index = batch_start + parser->implementation->structural_indexes[cur_struct_index]; + + // Check if at end of structural indexes (i.e. at end of batch) + if (cur_struct_index >= static_cast(parser->implementation->n_structural_indexes)) { + error = EMPTY; + // Load another batch (if available) + while (error == EMPTY) { + batch_start = next_batch_start(); + if (batch_start >= len) { break; } +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread) { + load_from_stage1_thread(); + } + else { + error = run_stage1(*parser, batch_start); + } +#else + error = run_stage1(*parser, batch_start); +#endif + /** + * Whenever we move to another window, we need to update all pointers to make + * it appear as if the input buffer started at the beginning of the window. + * + * Take this input: + * + * {"z":5} {"1":1,"2":2,"4":4} [7, 10, 9] [15, 11, 12, 13] [154, 110, 112, 1311] + * + * Say you process the following window... + * + * '{"z":5} {"1":1,"2":2,"4":4} [7, 10, 9]' + * + * When you do so, the json_iterator has a pointer at the beginning of the memory region + * (pointing at the beginning of '{"z"...'. + * + * When you move to the window that starts at... + * + * '[7, 10, 9] [15, 11, 12, 13] ... + * + * then it is not sufficient to just run stage 1. You also need to re-anchor the + * json_iterator so that it believes we are starting at '[7, 10, 9]...'. + * + * Under the DOM front-end, this gets done automatically because the parser owns + * the pointer the data, and when you call stage1 and then stage2 on the same + * parser, then stage2 will run on the pointer acquired by stage1. + * + * That is, stage1 calls "this->buf = _buf" so the parser remembers the buffer that + * we used. But json_iterator has no callback when stage1 is called on the parser. + * In fact, I think that the parser is unaware of json_iterator. + * + * + * So we need to re-anchor the json_iterator after each call to stage 1 so that + * all of the pointers are in sync. + */ + doc.iter = json_iterator(&buf[batch_start], parser); + doc.iter._streaming = true; + /** + * End of resync. + */ + + if (error) { continue; } // If the error was EMPTY, we may want to load another batch. + doc_index = batch_start; + } + } + } + + inline void document_stream::next_document() noexcept { + // Go to next place where depth=0 (document depth) + error = doc.iter.skip_child(0); + if (error) { return; } + // Always set depth=1 at the start of document + doc.iter._depth = 1; + // consume comma if comma separated is allowed + if (allow_comma_separated) { doc.iter.consume_character(','); } + // Resets the string buffer at the beginning, thus invalidating the strings. + doc.iter._string_buf_loc = parser->string_buf.get(); + doc.iter._root = doc.iter.position(); + } + + inline size_t document_stream::next_batch_start() const noexcept { + return batch_start + parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]; + } + + inline error_code document_stream::run_stage1(ondemand::parser& p, size_t _batch_start) noexcept { + // This code only updates the structural index in the parser, it does not update any json_iterator + // instance. + size_t remaining = len - _batch_start; + if (remaining <= batch_size) { + return p.implementation->stage1(&buf[_batch_start], remaining, stage1_mode::streaming_final); + } + else { + return p.implementation->stage1(&buf[_batch_start], batch_size, stage1_mode::streaming_partial); + } + } + + simdjson_inline size_t document_stream::iterator::current_index() const noexcept { + return stream->doc_index; + } + + simdjson_inline std::string_view document_stream::iterator::source() const noexcept { + auto depth = stream->doc.iter.depth(); + auto cur_struct_index = stream->doc.iter._root - stream->parser->implementation->structural_indexes.get(); + + // If at root, process the first token to determine if scalar value + if (stream->doc.iter.at_root()) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': // Depth=1 already at start of document + break; + case '}': case ']': + depth--; + break; + default: // Scalar value document + // TODO: Remove any trailing whitespaces + // This returns a string spanning from start of value to the beginning of the next document (excluded) + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[++cur_struct_index] - current_index() - 1); + } + cur_struct_index++; + } + + while (cur_struct_index <= static_cast(stream->parser->implementation->n_structural_indexes)) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': + depth++; + break; + case '}': case ']': + depth--; + break; + } + if (depth == 0) { break; } + cur_struct_index++; + } + + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[cur_struct_index] - current_index() + stream->batch_start + 1);; + } + + inline error_code document_stream::iterator::error() const noexcept { + return stream->error; + } + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void document_stream::load_from_stage1_thread() noexcept { + worker->finish(); + // Swap to the parser that was loaded up in the thread. Make sure the parser has + // enough memory to swap to, as well. + std::swap(stage1_thread_parser, *parser); + error = stage1_thread_error; + if (error) { return; } + + // If there's anything left, start the stage 1 thread! + if (next_batch_start() < len) { + start_stage1_thread(); + } + } + + inline void document_stream::start_stage1_thread() noexcept { + // we call the thread on a lambda that will update + // this->stage1_thread_error + // there is only one thread that may write to this value + // TODO this is NOT exception-safe. + this->stage1_thread_error = UNINITIALIZED; // In case something goes wrong, make sure it's an error + size_t _next_batch_start = this->next_batch_start(); + + worker->run(this, &this->stage1_thread_parser, _next_batch_start); + } + +#endif // SIMDJSON_THREADS_ENABLED + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result::simdjson_result( + haswell::ondemand::document_stream&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + +} + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H +/* end file simdjson/generic/ondemand/document_stream-inl.h for haswell */ +/* including simdjson/generic/ondemand/field-inl.h for haswell: #include "simdjson/generic/ondemand/field-inl.h" */ +/* begin file simdjson/generic/ondemand/field-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + // clang 6 doesn't think the default constructor can be noexcept, so we make it explicit + simdjson_inline field::field() noexcept : std::pair() {} + + simdjson_inline field::field(raw_json_string key, ondemand::value&& value) noexcept + : std::pair(key, std::forward(value)) + { + } + + simdjson_inline simdjson_result field::start(value_iterator& parent_iter) noexcept { + raw_json_string key; + SIMDJSON_TRY(parent_iter.field_key().get(key)); + SIMDJSON_TRY(parent_iter.field_value()); + return field::start(parent_iter, key); + } + + simdjson_inline simdjson_result field::start(const value_iterator& parent_iter, raw_json_string key) noexcept { + return field(key, parent_iter.child()); + } + + simdjson_inline simdjson_warn_unused simdjson_result field::unescaped_key(bool allow_replacement) noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() but Visual Studio won't let us. + simdjson_result answer = first.unescape(second.iter.json_iter(), allow_replacement); + first.consume(); + return answer; + } + + simdjson_inline raw_json_string field::key() const noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() by Visual Studio won't let us. + return first; + } + + simdjson_inline value& field::value() & noexcept { + return second; + } + + simdjson_inline value field::value() && noexcept { + return std::forward(*this).second; + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + haswell::ondemand::field&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::key() noexcept { + if (error()) { return error(); } + return first.key(); + } + simdjson_inline simdjson_result simdjson_result::unescaped_key(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.unescaped_key(allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::value() noexcept { + if (error()) { return error(); } + return std::move(first.value()); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H +/* end file simdjson/generic/ondemand/field-inl.h for haswell */ +/* including simdjson/generic/ondemand/json_iterator-inl.h for haswell: #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/json_iterator-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline json_iterator::json_iterator(json_iterator&& other) noexcept + : token(std::forward(other.token)), + parser{ other.parser }, + _string_buf_loc{ other._string_buf_loc }, + error{ other.error }, + _depth{ other._depth }, + _root{ other._root }, + _streaming{ other._streaming } + { + other.parser = nullptr; + } + simdjson_inline json_iterator& json_iterator::operator=(json_iterator&& other) noexcept { + token = other.token; + parser = other.parser; + _string_buf_loc = other._string_buf_loc; + error = other.error; + _depth = other._depth; + _root = other._root; + _streaming = other._streaming; + other.parser = nullptr; + return *this; + } + + simdjson_inline json_iterator::json_iterator(const uint8_t* buf, ondemand::parser* _parser) noexcept + : token(buf, &_parser->implementation->structural_indexes[0]), + parser{ _parser }, + _string_buf_loc{ parser->string_buf.get() }, + _depth{ 1 }, + _root{ parser->implementation->structural_indexes.get() }, + _streaming{ false } + + { + logger::log_headers(); +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif + } + + inline void json_iterator::rewind() noexcept { + token.set_position(root_position()); + logger::log_headers(); // We start again + _string_buf_loc = parser->string_buf.get(); + _depth = 1; + } + + inline bool json_iterator::balanced() const noexcept { + token_iterator ti(token); + int32_t count{ 0 }; + ti.set_position(root_position()); + while (ti.peek() <= peek_last()) { + switch (*ti.return_current_and_advance()) + { + case '[': case '{': + count++; + break; + case ']': case '}': + count--; + break; + default: + break; + } + } + return count == 0; + } + + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and parent_depth, which is a desired effect. The warning does not show up if the + // skip_child() function is not marked inline). + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline error_code json_iterator::skip_child(depth_t parent_depth) noexcept { + if (depth() <= parent_depth) { return SUCCESS; } + switch (*return_current_and_advance()) { + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + + // For the first open array/object in a value, we've already incremented depth, so keep it the same + // We never stop at colon, but if we did, it wouldn't affect depth + case '[': case '{': case ':': + logger::log_start_value(*this, "skip"); + break; + // If there is a comma, we have just finished a value in an array/object, and need to get back in + case ',': + logger::log_value(*this, "skip"); + break; + // ] or } means we just finished a value and need to jump out of the array/object + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } +#if SIMDJSON_CHECK_EOF + // If there are no more tokens, the parent is incomplete. + if (at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "Missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + break; + case '"': + if (*peek() == ':') { + // We are at a key!!! + // This might happen if you just started an object and you skip it immediately. + // Performance note: it would be nice to get rid of this check as it is somewhat + // expensive. + // https://github.com/simdjson/simdjson/issues/1742 + logger::log_value(*this, "key"); + return_current_and_advance(); // eat up the ':' + break; // important!!! + } + simdjson_fallthrough; + // Anything else must be a scalar value + default: + // For the first scalar, we will have incremented depth already, so we decrement it here. + logger::log_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + } + + // Now that we've considered the first value, we only increment/decrement for arrays/objects + while (position() < end_position()) { + switch (*return_current_and_advance()) { + case '[': case '{': + logger::log_start_value(*this, "skip"); + _depth++; + break; + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + default: + logger::log_value(*this, "skip", ""); + break; + } + } + + return report_error(TAPE_ERROR, "not enough close braces"); + } + + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool json_iterator::at_root() const noexcept { + return position() == root_position(); + } + + simdjson_inline bool json_iterator::is_single_token() const noexcept { + return parser->implementation->n_structural_indexes == 1; + } + + simdjson_inline bool json_iterator::streaming() const noexcept { + return _streaming; + } + + simdjson_inline token_position json_iterator::root_position() const noexcept { + return _root; + } + + simdjson_inline void json_iterator::assert_at_document_depth() const noexcept { + SIMDJSON_ASSUME(_depth == 1); + } + + simdjson_inline void json_iterator::assert_at_root() const noexcept { + SIMDJSON_ASSUME(_depth == 1); +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + // Under Visual Studio, the next SIMDJSON_ASSUME fails with: the argument + // has side effects that will be discarded. + SIMDJSON_ASSUME(token.position() == _root); +#endif + } + + simdjson_inline void json_iterator::assert_more_tokens(uint32_t required_tokens) const noexcept { + assert_valid_position(token._position + required_tokens - 1); + } + + simdjson_inline void json_iterator::assert_valid_position(token_position position) const noexcept { +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(position >= &parser->implementation->structural_indexes[0]); + SIMDJSON_ASSUME(position < &parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]); +#endif + } + + simdjson_inline bool json_iterator::at_end() const noexcept { + return position() == end_position(); + } + simdjson_inline token_position json_iterator::end_position() const noexcept { + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + return &parser->implementation->structural_indexes[n_structural_indexes]; + } + + inline std::string json_iterator::to_string() const noexcept { + if (!is_alive()) { return "dead json_iterator instance"; } + const char* current_structural = reinterpret_cast(token.peek()); + return std::string("json_iterator [ depth : ") + std::to_string(_depth) + + std::string(", structural : '") + std::string(current_structural, 1) + + std::string("', offset : ") + std::to_string(token.current_offset()) + + std::string("', error : ") + error_message(error) + + std::string(" ]"); + } + + inline simdjson_result json_iterator::current_location() const noexcept { + if (!is_alive()) { // Unrecoverable error + if (!at_root()) { + return reinterpret_cast(token.peek(-1)); + } + else { + return reinterpret_cast(token.peek()); + } + } + if (at_end()) { + return OUT_OF_BOUNDS; + } + return reinterpret_cast(token.peek()); + } + + simdjson_inline bool json_iterator::is_alive() const noexcept { + return parser; + } + + simdjson_inline void json_iterator::abandon() noexcept { + parser = nullptr; + _depth = 0; + } + + simdjson_inline const uint8_t* json_iterator::return_current_and_advance() noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif // SIMDJSON_CHECK_EOF + return token.return_current_and_advance(); + } + + simdjson_inline const uint8_t* json_iterator::unsafe_pointer() const noexcept { + // deliberately done without safety guard: + return token.peek(); + } + + simdjson_inline const uint8_t* json_iterator::peek(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // SIMDJSON_CHECK_EOF + return token.peek(delta); + } + + simdjson_inline uint32_t json_iterator::peek_length(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // #if SIMDJSON_CHECK_EOF + return token.peek_length(delta); + } + + simdjson_inline const uint8_t* json_iterator::peek(token_position position) const noexcept { + // todo: currently we require end-of-string buffering, but the following + // assert_valid_position should be turned on if/when we lift that condition. + // assert_valid_position(position); + // This is almost surely related to SIMDJSON_CHECK_EOF but given that SIMDJSON_CHECK_EOF + // is ON by default, we have no choice but to disable it for real with a comment. + return token.peek(position); + } + + simdjson_inline uint32_t json_iterator::peek_length(token_position position) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_valid_position(position); +#endif // SIMDJSON_CHECK_EOF + return token.peek_length(position); + } + + simdjson_inline token_position json_iterator::last_position() const noexcept { + // The following line fails under some compilers... + // SIMDJSON_ASSUME(parser->implementation->n_structural_indexes > 0); + // since it has side-effects. + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + SIMDJSON_ASSUME(n_structural_indexes > 0); + return &parser->implementation->structural_indexes[n_structural_indexes - 1]; + } + simdjson_inline const uint8_t* json_iterator::peek_last() const noexcept { + return token.peek(last_position()); + } + + simdjson_inline void json_iterator::ascend_to(depth_t parent_depth) noexcept { + SIMDJSON_ASSUME(parent_depth >= 0 && parent_depth < INT32_MAX - 1); + SIMDJSON_ASSUME(_depth == parent_depth + 1); + _depth = parent_depth; + } + + simdjson_inline void json_iterator::descend_to(depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); + _depth = child_depth; + } + + simdjson_inline depth_t json_iterator::depth() const noexcept { + return _depth; + } + + simdjson_inline uint8_t*& json_iterator::string_buf_loc() noexcept { + return _string_buf_loc; + } + + simdjson_inline error_code json_iterator::report_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error != SUCCESS && _error != UNINITIALIZED && _error != INCORRECT_TYPE && _error != NO_SUCH_FIELD); + logger::log_error(*this, message); + error = _error; + return error; + } + + simdjson_inline token_position json_iterator::position() const noexcept { + return token.position(); + } + + simdjson_inline simdjson_result json_iterator::unescape(raw_json_string in, bool allow_replacement) noexcept { + return parser->unescape(in, _string_buf_loc, allow_replacement); + } + + simdjson_inline simdjson_result json_iterator::unescape_wobbly(raw_json_string in) noexcept { + return parser->unescape_wobbly(in, _string_buf_loc); + } + + simdjson_inline void json_iterator::reenter_child(token_position position, depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); +#if SIMDJSON_DEVELOPMENT_CHECKS +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(size_t(child_depth) < parser->max_depth()); + SIMDJSON_ASSUME(position >= parser->start_positions[child_depth]); +#endif +#endif + token.set_position(position); + _depth = child_depth; + } + + simdjson_inline error_code json_iterator::consume_character(char c) noexcept { + if (*peek() == c) { + return_current_and_advance(); + return SUCCESS; + } + return TAPE_ERROR; + } + +#if SIMDJSON_DEVELOPMENT_CHECKS + + simdjson_inline token_position json_iterator::start_position(depth_t depth) const noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + return size_t(depth) < parser->max_depth() ? parser->start_positions[depth] : 0; + } + + simdjson_inline void json_iterator::set_start_position(depth_t depth, token_position position) noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + if (size_t(depth) < parser->max_depth()) { parser->start_positions[depth] = position; } + } + +#endif + + + simdjson_inline error_code json_iterator::optional_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error == INCORRECT_TYPE || _error == NO_SUCH_FIELD); + logger::log_error(*this, message); + return _error; + } + + + simdjson_warn_unused simdjson_inline bool json_iterator::copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept { + // This function is not expected to be called in performance-sensitive settings. + // Let us guard against silly cases: + if ((N < max_len) || (N == 0)) { return false; } + // Copy to the buffer. + std::memcpy(tmpbuf, json, max_len); + if (N > max_len) { // We pad whatever remains with ' '. + std::memset(tmpbuf + max_len, ' ', N - max_len); + } + return true; + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::json_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/json_iterator-inl.h for haswell */ +/* including simdjson/generic/ondemand/json_type-inl.h for haswell: #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* begin file simdjson/generic/ondemand/json_type-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept { + switch (type) { + case json_type::array: out << "array"; break; + case json_type::object: out << "object"; break; + case json_type::number: out << "number"; break; + case json_type::string: out << "string"; break; + case json_type::boolean: out << "boolean"; break; + case json_type::null: out << "null"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false) { + return out << type.value(); + } +#endif + + + + simdjson_inline number_type number::get_number_type() const noexcept { + return type; + } + + simdjson_inline bool number::is_uint64() const noexcept { + return get_number_type() == number_type::unsigned_integer; + } + + simdjson_inline uint64_t number::get_uint64() const noexcept { + return payload.unsigned_integer; + } + + simdjson_inline number::operator uint64_t() const noexcept { + return get_uint64(); + } + + + simdjson_inline bool number::is_int64() const noexcept { + return get_number_type() == number_type::signed_integer; + } + + simdjson_inline int64_t number::get_int64() const noexcept { + return payload.signed_integer; + } + + simdjson_inline number::operator int64_t() const noexcept { + return get_int64(); + } + + simdjson_inline bool number::is_double() const noexcept { + return get_number_type() == number_type::floating_point_number; + } + + simdjson_inline double number::get_double() const noexcept { + return payload.floating_point_number; + } + + simdjson_inline number::operator double() const noexcept { + return get_double(); + } + + simdjson_inline double number::as_double() const noexcept { + if (is_double()) { + return payload.floating_point_number; + } + if (is_int64()) { + return double(payload.signed_integer); + } + return double(payload.unsigned_integer); + } + + simdjson_inline void number::append_s64(int64_t value) noexcept { + payload.signed_integer = value; + type = number_type::signed_integer; + } + + simdjson_inline void number::append_u64(uint64_t value) noexcept { + payload.unsigned_integer = value; + type = number_type::unsigned_integer; + } + + simdjson_inline void number::append_double(double value) noexcept { + payload.floating_point_number = value; + type = number_type::floating_point_number; + } + + simdjson_inline void number::skip_double() noexcept { + type = number_type::floating_point_number; + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::json_type&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H +/* end file simdjson/generic/ondemand/json_type-inl.h for haswell */ +/* including simdjson/generic/ondemand/logger-inl.h for haswell: #include "simdjson/generic/ondemand/logger-inl.h" */ +/* begin file simdjson/generic/ondemand/logger-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace haswell { + namespace ondemand { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static int log_depth = 0; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + template + static inline std::string string_format(const std::string& format, const Args&... args) + { + SIMDJSON_PUSH_DISABLE_ALL_WARNINGS + int size_s = std::snprintf(nullptr, 0, format.c_str(), args...) + 1; + auto size = static_cast(size_s); + if (size <= 0) return std::string(); + std::unique_ptr buf(new char[size]); + std::snprintf(buf.get(), size, format.c_str(), args...); + SIMDJSON_POP_DISABLE_WARNINGS + return std::string(buf.get(), buf.get() + size - 1); + } + + static inline log_level get_log_level_from_env() + { + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe + char* lvl = getenv("SIMDJSON_LOG_LEVEL"); + SIMDJSON_POP_DISABLE_WARNINGS + if (lvl && simdjson_strcasecmp(lvl, "ERROR") == 0) { return log_level::error; } + return log_level::info; + } + + static inline log_level log_threshold() + { + static log_level threshold = get_log_level_from_env(); + return threshold; + } + + static inline bool should_log(log_level level) + { + return level >= log_threshold(); + } + + inline void log_event(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "", type, detail, log_level::info); + } + inline void log_value(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "+", type, detail, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + inline void log_start_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_line(iter, "+", type, "", delta, depth_delta, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + + inline void log_end_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + if (LOG_ENABLED) { log_depth--; } + log_line(iter, "-", type, "", delta, depth_delta, log_level::info); + } + + inline void log_error(const json_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_line(iter, "ERROR: ", error, detail, delta, depth_delta, log_level::error); + } + inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail) noexcept { + log_line(iter, index, depth, "ERROR: ", error, detail, log_level::error); + } + + inline void log_event(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_event(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_value(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_value(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_start_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_start_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_end_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_end_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_error(const value_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_error(iter.json_iter(), error, detail, delta, depth_delta); + } + + inline void log_headers() noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(log_level::info))) { + // Technically a static variable is not thread-safe, but if you are using threads and logging... well... + static bool displayed_hint{ false }; + log_depth = 0; + printf("\n"); + if (!displayed_hint) { + // We only print this helpful header once. + printf("# Logging provides the depth and position of the iterator user-visible steps:\n"); + printf("# +array says 'this is where we were when we discovered the start array'\n"); + printf( + "# -array says 'this is where we were when we ended the array'\n"); + printf("# skip says 'this is a structural or value I am skipping'\n"); + printf("# +/-skip says 'this is a start/end array or object I am skipping'\n"); + printf("#\n"); + printf("# The indentation of the terms (array, string,...) indicates the depth,\n"); + printf("# in addition to the depth being displayed.\n"); + printf("#\n"); + printf("# Every token in the document has a single depth determined by the tokens before it,\n"); + printf("# and is not affected by what the token actually is.\n"); + printf("#\n"); + printf("# Not all structural elements are presented as tokens in the logs.\n"); + printf("#\n"); + printf("# We never give control to the user within an empty array or an empty object.\n"); + printf("#\n"); + printf("# Inside an array, having a depth greater than the array's depth means that\n"); + printf("# we are pointing inside a value.\n"); + printf("# Having a depth equal to the array means that we are pointing right before a value.\n"); + printf("# Having a depth smaller than the array means that we have moved beyond the array.\n"); + displayed_hint = true; + } + printf("\n"); + printf("| %-*s ", LOG_EVENT_LEN, "Event"); + printf("| %-*s ", LOG_BUFFER_LEN, "Buffer"); + printf("| %-*s ", LOG_SMALL_BUFFER_LEN, "Next"); + // printf("| %-*s ", 5, "Next#"); + printf("| %-*s ", 5, "Depth"); + printf("| Detail "); + printf("|\n"); + + printf("|%.*s", LOG_EVENT_LEN + 2, DASHES); + printf("|%.*s", LOG_BUFFER_LEN + 2, DASHES); + printf("|%.*s", LOG_SMALL_BUFFER_LEN + 2, DASHES); + // printf("|%.*s", 5+2, DASHES); + printf("|%.*s", 5 + 2, DASHES); + printf("|--------"); + printf("|\n"); + fflush(stdout); + } + } + } + + template + inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, log_level level, Args&&... args) noexcept { + log_line(iter, iter.position() + delta, depth_t(iter.depth() + depth_delta), title_prefix, title, detail, level, std::forward(args)...); + } + + template + inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, log_level level, Args&&... args) noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(level))) { + const int indent = depth * 2; + const auto buf = iter.token.buf; + auto msg = string_format(title, std::forward(args)...); + printf("| %*s%s%-*s ", indent, "", title_prefix, + LOG_EVENT_LEN - indent - int(strlen(title_prefix)), msg.c_str()); + { + // Print the current structural. + printf("| "); + // Before we begin, the index might point right before the document. + // This could be unsafe, see https://github.com/simdjson/simdjson/discussions/1938 + if (index < iter._root) { + printf("%*s", LOG_BUFFER_LEN, ""); + } + else { + auto current_structural = &buf[*index]; + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current_structural[i])); + } + } + printf(" "); + } + { + // Print the next structural. + printf("| "); + auto next_structural = &buf[*(index + 1)]; + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next_structural[i])); + } + printf(" "); + } + // printf("| %5u ", *(index+1)); + printf("| %5i ", depth); + printf("| %6.*s ", int(detail.size()), detail.data()); + printf("|\n"); + fflush(stdout); + } + } + } + + } // namespace logger + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H +/* end file simdjson/generic/ondemand/logger-inl.h for haswell */ +/* including simdjson/generic/ondemand/object-inl.h for haswell: #include "simdjson/generic/ondemand/object-inl.h" */ +/* begin file simdjson/generic/ondemand/object-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) & noexcept { + return find_field_unordered(key); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) && noexcept { + return std::forward(*this).find_field_unordered(key); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + + simdjson_inline simdjson_result object::start(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_object().error()); + return object(iter); + } + simdjson_inline simdjson_result object::start_root(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_root_object().error()); + return object(iter); + } + simdjson_inline error_code object::consume() noexcept { + if (iter.is_at_key()) { + /** + * whenever you are pointing at a key, calling skip_child() is + * unsafe because you will hit a string and you will assume that + * it is string value, and this mistake will lead you to make bad + * depth computation. + */ + /** + * We want to 'consume' the key. We could really + * just do _json_iter->return_current_and_advance(); at this + * point, but, for clarity, we will use the high-level API to + * eat the key. We assume that the compiler optimizes away + * most of the work. + */ + simdjson_unused raw_json_string actual_key; + auto error = iter.field_key().get(actual_key); + if (error) { iter.abandon(); return error; }; + // Let us move to the value while we are at it. + if ((error = iter.field_value())) { iter.abandon(); return error; } + } + auto error_skip = iter.json_iter().skip_child(iter.depth() - 1); + if (error_skip) { iter.abandon(); } + return error_skip; + } + + simdjson_inline simdjson_result object::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + const uint8_t* final_point{ iter._json_iter->peek() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result object::started(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.started_object().error()); + return object(iter); + } + + simdjson_inline object object::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline object::object(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result object::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return object_iterator(iter); + } + simdjson_inline simdjson_result object::end() noexcept { + return object_iterator(iter); + } + + inline simdjson_result object::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + size_t slash = json_pointer.find('/'); + std::string_view key = json_pointer.substr(0, slash); + // Grab the child with the given key + simdjson_result child; + + // If there is an escape character in the key, unescape it and then get the child. + size_t escape = key.find('~'); + if (escape != std::string_view::npos) { + // Unescape the key + std::string unescaped(key); + do { + switch (unescaped[escape + 1]) { + case '0': + unescaped.replace(escape, 2, "~"); + break; + case '1': + unescaped.replace(escape, 2, "/"); + break; + default: + return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); + } + escape = unescaped.find('~', escape + 1); + } while (escape != std::string::npos); + child = find_field(unescaped); // Take note find_field does not unescape keys when matching + } + else { + child = find_field(key); + } + if (child.error()) { + return child; // we do not continue if there was an error + } + // If there is a /, we have to recurse and look up more of the path + if (slash != std::string_view::npos) { + child = child.at_pointer(json_pointer.substr(slash)); + } + return child; + } + + simdjson_inline simdjson_result object::count_fields() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the object after counting the number of elements. + iter.reset_object(); + return count; + } + + simdjson_inline simdjson_result object::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_object().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + simdjson_inline simdjson_result object::reset() & noexcept { + return iter.reset_object(); + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::object&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first)[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + inline simdjson_result simdjson_result::reset() noexcept { + if (error()) { return error(); } + return first.reset(); + } + + inline simdjson_result simdjson_result::is_empty() noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H +/* end file simdjson/generic/ondemand/object-inl.h for haswell */ +/* including simdjson/generic/ondemand/object_iterator-inl.h for haswell: #include "simdjson/generic/ondemand/object_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/object_iterator-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + // + // object_iterator + // + + simdjson_inline object_iterator::object_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result object_iterator::operator*() noexcept { + error_code error = iter.error(); + if (error) { iter.abandon(); return error; } + auto result = field::start(iter); + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (result.error()) { iter.abandon(); } + return result; + } + simdjson_inline bool object_iterator::operator==(const object_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool object_iterator::operator!=(const object_iterator&) const noexcept { + return iter.is_open(); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline object_iterator& object_iterator::operator++() noexcept { + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (!iter.is_open()) { return *this; } // Iterator will be released if there is an error + + simdjson_unused error_code error; + if ((error = iter.skip_child())) { return *this; } + + simdjson_unused bool has_value; + if ((error = iter.has_next_field().get(has_value))) { return *this; }; + return *this; + } + SIMDJSON_POP_DISABLE_WARNINGS + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter.depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the object is first found and the iterator is just past the {. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the , or } before the next value. In this state, + // depth == iter.depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter.depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter.depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the object iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet field may be missing or not be an + // object--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter.depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between fields, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter.depth == depth, and at_start == false. + // + // Errors that occur while reading a field to give to the user (such as when the key is not a + // string or the field is missing a colon) are yielded immediately. Depth is then decremented, + // moving to the Finished state without transitioning through an Error state at all. + // + // ## Terminal State + // + // The terminal state has iter.depth < depth. at_start is always false. + // + // - Finished: When we have reached a }, we are finished. We signal this by decrementing depth. + // In this state, iter.depth < depth, at_start == false, and error == SUCCESS. + // + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + haswell::ondemand::object_iterator&& value + ) noexcept + : implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + // Checks for ']' and ',' + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++first; + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/object_iterator-inl.h for haswell */ +/* including simdjson/generic/ondemand/parser-inl.h for haswell: #include "simdjson/generic/ondemand/parser-inl.h" */ +/* begin file simdjson/generic/ondemand/parser-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string_view.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/dom/base.h" // for MINIMAL_DOCUMENT_CAPACITY */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline parser::parser(size_t max_capacity) noexcept + : _max_capacity{ max_capacity } { + } + + simdjson_warn_unused simdjson_inline error_code parser::allocate(size_t new_capacity, size_t new_max_depth) noexcept { + if (new_capacity > max_capacity()) { return CAPACITY; } + if (string_buf && new_capacity == capacity() && new_max_depth == max_depth()) { return SUCCESS; } + + // string_capacity copied from document::allocate + _capacity = 0; + size_t string_capacity = SIMDJSON_ROUNDUP_N(5 * new_capacity / 3 + SIMDJSON_PADDING, 64); + string_buf.reset(new (std::nothrow) uint8_t[string_capacity]); +#if SIMDJSON_DEVELOPMENT_CHECKS + start_positions.reset(new (std::nothrow) token_position[new_max_depth]); +#endif + if (implementation) { + SIMDJSON_TRY(implementation->set_capacity(new_capacity)); + SIMDJSON_TRY(implementation->set_max_depth(new_max_depth)); + } + else { + SIMDJSON_TRY(simdjson::get_active_implementation()->create_dom_parser_implementation(new_capacity, new_max_depth, implementation)); + } + _capacity = new_capacity; + _max_depth = new_max_depth; + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length() || !string_buf) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return document::start({ reinterpret_cast(json.data()), this }); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const char* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const uint8_t* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string_view json, size_t allocated) & noexcept { + return iterate(padded_string_view(json, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string& json) & noexcept { + if (json.capacity() - json.size() < SIMDJSON_PADDING) { + json.reserve(json.size() + SIMDJSON_PADDING); + } + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const std::string& json) & noexcept { + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + padded_string_view json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + const padded_string& json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate_raw(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length()) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return json_iterator(reinterpret_cast(json.data()), this); + } + + inline simdjson_result parser::iterate_many(const uint8_t* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + if (allow_comma_separated && batch_size < len) { batch_size = len; } + return document_stream(*this, buf, len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const char* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(reinterpret_cast(buf), len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const std::string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const padded_string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + + simdjson_inline size_t parser::capacity() const noexcept { + return _capacity; + } + simdjson_inline size_t parser::max_capacity() const noexcept { + return _max_capacity; + } + simdjson_inline size_t parser::max_depth() const noexcept { + return _max_depth; + } + + simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { + if (max_capacity < dom::MINIMAL_DOCUMENT_CAPACITY) { + _max_capacity = max_capacity; + } + else { + _max_capacity = dom::MINIMAL_DOCUMENT_CAPACITY; + } + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement) const noexcept { + uint8_t* end = implementation->parse_string(in.buf, dst, allow_replacement); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept { + uint8_t* end = implementation->parse_wobbly_string(in.buf, dst); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::parser&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H +/* end file simdjson/generic/ondemand/parser-inl.h for haswell */ +/* including simdjson/generic/ondemand/raw_json_string-inl.h for haswell: #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + namespace haswell { + namespace ondemand { + + simdjson_inline raw_json_string::raw_json_string(const uint8_t* _buf) noexcept : buf{ _buf } {} + + simdjson_inline const char* raw_json_string::raw() const noexcept { return reinterpret_cast(buf); } + + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(std::string_view target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; pos < target.size() && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(const char* target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; target[pos] && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; target[pos]; pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(size_t length, std::string_view target) const noexcept { + // If we are going to call memcmp, then we must know something about the length of the raw_json_string. + return (length >= target.size()) && (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + + simdjson_inline bool raw_json_string::unsafe_is_equal(std::string_view target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + if (target.size() <= SIMDJSON_PADDING) { + return (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + const char* r{ raw() }; + size_t pos{ 0 }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(std::string_view target) const noexcept { + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(const char* target) const noexcept { + // Assumptions: 'target' does not contain unescaped quote characters, is null terminated and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(const char* target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept { + return a.unsafe_is_equal(c); + } + + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept { + return a == c; + } + + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept { + return !(a == c); + } + + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept { + return !(a == c); + } + + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape(json_iterator& iter, bool allow_replacement) const noexcept { + return iter.unescape(*this, allow_replacement); + } + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape_wobbly(json_iterator& iter) const noexcept { + return iter.unescape_wobbly(*this); + } + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream& out, const raw_json_string& str) noexcept { + bool in_escape = false; + const char* s = str.raw(); + while (true) { + switch (*s) { + case '\\': in_escape = !in_escape; break; + case '"': if (in_escape) { in_escape = false; } + else { return out; } break; + default: if (in_escape) { in_escape = false; } + } + out << *s; + s++; + } + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::raw_json_string&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::raw() const noexcept { + if (error()) { return error(); } + return first.raw(); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape(haswell::ondemand::json_iterator& iter, bool allow_replacement) const noexcept { + if (error()) { return error(); } + return first.unescape(iter, allow_replacement); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape_wobbly(haswell::ondemand::json_iterator& iter) const noexcept { + if (error()) { return error(); } + return first.unescape_wobbly(iter); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H +/* end file simdjson/generic/ondemand/raw_json_string-inl.h for haswell */ +/* including simdjson/generic/ondemand/serialization-inl.h for haswell: #include "simdjson/generic/ondemand/serialization-inl.h" */ +/* begin file simdjson/generic/ondemand/serialization-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/serialization.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + inline std::string_view trim(const std::string_view str) noexcept { + // We can almost surely do better by rolling our own find_first_not_of function. + size_t first = str.find_first_not_of(" \t\n\r"); + // If we have the empty string (just white space), then no trimming is possible, and + // we return the empty string_view. + if (std::string_view::npos == first) { return std::string_view(); } + size_t last = str.find_last_not_of(" \t\n\r"); + return str.substr(first, (last - first + 1)); + } + + + inline simdjson_result to_json_string(haswell::ondemand::document& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(haswell::ondemand::document_reference& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(haswell::ondemand::value& x) noexcept { + /** + * If we somehow receive a value that has already been consumed, + * then the following code could be in trouble. E.g., we create + * an array as needed, but if an array was already created, then + * it could be bad. + */ + using namespace haswell::ondemand; + haswell::ondemand::json_type t; + auto error = x.type().get(t); + if (error != SUCCESS) { return error; } + switch (t) + { + case json_type::array: + { + haswell::ondemand::array array; + error = x.get_array().get(array); + if (error) { return error; } + return to_json_string(array); + } + case json_type::object: + { + haswell::ondemand::object object; + error = x.get_object().get(object); + if (error) { return error; } + return to_json_string(object); + } + default: + return trim(x.raw_json_token()); + } + } + + inline simdjson_result to_json_string(haswell::ondemand::object& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(haswell::ondemand::array& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } +} // namespace simdjson + +namespace simdjson { + namespace haswell { + namespace ondemand { + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::document_reference& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::haswell::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + } + } +} // namespace simdjson::haswell::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H +/* end file simdjson/generic/ondemand/serialization-inl.h for haswell */ +/* including simdjson/generic/ondemand/token_iterator-inl.h for haswell: #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/token_iterator-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline token_iterator::token_iterator( + const uint8_t* _buf, + token_position position + ) noexcept : buf{ _buf }, _position{ position } + { + } + + simdjson_inline uint32_t token_iterator::current_offset() const noexcept { + return *(_position); + } + + + simdjson_inline const uint8_t* token_iterator::return_current_and_advance() noexcept { + return &buf[*(_position++)]; + } + + simdjson_inline const uint8_t* token_iterator::peek(token_position position) const noexcept { + return &buf[*position]; + } + simdjson_inline uint32_t token_iterator::peek_index(token_position position) const noexcept { + return *position; + } + simdjson_inline uint32_t token_iterator::peek_length(token_position position) const noexcept { + return *(position + 1) - *position; + } + + simdjson_inline const uint8_t* token_iterator::peek(int32_t delta) const noexcept { + return &buf[*(_position + delta)]; + } + simdjson_inline uint32_t token_iterator::peek_index(int32_t delta) const noexcept { + return *(_position + delta); + } + simdjson_inline uint32_t token_iterator::peek_length(int32_t delta) const noexcept { + return *(_position + delta + 1) - *(_position + delta); + } + + simdjson_inline token_position token_iterator::position() const noexcept { + return _position; + } + simdjson_inline void token_iterator::set_position(token_position target_position) noexcept { + _position = target_position; + } + + simdjson_inline bool token_iterator::operator==(const token_iterator& other) const noexcept { + return _position == other._position; + } + simdjson_inline bool token_iterator::operator!=(const token_iterator& other) const noexcept { + return _position != other._position; + } + simdjson_inline bool token_iterator::operator>(const token_iterator& other) const noexcept { + return _position > other._position; + } + simdjson_inline bool token_iterator::operator>=(const token_iterator& other) const noexcept { + return _position >= other._position; + } + simdjson_inline bool token_iterator::operator<(const token_iterator& other) const noexcept { + return _position < other._position; + } + simdjson_inline bool token_iterator::operator<=(const token_iterator& other) const noexcept { + return _position <= other._position; + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::token_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/token_iterator-inl.h for haswell */ +/* including simdjson/generic/ondemand/value-inl.h for haswell: #include "simdjson/generic/ondemand/value-inl.h" */ +/* begin file simdjson/generic/ondemand/value-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline value::value(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + simdjson_inline value value::start(const value_iterator& iter) noexcept { + return iter; + } + simdjson_inline value value::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline simdjson_result value::get_array() noexcept { + return array::start(iter); + } + simdjson_inline simdjson_result value::get_object() noexcept { + return object::start(iter); + } + simdjson_inline simdjson_result value::start_or_resume_object() noexcept { + if (iter.at_start()) { + return get_object(); + } + else { + return object::resume(iter); + } + } + + simdjson_inline simdjson_result value::get_raw_json_string() noexcept { + return iter.get_raw_json_string(); + } + simdjson_inline simdjson_result value::get_string(bool allow_replacement) noexcept { + return iter.get_string(allow_replacement); + } + template + simdjson_inline error_code value::get_string(string_type& receiver, bool allow_replacement) noexcept { + return iter.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result value::get_wobbly_string() noexcept { + return iter.get_wobbly_string(); + } + simdjson_inline simdjson_result value::get_double() noexcept { + return iter.get_double(); + } + simdjson_inline simdjson_result value::get_double_in_string() noexcept { + return iter.get_double_in_string(); + } + simdjson_inline simdjson_result value::get_uint64() noexcept { + return iter.get_uint64(); + } + simdjson_inline simdjson_result value::get_uint64_in_string() noexcept { + return iter.get_uint64_in_string(); + } + simdjson_inline simdjson_result value::get_int64() noexcept { + return iter.get_int64(); + } + simdjson_inline simdjson_result value::get_int64_in_string() noexcept { + return iter.get_int64_in_string(); + } + simdjson_inline simdjson_result value::get_bool() noexcept { + return iter.get_bool(); + } + simdjson_inline simdjson_result value::is_null() noexcept { + return iter.is_null(); + } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_array(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_object(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_number(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_double(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_bool(); } + + template simdjson_inline error_code value::get(T& out) noexcept { + return get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline value::operator array() noexcept(false) { + return get_array(); + } + simdjson_inline value::operator object() noexcept(false) { + return get_object(); + } + simdjson_inline value::operator uint64_t() noexcept(false) { + return get_uint64(); + } + simdjson_inline value::operator int64_t() noexcept(false) { + return get_int64(); + } + simdjson_inline value::operator double() noexcept(false) { + return get_double(); + } + simdjson_inline value::operator std::string_view() noexcept(false) { + return get_string(false); + } + simdjson_inline value::operator raw_json_string() noexcept(false) { + return get_raw_json_string(); + } + simdjson_inline value::operator bool() noexcept(false) { + return get_bool(); + } +#endif + + simdjson_inline simdjson_result value::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result value::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result value::count_elements() & noexcept { + simdjson_result answer; + auto a = get_array(); + answer = a.count_elements(); + // count_elements leaves you pointing inside the array, at the first element. + // We need to move back so that the user can create a new array (which requires that + // we point at '['). + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::count_fields() & noexcept { + simdjson_result answer; + auto a = get_object(); + answer = a.count_fields(); + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::at(size_t index) noexcept { + auto a = get_array(); + return a.at(index); + } + + simdjson_inline simdjson_result value::find_field(std::string_view key) noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result value::find_field(const char* key) noexcept { + return start_or_resume_object().find_field(key); + } + + simdjson_inline simdjson_result value::find_field_unordered(std::string_view key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result value::find_field_unordered(const char* key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + + simdjson_inline simdjson_result value::operator[](std::string_view key) noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result value::operator[](const char* key) noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline simdjson_result value::type() noexcept { + return iter.type(); + } + + simdjson_inline simdjson_result value::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool value::is_negative() noexcept { + return iter.is_negative(); + } + + simdjson_inline simdjson_result value::is_integer() noexcept { + return iter.is_integer(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number_type() noexcept { + return iter.get_number_type(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number() noexcept { + return iter.get_number(); + } + + simdjson_inline std::string_view value::raw_json_token() noexcept { + return std::string_view(reinterpret_cast(iter.peek_start()), iter.peek_start_length()); + } + + simdjson_inline simdjson_result value::raw_json() noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: { + ondemand::array array; + SIMDJSON_TRY(get_array().get(array)); + return array.raw_json(); + } + case json_type::object: { + ondemand::object object; + SIMDJSON_TRY(get_object().get(object)); + return object.raw_json(); + } + default: + return raw_json_token(); + } + } + + simdjson_inline simdjson_result value::current_location() noexcept { + return iter.json_iter().current_location(); + } + + simdjson_inline int32_t value::current_depth() const noexcept { + return iter.json_iter().depth(); + } + + simdjson_inline simdjson_result value::at_pointer(std::string_view json_pointer) noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + haswell::ondemand::value&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + if (error()) { return error(); } + return {}; + } + + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) noexcept { + if (error()) { return error(); } + return first[key]; + } + + simdjson_inline simdjson_result simdjson_result::get_array() noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return first.get(); + } + template simdjson_inline error_code simdjson_result::get(T& out) noexcept { + if (error()) { return error(); } + return first.get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return std::move(first); + } + template<> simdjson_inline error_code simdjson_result::get(haswell::ondemand::value& out) noexcept { + if (error()) { return error(); } + out = first; + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator haswell::ondemand::array() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::object() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator haswell::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H +/* end file simdjson/generic/ondemand/value-inl.h for haswell */ +/* including simdjson/generic/ondemand/value_iterator-inl.h for haswell: #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/value_iterator-inl.h for haswell */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/atomparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace haswell { + namespace ondemand { + + simdjson_inline value_iterator::value_iterator( + json_iterator* json_iter, + depth_t depth, + token_position start_position + ) noexcept : _json_iter{ json_iter }, _depth{ depth }, _start_position{ start_position } + { + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_root_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_object() noexcept { + assert_at_container_start(); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + if (*_json_iter->peek() == '}') { + logger::log_value(*_json_iter, "empty object"); + _json_iter->return_current_and_advance(); + end_container(); + return false; + } + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_object() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // object: e.g., `{"a":2} foo }`. Users concerned with garbage content should + // call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != '}') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing } at end"); + } + // If the last character is } *and* the first gibberish character is also '}' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == '}') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed object. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_object() noexcept { + auto error = check_root_object(); + if (error) { return error; } + return started_object(); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::end_container() noexcept { +#if SIMDJSON_CHECK_EOF + if (depth() > 1 && at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing parent ] or }"); } + // if (depth() <= 1 && !at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + _json_iter->ascend_to(depth() - 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_field() noexcept { + assert_at_next(); + + // It's illegal to call this unless there are more tokens: anything that ends in } or ] is + // obligated to verify there are more tokens if they are not the top level. + switch (*_json_iter->return_current_and_advance()) { + case '}': + logger::log_end_value(*_json_iter, "object"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between object fields"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_raw(const std::string_view key) noexcept { + error_code error; + bool has_value; + // + // Initially, the object can be in one of a few different places: + // + // 1. The start of the object, at the first field: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + if (at_first_field()) { + has_value = true; + + // + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + return false; + + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + if ((error = skip_child())) { abandon(); return error; } + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + while (has_value) { + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + //if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); // Skip the value entirely + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + + // If the loop ended, we're out of fields to look at. + return false; + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_unordered_raw(const std::string_view key) noexcept { + /** + * When find_field_unordered_raw is called, we can either be pointing at the + * first key, pointing outside (at the closing brace) or if a key was matched + * we can be either pointing right afterthe ':' right before the value (that we need skip), + * or we may have consumed the value and we might be at a comma or at the + * final brace (ready for a call to has_next_field()). + */ + error_code error; + bool has_value; + + // First, we scan from that point to the end. + // If we don't find a match, we may loop back around, and scan from the beginning to that point. + token_position search_start = _json_iter->position(); + + // We want to know whether we need to go back to the beginning. + bool at_first = at_first_field(); + /////////////// + // Initially, the object can be in one of a few different places: + // + // 1. At the first key: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + // + if (at_first) { + has_value = true; + + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { + +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + SIMDJSON_TRY(reset_object().get(has_value)); + at_first = true; + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + // If someone queried a key but they not did access the value, then we are left pointing + // at the ':' and we need to move forward through the value... If the value was + // processed then skip_child() does not move the iterator (but may adjust the depth). + if ((error = skip_child())) { abandon(); return error; } + search_start = _json_iter->position(); + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + + // After initial processing, we will be in one of two states: + // + // ``` + // // At the beginning of a field + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // At the end of the object + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // ``` + // + // Next, we find a match starting from the current position. + while (has_value) { + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + // Performance note: it maybe wasteful to rewind to the beginning when there might be + // no other query following. Indeed, it would require reskipping the whole object. + // Instead, you can just stay where you are. If there is a new query, there is always time + // to rewind. + if (at_first) { return false; } + + // If we reach the end without finding a match, search the rest of the fields starting at the + // beginning of the object. + // (We have already run through the object before, so we've already validated its structure. We + // don't check errors in this bit.) + SIMDJSON_TRY(reset_object().get(has_value)); + while (true) { + SIMDJSON_ASSUME(has_value); // we should reach search_start before ever reaching the end of the object + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + error = field_key().get(actual_key); SIMDJSON_ASSUME(!error); + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + error = field_value(); SIMDJSON_ASSUME(!error); + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // If we reached the end of the key-value pair we started from, then we know + // that the key is not there so we return false. We are either right before + // the next comma or the final brace. + if (_json_iter->position() == search_start) { return false; } + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + error = has_next_field().get(has_value); SIMDJSON_ASSUME(!error); + // If we make the mistake of exiting here, then we could be left pointing at a key + // in the middle of an object. That's not an allowable state. + } + // If the loop ended, we're out of fields to look at. The program should + // never reach this point. + return false; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::field_key() noexcept { + assert_at_next(); + + const uint8_t* key = _json_iter->return_current_and_advance(); + if (*(key++) != '"') { return report_error(TAPE_ERROR, "Object key is not a string"); } + return raw_json_string(key); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::field_value() noexcept { + assert_at_next(); + + if (*_json_iter->return_current_and_advance() != ':') { return report_error(TAPE_ERROR, "Missing colon in object field"); } + _json_iter->descend_to(depth() + 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_root_array(); + } + + inline std::string value_iterator::to_string() const noexcept { + auto answer = std::string("value_iterator [ depth : ") + std::to_string(_depth) + std::string(", "); + if (_json_iter != nullptr) { answer += _json_iter->to_string(); } + answer += std::string(" ]"); + return answer; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_array() noexcept { + assert_at_container_start(); + if (*_json_iter->peek() == ']') { + logger::log_value(*_json_iter, "empty array"); + _json_iter->return_current_and_advance(); + SIMDJSON_TRY(end_container()); + return false; + } + _json_iter->descend_to(depth() + 1); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_array() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // array: e.g., `[1, 2] foo]`. Users concerned with garbage content should + // also call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != ']') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing ] at end"); + } + // If the last character is ] *and* the first gibberish character is also ']' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == ']') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed array. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_array() noexcept { + auto error = check_root_array(); + if (error) { return error; } + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_element() noexcept { + assert_at_next(); + + logger::log_event(*this, "has_next_element"); + switch (*_json_iter->return_current_and_advance()) { + case ']': + logger::log_end_value(*_json_iter, "array"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + _json_iter->descend_to(depth() + 1); + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between array elements"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_bool(const uint8_t* json) const noexcept { + auto not_true = atomparsing::str4ncmp(json, "true"); + auto not_false = atomparsing::str4ncmp(json, "fals") | (json[4] ^ 'e'); + bool error = (not_true && not_false) || jsoncharutils::is_not_structural_or_whitespace(json[not_true ? 5 : 4]); + if (error) { return incorrect_type_error("Not a boolean"); } + return simdjson_result(!not_true); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_null(const uint8_t* json) const noexcept { + bool is_null_string = !atomparsing::str4ncmp(json, "null") && jsoncharutils::is_structural_or_whitespace(json[4]); + // if we start with 'n', we must be a null + if (!is_null_string && json[0] == 'n') { return incorrect_type_error("Not a null but starts with n"); } + return is_null_string; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_string(bool allow_replacement) noexcept { + return get_raw_json_string().unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_string(string_type& receiver, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_string(allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_wobbly_string() noexcept { + return get_raw_json_string().unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_raw_json_string() noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64() noexcept { + auto result = numberparsing::parse_unsigned(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64_in_string() noexcept { + auto result = numberparsing::parse_unsigned_in_string(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64() noexcept { + auto result = numberparsing::parse_integer(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64_in_string() noexcept { + auto result = numberparsing::parse_integer_in_string(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double() noexcept { + auto result = numberparsing::parse_double(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double_in_string() noexcept { + auto result = numberparsing::parse_double_in_string(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_bool() noexcept { + auto result = parse_bool(peek_non_root_scalar("bool")); + if (result.error() == SUCCESS) { advance_non_root_scalar("bool"); } + return result; + } + simdjson_inline simdjson_result value_iterator::is_null() noexcept { + bool is_null_value; + SIMDJSON_TRY(parse_null(peek_non_root_scalar("null")).get(is_null_value)); + if (is_null_value) { advance_non_root_scalar("null"); } + return is_null_value; + } + simdjson_inline bool value_iterator::is_negative() noexcept { + return numberparsing::is_negative(peek_non_root_scalar("numbersign")); + } + simdjson_inline bool value_iterator::is_root_negative() noexcept { + return numberparsing::is_negative(peek_root_scalar("numbersign")); + } + simdjson_inline simdjson_result value_iterator::is_integer() noexcept { + return numberparsing::is_integer(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number_type() noexcept { + return numberparsing::get_number_type(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number() noexcept { + number num; + error_code error = numberparsing::parse_number(peek_non_root_scalar("number"), num); + if (error) { return error; } + return num; + } + + simdjson_inline simdjson_result value_iterator::is_root_integer(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("is_root_integer"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + return false; // if there are more than 20 characters, it cannot be represented as an integer. + } + auto answer = numberparsing::is_integer(tmpbuf); + // If the parsing was a success, we must still check that it is + // a single scalar. Note that we parse first because of cases like '[]' where + // getting TRAILING_CONTENT is wrong. + if (check_trailing && (answer.error() == SUCCESS) && (!_json_iter->is_single_token())) { return TRAILING_CONTENT; } + return answer; + } + + simdjson_inline simdjson_result value_iterator::get_root_number_type(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto answer = numberparsing::get_number_type(tmpbuf); + if (check_trailing && (answer.error() == SUCCESS) && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + return answer; + } + simdjson_inline simdjson_result value_iterator::get_root_number(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + number num; + error_code error = numberparsing::parse_number(tmpbuf, num); + if (error) { return error; } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("number"); + return num; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_string(bool check_trailing, bool allow_replacement) noexcept { + return get_root_raw_json_string(check_trailing).unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_root_string(check_trailing, allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_wobbly_string(bool check_trailing) noexcept { + return get_root_raw_json_string(check_trailing).unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_raw_json_string(bool check_trailing) noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_bool(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("bool"); + uint8_t tmpbuf[5 + 1 + 1]; // +1 for null termination + tmpbuf[5 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 5 + 1)) { return incorrect_type_error("Not a boolean"); } + auto result = parse_bool(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("bool"); + } + return result; + } + simdjson_inline simdjson_result value_iterator::is_root_null(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("null"); + bool result = (max_len >= 4 && !atomparsing::str4ncmp(json, "null") && + (max_len == 4 || jsoncharutils::is_structural_or_whitespace(json[4]))); + if (result) { // we have something that looks like a null. + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("null"); + } + return result; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::skip_child() noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth >= _depth); + + return _json_iter->skip_child(depth()); + } + + simdjson_inline value_iterator value_iterator::child() const noexcept { + assert_at_child(); + return { _json_iter, depth() + 1, _json_iter->token.position() }; + } + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and iterator depth, which is a desired effect. It does not happen if is_open is + // marked non-inline. + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline bool value_iterator::is_open() const noexcept { + return _json_iter->depth() >= depth(); + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool value_iterator::at_end() const noexcept { + return _json_iter->at_end(); + } + + simdjson_inline bool value_iterator::at_start() const noexcept { + return _json_iter->token.position() == start_position(); + } + + simdjson_inline bool value_iterator::at_first_field() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + return _json_iter->token.position() == start_position() + 1; + } + + simdjson_inline void value_iterator::abandon() noexcept { + _json_iter->abandon(); + } + + simdjson_warn_unused simdjson_inline depth_t value_iterator::depth() const noexcept { + return _depth; + } + simdjson_warn_unused simdjson_inline error_code value_iterator::error() const noexcept { + return _json_iter->error; + } + simdjson_warn_unused simdjson_inline uint8_t*& value_iterator::string_buf_loc() noexcept { + return _json_iter->string_buf_loc(); + } + simdjson_warn_unused simdjson_inline const json_iterator& value_iterator::json_iter() const noexcept { + return *_json_iter; + } + simdjson_warn_unused simdjson_inline json_iterator& value_iterator::json_iter() noexcept { + return *_json_iter; + } + + simdjson_inline const uint8_t* value_iterator::peek_start() const noexcept { + return _json_iter->peek(start_position()); + } + simdjson_inline uint32_t value_iterator::peek_start_length() const noexcept { + return _json_iter->peek_length(start_position()); + } + + simdjson_inline const uint8_t* value_iterator::peek_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return peek_start(); } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return; } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept { + logger::log_start_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + const uint8_t* json; + if (!is_at_start()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + json = peek_start(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + } + else { + assert_at_start(); + /** + * We should be prudent. Let us peek. If it is not the right type, we + * return an error. Only once we have determined that we have the right + * type are we allowed to advance! + */ + json = _json_iter->peek(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + _json_iter->return_current_and_advance(); + } + + + return SUCCESS; + } + + + simdjson_inline const uint8_t* value_iterator::peek_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_root(); + return _json_iter->peek(); + } + simdjson_inline const uint8_t* value_iterator::peek_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_non_root_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_root(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + simdjson_inline void value_iterator::advance_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_non_root_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::incorrect_type_error(const char* message) const noexcept { + logger::log_error(*_json_iter, start_position(), depth(), message); + return INCORRECT_TYPE; + } + + simdjson_inline bool value_iterator::is_at_start() const noexcept { + return position() == start_position(); + } + + simdjson_inline bool value_iterator::is_at_key() const noexcept { + // Keys are at the same depth as the object. + // Note here that we could be safer and check that we are within an object, + // but we do not. + return _depth == _json_iter->_depth && *_json_iter->peek() == '"'; + } + + simdjson_inline bool value_iterator::is_at_iterator_start() const noexcept { + // We can legitimately be either at the first value ([1]), or after the array if it's empty ([]). + auto delta = position() - start_position(); + return delta == 1 || delta == 2; + } + + inline void value_iterator::assert_at_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_container_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position + 1); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_next() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + simdjson_inline void value_iterator::move_at_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position); + } + + simdjson_inline void value_iterator::move_at_container_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position + 1); + } + + simdjson_inline simdjson_result value_iterator::reset_array() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_array(); + } + + simdjson_inline simdjson_result value_iterator::reset_object() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_object(); + } + + inline void value_iterator::assert_at_child() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth + 1); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_root() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth == 1); + } + + inline void value_iterator::assert_at_non_root_start() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth > 1); + } + + inline void value_iterator::assert_is_valid() const noexcept { + SIMDJSON_ASSUME(_json_iter != nullptr); + } + + simdjson_inline bool value_iterator::is_valid() const noexcept { + return _json_iter != nullptr; + } + + simdjson_inline simdjson_result value_iterator::type() const noexcept { + switch (*peek_start()) { + case '{': + return json_type::object; + case '[': + return json_type::array; + case '"': + return json_type::string; + case 'n': + return json_type::null; + case 't': case 'f': + return json_type::boolean; + case '-': + case '0': case '1': case '2': case '3': case '4': + case '5': case '6': case '7': case '8': case '9': + return json_type::number; + default: + return TAPE_ERROR; + } + } + + simdjson_inline token_position value_iterator::start_position() const noexcept { + return _start_position; + } + + simdjson_inline token_position value_iterator::position() const noexcept { + return _json_iter->position(); + } + + simdjson_inline token_position value_iterator::end_position() const noexcept { + return _json_iter->end_position(); + } + + simdjson_inline token_position value_iterator::last_position() const noexcept { + return _json_iter->last_position(); + } + + simdjson_inline error_code value_iterator::report_error(error_code error, const char* message) noexcept { + return _json_iter->report_error(error, message); + } + + } // namespace ondemand + } // namespace haswell +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(haswell::ondemand::value_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/value_iterator-inl.h for haswell */ +/* end file simdjson/generic/ondemand/amalgamated.h for haswell */ +/* including simdjson/haswell/end.h: #include "simdjson/haswell/end.h" */ +/* begin file simdjson/haswell/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/haswell/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_HASWELL +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "haswell" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/haswell/end.h */ + +#endif // SIMDJSON_HASWELL_ONDEMAND_H +/* end file simdjson/haswell/ondemand.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(icelake) +/* including simdjson/icelake/ondemand.h: #include "simdjson/icelake/ondemand.h" */ +/* begin file simdjson/icelake/ondemand.h */ +#ifndef SIMDJSON_ICELAKE_ONDEMAND_H +#define SIMDJSON_ICELAKE_ONDEMAND_H + +/* including simdjson/icelake/begin.h: #include "simdjson/icelake/begin.h" */ +/* begin file simdjson/icelake/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "icelake" */ +#define SIMDJSON_IMPLEMENTATION icelake +/* including simdjson/icelake/base.h: #include "simdjson/icelake/base.h" */ +/* begin file simdjson/icelake/base.h */ +#ifndef SIMDJSON_ICELAKE_BASE_H +#define SIMDJSON_ICELAKE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_ICELAKE +namespace simdjson { + /** + * Implementation for Icelake (Intel AVX512). + */ + namespace icelake { + + class implementation; + + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BASE_H +/* end file simdjson/icelake/base.h */ +/* including simdjson/icelake/intrinsics.h: #include "simdjson/icelake/intrinsics.h" */ +/* begin file simdjson/icelake/intrinsics.h */ +#ifndef SIMDJSON_ICELAKE_INTRINSICS_H +#define SIMDJSON_ICELAKE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + * e.g., if __AVX2__ is set... in turn, we normally set these + * macros by compiling against the corresponding architecture + * (e.g., arch:AVX2, -mavx2, etc.) which compiles the whole + * software with these advanced instructions. In simdjson, we + * want to compile the whole program for a generic target, + * and only target our specific kernels. As a workaround, + * we directly include the needed headers. These headers would + * normally guard against such usage, but we carefully included + * (or ) before, so the headers + * are fooled. + */ +#include // for _blsr_u64 +#include // for __lzcnt64 +#include // for most things (AVX2, AVX512, _popcnt64) +#include +#include +#include +#include +#include // for _mm_clmulepi64_si128 + // Important: we need the AVX-512 headers: +#include +#include +#include +#include +#include +#include +#include +// unfortunately, we may not get _blsr_u64, but, thankfully, clang +// has it as a macro. +#ifndef _blsr_u64 +// we roll our own +#define _blsr_u64(n) ((n - 1) & n) +#endif // _blsr_u64 +#endif // SIMDJSON_CLANG_VISUAL_STUDIO + +static_assert(sizeof(__m512i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for icelake"); + +#endif // SIMDJSON_ICELAKE_INTRINSICS_H +/* end file simdjson/icelake/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_TARGET_REGION("avx512f,avx512dq,avx512cd,avx512bw,avx512vbmi,avx512vbmi2,avx512vl,avx2,bmi,pclmul,lzcnt,popcnt") +#endif + +/* including simdjson/icelake/bitmanipulation.h: #include "simdjson/icelake/bitmanipulation.h" */ +/* begin file simdjson/icelake/bitmanipulation.h */ +#ifndef SIMDJSON_ICELAKE_BITMANIPULATION_H +#define SIMDJSON_ICELAKE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return (int)_tzcnt_u64(input_num); +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + //////// + // You might expect the next line to be equivalent to + // return (int)_tzcnt_u64(input_num); + // but the generated code differs and might be less efficient? + //////// + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return _blsr_u64(input_num); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { + return int(_lzcnt_u64(input_num)); + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMANIPULATION_H +/* end file simdjson/icelake/bitmanipulation.h */ +/* including simdjson/icelake/bitmask.h: #include "simdjson/icelake/bitmask.h" */ +/* begin file simdjson/icelake/bitmask.h */ +#ifndef SIMDJSON_ICELAKE_BITMASK_H +#define SIMDJSON_ICELAKE_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processor supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_BITMASK_H +/* end file simdjson/icelake/bitmask.h */ +/* including simdjson/icelake/simd.h: #include "simdjson/icelake/simd.h" */ +/* begin file simdjson/icelake/simd.h */ +#ifndef SIMDJSON_ICELAKE_SIMD_H +#define SIMDJSON_ICELAKE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if defined(__GNUC__) && !defined(__clang__) +#if __GNUC__ == 8 +#define SIMDJSON_GCC8 1 +#endif // __GNUC__ == 8 +#endif // defined(__GNUC__) && !defined(__clang__) + +#if SIMDJSON_GCC8 +/** + * GCC 8 fails to provide _mm512_set_epi8. We roll our own. + */ +inline __m512i _mm512_set_epi8(uint8_t a0, uint8_t a1, uint8_t a2, uint8_t a3, uint8_t a4, uint8_t a5, uint8_t a6, uint8_t a7, uint8_t a8, uint8_t a9, uint8_t a10, uint8_t a11, uint8_t a12, uint8_t a13, uint8_t a14, uint8_t a15, uint8_t a16, uint8_t a17, uint8_t a18, uint8_t a19, uint8_t a20, uint8_t a21, uint8_t a22, uint8_t a23, uint8_t a24, uint8_t a25, uint8_t a26, uint8_t a27, uint8_t a28, uint8_t a29, uint8_t a30, uint8_t a31, uint8_t a32, uint8_t a33, uint8_t a34, uint8_t a35, uint8_t a36, uint8_t a37, uint8_t a38, uint8_t a39, uint8_t a40, uint8_t a41, uint8_t a42, uint8_t a43, uint8_t a44, uint8_t a45, uint8_t a46, uint8_t a47, uint8_t a48, uint8_t a49, uint8_t a50, uint8_t a51, uint8_t a52, uint8_t a53, uint8_t a54, uint8_t a55, uint8_t a56, uint8_t a57, uint8_t a58, uint8_t a59, uint8_t a60, uint8_t a61, uint8_t a62, uint8_t a63) { + return _mm512_set_epi64(uint64_t(a7) + (uint64_t(a6) << 8) + (uint64_t(a5) << 16) + (uint64_t(a4) << 24) + (uint64_t(a3) << 32) + (uint64_t(a2) << 40) + (uint64_t(a1) << 48) + (uint64_t(a0) << 56), + uint64_t(a15) + (uint64_t(a14) << 8) + (uint64_t(a13) << 16) + (uint64_t(a12) << 24) + (uint64_t(a11) << 32) + (uint64_t(a10) << 40) + (uint64_t(a9) << 48) + (uint64_t(a8) << 56), + uint64_t(a23) + (uint64_t(a22) << 8) + (uint64_t(a21) << 16) + (uint64_t(a20) << 24) + (uint64_t(a19) << 32) + (uint64_t(a18) << 40) + (uint64_t(a17) << 48) + (uint64_t(a16) << 56), + uint64_t(a31) + (uint64_t(a30) << 8) + (uint64_t(a29) << 16) + (uint64_t(a28) << 24) + (uint64_t(a27) << 32) + (uint64_t(a26) << 40) + (uint64_t(a25) << 48) + (uint64_t(a24) << 56), + uint64_t(a39) + (uint64_t(a38) << 8) + (uint64_t(a37) << 16) + (uint64_t(a36) << 24) + (uint64_t(a35) << 32) + (uint64_t(a34) << 40) + (uint64_t(a33) << 48) + (uint64_t(a32) << 56), + uint64_t(a47) + (uint64_t(a46) << 8) + (uint64_t(a45) << 16) + (uint64_t(a44) << 24) + (uint64_t(a43) << 32) + (uint64_t(a42) << 40) + (uint64_t(a41) << 48) + (uint64_t(a40) << 56), + uint64_t(a55) + (uint64_t(a54) << 8) + (uint64_t(a53) << 16) + (uint64_t(a52) << 24) + (uint64_t(a51) << 32) + (uint64_t(a50) << 40) + (uint64_t(a49) << 48) + (uint64_t(a48) << 56), + uint64_t(a63) + (uint64_t(a62) << 8) + (uint64_t(a61) << 16) + (uint64_t(a60) << 24) + (uint64_t(a59) << 32) + (uint64_t(a58) << 40) + (uint64_t(a57) << 48) + (uint64_t(a56) << 56)); +} +#endif // SIMDJSON_GCC8 + + + +namespace simdjson { + namespace icelake { + namespace { + namespace simd { + + // Forward-declared so they can be used by splat and friends. + template + struct base { + __m512i value; + + // Zero constructor + simdjson_inline base() : value{ __m512i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m512i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m512i& () const { return this->value; } + simdjson_inline operator __m512i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm512_or_si512(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm512_and_si512(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm512_xor_si512(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm512_andnot_si512(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + // Forward-declared so they can be used by splat and friends. + template + struct simd8; + + template> + struct base8 : base> { + typedef uint32_t bitmask_t; + typedef uint64_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m512i _value) : base>(_value) {} + + friend simdjson_really_inline uint64_t operator==(const simd8 lhs, const simd8 rhs) { + return _mm512_cmpeq_epi8_mask(lhs, rhs); + } + + static const int SIZE = sizeof(base::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + // workaround for compilers unable to figure out that 16 - N is a constant (GCC 8) + constexpr int shift = 16 - N; + return _mm512_alignr_epi8(*this, _mm512_permutex2var_epi64(prev_chunk, _mm512_set_epi64(13, 12, 11, 10, 9, 8, 7, 6), *this), shift); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm512_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m512i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + simdjson_inline bool any() const { return !!_mm512_test_epi8_mask(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm512_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm512_setzero_si512(); } + static simdjson_inline simd8 load(const T values[64]) { + return _mm512_loadu_si512(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m512i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[64]) const { return _mm512_storeu_si512(reinterpret_cast<__m512i*>(dst), *this); } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm512_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm512_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm512_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 32 - count_ones(mask) bytes of the result are significant but 32 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint64_t mask, L* output) const { + _mm512_mask_compressstoreu_epi8(output, ~mask, *this); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15, + int8_t v16, int8_t v17, int8_t v18, int8_t v19, int8_t v20, int8_t v21, int8_t v22, int8_t v23, + int8_t v24, int8_t v25, int8_t v26, int8_t v27, int8_t v28, int8_t v29, int8_t v30, int8_t v31, + int8_t v32, int8_t v33, int8_t v34, int8_t v35, int8_t v36, int8_t v37, int8_t v38, int8_t v39, + int8_t v40, int8_t v41, int8_t v42, int8_t v43, int8_t v44, int8_t v45, int8_t v46, int8_t v47, + int8_t v48, int8_t v49, int8_t v50, int8_t v51, int8_t v52, int8_t v53, int8_t v54, int8_t v55, + int8_t v56, int8_t v57, int8_t v58, int8_t v59, int8_t v60, int8_t v61, int8_t v62, int8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epi8(*this, other); } + + simdjson_inline simd8 operator>(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(*this, other), _mm512_set1_epi8(uint8_t(0x80))); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm512_maskz_abs_epi8(_mm512_cmpgt_epi8_mask(other, *this), _mm512_set1_epi8(uint8_t(0x80))); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m512i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t values[64]) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15, + uint8_t v16, uint8_t v17, uint8_t v18, uint8_t v19, uint8_t v20, uint8_t v21, uint8_t v22, uint8_t v23, + uint8_t v24, uint8_t v25, uint8_t v26, uint8_t v27, uint8_t v28, uint8_t v29, uint8_t v30, uint8_t v31, + uint8_t v32, uint8_t v33, uint8_t v34, uint8_t v35, uint8_t v36, uint8_t v37, uint8_t v38, uint8_t v39, + uint8_t v40, uint8_t v41, uint8_t v42, uint8_t v43, uint8_t v44, uint8_t v45, uint8_t v46, uint8_t v47, + uint8_t v48, uint8_t v49, uint8_t v50, uint8_t v51, uint8_t v52, uint8_t v53, uint8_t v54, uint8_t v55, + uint8_t v56, uint8_t v57, uint8_t v58, uint8_t v59, uint8_t v60, uint8_t v61, uint8_t v62, uint8_t v63 + ) : simd8(_mm512_set_epi8( + v63, v62, v61, v60, v59, v58, v57, v56, + v55, v54, v53, v52, v51, v50, v49, v48, + v47, v46, v45, v44, v43, v42, v41, v40, + v39, v38, v37, v36, v35, v34, v33, v32, + v31, v30, v29, v28, v27, v26, v25, v24, + v23, v22, v21, v20, v19, v18, v17, v16, + v15, v14, v13, v12, v11, v10, v9, v8, + v7, v6, v5, v4, v3, v2, v1, v0 + )) {} + + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15, + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm512_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm512_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm512_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm512_min_epu8(other, *this); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline uint64_t operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline uint64_t operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->lt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return _mm512_mask_blend_epi8(*this == uint8_t(0), _mm512_set1_epi8(0), _mm512_set1_epi8(-1)); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + + simdjson_inline bool is_ascii() const { return _mm512_movepi8_mask(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { + return !_mm512_test_epi8_mask(*this, *this); + } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return !_mm512_test_epi8_mask(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm512_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm512_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline uint64_t get_bit() const { return _mm512_movepi8_mask(_mm512_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 1, "Icelake kernel should use one register per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1) : chunks{ chunk0, chunk1 } {} + simdjson_inline simd8x64(const simd8 chunk0) : chunks{ chunk0 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr) } {} + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(mask, output); + return 64 - count_ones(mask); + } + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + } + + simdjson_inline simd8 reduce_or() const { + return this->chunks[0]; + } + + simdjson_inline simd8x64 bit_or(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] | mask + ); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] == mask; + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return this->chunks[0] == other.chunks[0]; + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return this->chunks[0] <= mask; + } + }; // struct simd8x64 + + } // namespace simd + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_SIMD_H +/* end file simdjson/icelake/simd.h */ +/* including simdjson/icelake/stringparsing_defs.h: #include "simdjson/icelake/stringparsing_defs.h" */ +/* begin file simdjson/icelake/stringparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +#define SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/simd.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 64; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return ((quote_bits - 1) & bs_bits) != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint64_t bs_bits; + uint64_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 15 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v(src); + // store to dest unconditionally - we can overwrite the bits we don't like later + v.store(dst); + return { + static_cast(v == '\\'), // bs_bits + static_cast(v == '"'), // quote_bits + }; + } + + } // unnamed namespace + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_ICELAKE_STRINGPARSING_DEFS_H +/* end file simdjson/icelake/stringparsing_defs.h */ +/* including simdjson/icelake/numberparsing_defs.h: #include "simdjson/icelake/numberparsing_defs.h" */ +/* begin file simdjson/icelake/numberparsing_defs.h */ +#ifndef SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +#define SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace numberparsing { + + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace icelake +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_ICELAKE_NUMBERPARSING_DEFS_H +/* end file simdjson/icelake/numberparsing_defs.h */ +/* end file simdjson/icelake/begin.h */ +/* including simdjson/generic/ondemand/amalgamated.h for icelake: #include "simdjson/generic/ondemand/amalgamated.h" */ +/* begin file simdjson/generic/ondemand/amalgamated.h for icelake */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H) +#error simdjson/generic/ondemand/dependencies.h must be included before simdjson/generic/ondemand/amalgamated.h! +#endif + +// Stuff other things depend on +/* including simdjson/generic/ondemand/base.h for icelake: #include "simdjson/generic/ondemand/base.h" */ +/* begin file simdjson/generic/ondemand/base.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + /** + * A fast, simple, DOM-like interface that parses JSON as you use it. + * + * Designed for maximum speed and a lower memory profile. + */ + namespace ondemand { + + /** Represents the depth of a JSON value (number of nested arrays/objects). */ + using depth_t = int32_t; + + /** @copydoc simdjson::icelake::number_type */ + using number_type = simdjson::icelake::number_type; + + /** @private Position in the JSON buffer indexes */ + using token_position = const uint32_t*; + + class array; + class array_iterator; + class document; + class document_reference; + class document_stream; + class field; + class json_iterator; + enum class json_type; + struct number; + class object; + class object_iterator; + class parser; + class raw_json_string; + class token_iterator; + class value; + class value_iterator; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_BASE_H +/* end file simdjson/generic/ondemand/base.h for icelake */ +/* including simdjson/generic/ondemand/value_iterator.h for icelake: #include "simdjson/generic/ondemand/value_iterator.h" */ +/* begin file simdjson/generic/ondemand/value_iterator.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * Iterates through a single JSON value at a particular depth. + * + * Does not keep track of the type of value: provides methods for objects, arrays and scalars and expects + * the caller to call the right ones. + * + * @private This is not intended for external use. + */ + class value_iterator { + protected: + /** The underlying JSON iterator */ + json_iterator* _json_iter{}; + /** The depth of this value */ + depth_t _depth{}; + /** + * The starting token index for this value + */ + token_position _start_position{}; + + public: + simdjson_inline value_iterator() noexcept = default; + + /** + * Denote that we're starting a document. + */ + simdjson_inline void start_document() noexcept; + + /** + * Skips a non-iterated or partially-iterated JSON value, whether it is a scalar, array or object. + * + * Optimized for scalars. + */ + simdjson_warn_unused simdjson_inline error_code skip_child() noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is at the start of the value + */ + simdjson_inline bool at_start() const noexcept; + + /** + * Tell whether the value is open--if the value has not been used, or the array/object is still open. + */ + simdjson_inline bool is_open() const noexcept; + + /** + * Tell whether the value is at an object's first field (just after the {). + */ + simdjson_inline bool at_first_field() const noexcept; + + /** + * Abandon all iteration. + */ + simdjson_inline void abandon() noexcept; + + /** + * Get the child value as a value_iterator. + */ + simdjson_inline value_iterator child_value() const noexcept; + + /** + * Get the depth of this value. + */ + simdjson_inline int32_t depth() const noexcept; + + /** + * Get the JSON type of this value. + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() const noexcept; + + /** + * @addtogroup object Object iteration + * + * Methods to iterate and find object fields. These methods generally *assume* the value is + * actually an object; the caller is responsible for keeping track of that fact. + * + * @{ + */ + + /** + * Start an object iteration. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + */ + simdjson_warn_unused simdjson_inline simdjson_result start_object() noexcept; + /** + * Start an object iteration from the root. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_object() noexcept; + /** + * Checks whether an object could be started from the root. May be called by start_root_object. + * + * @returns SUCCESS if it is possible to safely start an object from the root (document level). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_object() noexcept; + /** + * Start an object iteration after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_object() noexcept; + /** + * Start an object iteration from the root, after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_object() noexcept; + + /** + * Moves to the next field in an object. + * + * Looks for , and }. If } is found, the object is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return whether there is another field in the object. + * @error TAPE_ERROR If there is a comma missing between fields. + * @error TAPE_ERROR If there is a comma, but not enough tokens remaining to have a key, :, and value. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_field() noexcept; + + /** + * Get the current field's key. + */ + simdjson_warn_unused simdjson_inline simdjson_result field_key() noexcept; + + /** + * Pass the : in the field and move to its value. + */ + simdjson_warn_unused simdjson_inline error_code field_value() noexcept; + + /** + * Find the next field with the given key. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline error_code find_field(const std::string_view key) noexcept; + + /** + * Find the next field with the given key, *without* unescaping. This assumes object order: it + * will not find the field if it was already passed when looking for some *other* field. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_raw(const std::string_view key) noexcept; + + /** + * Find the field with the given key without regard to order, and *without* unescaping. + * + * This is an unordered object lookup: if the field is not found initially, it will cycle around and scan from the beginning. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_unordered_raw(const std::string_view key) noexcept; + + /** @} */ + + /** + * @addtogroup array Array iteration + * Methods to iterate over array elements. These methods generally *assume* the value is actually + * an object; the caller is responsible for keeping track of that fact. + * @{ + */ + + /** + * Check for an opening [ and start an array iteration. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + */ + simdjson_warn_unused simdjson_inline simdjson_result start_array() noexcept; + /** + * Check for an opening [ and start an array iteration while at the root. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_array() noexcept; + /** + * Checks whether an array could be started from the root. May be called by start_root_array. + * + * @returns SUCCESS if it is possible to safely start an array from the root (document level). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_array() noexcept; + /** + * Start an array iteration, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_array() noexcept; + /** + * Start an array iteration from the root, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_array() noexcept; + + /** + * Moves to the next element in an array. + * + * Looks for , and ]. If ] is found, the array is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return Whether there is another element in the array. + * @error TAPE_ERROR If there is a comma missing between elements. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_element() noexcept; + + /** + * Get a child value iterator. + */ + simdjson_warn_unused simdjson_inline value_iterator child() const noexcept; + + /** @} */ + + /** + * @defgroup scalar Scalar values + * @addtogroup scalar + * @{ + */ + + simdjson_warn_unused simdjson_inline simdjson_result get_string(bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_bool() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_null() noexcept; + simdjson_warn_unused simdjson_inline bool is_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_integer() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + simdjson_warn_unused simdjson_inline simdjson_result get_root_string(bool check_trailing, bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_wobbly_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_raw_json_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_bool(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline bool is_root_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_integer(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number_type(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_null(bool check_trailing) noexcept; + + simdjson_inline error_code error() const noexcept; + simdjson_inline uint8_t*& string_buf_loc() noexcept; + simdjson_inline const json_iterator& json_iter() const noexcept; + simdjson_inline json_iterator& json_iter() noexcept; + + simdjson_inline void assert_is_valid() const noexcept; + simdjson_inline bool is_valid() const noexcept; + + /** @} */ + protected: + /** + * Restarts an array iteration. + * @returns Whether the array has any elements (returns false for empty). + */ + simdjson_inline simdjson_result reset_array() noexcept; + /** + * Restarts an object iteration. + * @returns Whether the object has any fields (returns false for empty). + */ + simdjson_inline simdjson_result reset_object() noexcept; + /** + * move_at_start(): moves us so that we are pointing at the beginning of + * the container. It updates the index so that at_start() is true and it + * syncs the depth. The user can then create a new container instance. + * + * Usage: used with value::count_elements(). + **/ + simdjson_inline void move_at_start() noexcept; + + /** + * move_at_container_start(): moves us so that we are pointing at the beginning of + * the container so that assert_at_container_start() passes. + * + * Usage: used with reset_array() and reset_object(). + **/ + simdjson_inline void move_at_container_start() noexcept; + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + simdjson_inline value_iterator(json_iterator* json_iter, depth_t depth, token_position start_index) noexcept; + + simdjson_inline simdjson_result parse_null(const uint8_t* json) const noexcept; + simdjson_inline simdjson_result parse_bool(const uint8_t* json) const noexcept; + simdjson_inline const uint8_t* peek_start() const noexcept; + simdjson_inline uint32_t peek_start_length() const noexcept; + + /** + * The general idea of the advance_... methods and the peek_* methods + * is that you first peek and check that you have desired type. If you do, + * and only if you do, then you advance. + * + * We used to unconditionally advance. But this made reasoning about our + * current state difficult. + * Suppose you always advance. Look at the 'value' matching the key + * "shadowable" in the following example... + * + * ({"globals":{"a":{"shadowable":[}}}}) + * + * If the user thinks it is a Boolean and asks for it, then we check the '[', + * decide it is not a Boolean, but still move into the next character ('}'). Now + * we are left pointing at '}' right after a '['. And we have not yet reported + * an error, only that we do not have a Boolean. + * + * If, instead, you just stand your ground until it is content that you know, then + * you will only even move beyond the '[' if the user tells you that you have an + * array. So you will be at the '}' character inside the array and, hopefully, you + * will then catch the error because an array cannot start with '}', but the code + * processing Boolean values does not know this. + * + * So the contract is: first call 'peek_...' and then call 'advance_...' only + * if you have determined that it is a type you can handle. + * + * Unfortunately, it makes the code more verbose, longer and maybe more error prone. + */ + + simdjson_inline void advance_scalar(const char* type) noexcept; + simdjson_inline void advance_root_scalar(const char* type) noexcept; + simdjson_inline void advance_non_root_scalar(const char* type) noexcept; + + simdjson_inline const uint8_t* peek_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_root_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_non_root_scalar(const char* type) noexcept; + + + simdjson_inline error_code start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept; + simdjson_inline error_code end_container() noexcept; + + /** + * Advance to a place expecting a value (increasing depth). + * + * @return The current token (the one left behind). + * @error TAPE_ERROR If the document ended early. + */ + simdjson_inline simdjson_result advance_to_value() noexcept; + + simdjson_inline error_code incorrect_type_error(const char* message) const noexcept; + simdjson_inline error_code error_unless_more_tokens(uint32_t tokens = 1) const noexcept; + + simdjson_inline bool is_at_start() const noexcept; + /** + * is_at_iterator_start() returns true on an array or object after it has just been + * created, whether the instance is empty or not. + * + * Usage: used by array::begin() in debug mode (SIMDJSON_DEVELOPMENT_CHECKS) + */ + simdjson_inline bool is_at_iterator_start() const noexcept; + + /** + * Assuming that we are within an object, this returns true if we + * are pointing at a key. + * + * Usage: the skip_child() method should never be used while we are pointing + * at a key inside an object. + */ + simdjson_inline bool is_at_key() const noexcept; + + inline void assert_at_start() const noexcept; + inline void assert_at_container_start() const noexcept; + inline void assert_at_root() const noexcept; + inline void assert_at_child() const noexcept; + inline void assert_at_next() const noexcept; + inline void assert_at_non_root_start() const noexcept; + + /** Get the starting position of this value */ + simdjson_inline token_position start_position() const noexcept; + + /** @copydoc error_code json_iterator::position() const noexcept; */ + simdjson_inline token_position position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position last_position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position end_position() const noexcept; + /** @copydoc error_code json_iterator::report_error(error_code error, const char *message) noexcept; */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + friend class document; + friend class object; + friend class array; + friend class value; + }; // value_iterator + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::value_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H +/* end file simdjson/generic/ondemand/value_iterator.h for icelake */ +/* including simdjson/generic/ondemand/value.h for icelake: #include "simdjson/generic/ondemand/value.h" */ +/* begin file simdjson/generic/ondemand/value.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * An ephemeral JSON value returned during iteration. It is only valid for as long as you do + * not access more data in the JSON document. + */ + class value { + public: + /** + * Create a new invalid value. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline value() noexcept = default; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) noexcept; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() noexcept; + + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() noexcept; + + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + + /** + * Cast this JSON value (inside string) to a unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + + /** + * Cast this JSON value to a "wobbly" string. + * + * The string is may not be a valid UTF-8 string. + * See https://simonsapin.github.io/wtf-8/ + * + * Important: a value should be consumed once. Calling get_wobbly_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); +#endif + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + * + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * Performance hint: You should only call count_elements() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method on the object instance. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @return The type of JSON value (json_type::array, json_type::object, json_type::string, + * json_type::number, json_type::boolean, or json_type::null). + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the value is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the value is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the value is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * Performance note: if you call this function systematically + * before parsing a number, you may have fallen for a performance + * anti-pattern. + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + * + * Performance note: this is designed with performance in mind. When + * calling 'get_number()', you scan the number string only once, determining + * efficiently the type and storing it in an efficient manner. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. However, if this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view is guaranteed to be + * a non-space token. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + * + * See also value::raw_json(). + */ + simdjson_inline std::string_view raw_json_token() noexcept; + + /** + * Get a string_view pointing at this value in the JSON document. + * If this element is an array or an object, it consumes the array or the object + * and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + * If this element is a scalar (string, number, Boolean, null), it returns what + * raw_json_token() would return. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + simdjson_inline simdjson_result current_location() noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. + * + * Calling at_pointer() on non-document instances (e.g., arrays and objects) is not + * standardized (by RFC 6901). We provide some experimental support for JSON pointers + * on non-document instances. Yet it is not the case when calling at_pointer on an array + * or an object instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + protected: + /** + * Create a value. + */ + simdjson_inline value(const value_iterator& iter) noexcept; + + /** + * Skip this value, allowing iteration to continue. + */ + simdjson_inline void skip() noexcept; + + /** + * Start a value at the current position. + * + * (It should already be started; this is just a self-documentation method.) + */ + static simdjson_inline value start(const value_iterator& iter) noexcept; + + /** + * Resume a value. + */ + static simdjson_inline value resume(const value_iterator& iter) noexcept; + + /** + * Get the object, starting or resuming it as necessary + */ + simdjson_inline simdjson_result start_or_resume_object() noexcept; + + // simdjson_inline void log_value(const char *type) const noexcept; + // simdjson_inline void log_error(const char *message) const noexcept; + + value_iterator iter{}; + + friend class document; + friend class array_iterator; + friend class field; + friend class object; + friend struct simdjson_result; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::value&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result get_array() noexcept; + simdjson_inline simdjson_result get_object() noexcept; + + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() noexcept; + + template simdjson_inline error_code get(T& out) noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator icelake::ondemand::array() noexcept(false); + simdjson_inline operator icelake::ondemand::object() noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator icelake::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + */ + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + + /** @copydoc simdjson_inline std::string_view value::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + /** @copydoc simdjson_inline simdjson_result current_location() noexcept */ + simdjson_inline simdjson_result current_location() noexcept; + /** @copydoc simdjson_inline int32_t current_depth() const noexcept */ + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_H +/* end file simdjson/generic/ondemand/value.h for icelake */ +/* including simdjson/generic/ondemand/logger.h for icelake: #include "simdjson/generic/ondemand/logger.h" */ +/* begin file simdjson/generic/ondemand/logger.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + // Logging should be free unless SIMDJSON_VERBOSE_LOGGING is set. Importantly, it is critical + // that the call to the log functions be side-effect free. Thus, for example, you should not + // create temporary std::string instances. + namespace logger { + + enum class log_level : int32_t { + info = 0, + error = 1 + }; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + + // We do not want these functions to be 'really inlined' since real inlining is + // for performance purposes and if you are using the loggers, you do not care about + // performance (or should not). + static inline void log_headers() noexcept; + // If args are provided, title will be treated as format string + template + static inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + template + static inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + static inline void log_event(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_value(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_start_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail = "") noexcept; + static inline void log_error(const json_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_event(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_error(const value_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + } // namespace logger + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_H +/* end file simdjson/generic/ondemand/logger.h for icelake */ +/* including simdjson/generic/ondemand/token_iterator.h for icelake: #include "simdjson/generic/ondemand/token_iterator.h" */ +/* begin file simdjson/generic/ondemand/token_iterator.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * Iterates through JSON tokens (`{` `}` `[` `]` `,` `:` `""` `123` `true` `false` `null`) + * detected by stage 1. + * + * @private This is not intended for external use. + */ + class token_iterator { + public: + /** + * Create a new invalid token_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline token_iterator() noexcept = default; + simdjson_inline token_iterator(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator& operator=(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator(const token_iterator& other) noexcept = default; + simdjson_inline token_iterator& operator=(const token_iterator& other) noexcept = default; + + /** + * Advance to the next token (returning the current one). + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + /** + * Reports the current offset in bytes from the start of the underlying buffer. + */ + simdjson_inline uint32_t current_offset() const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + + /** + * Return the current index. + */ + simdjson_inline token_position position() const noexcept; + /** + * Reset to a previously saved index. + */ + simdjson_inline void set_position(token_position target_position) noexcept; + + // NOTE: we don't support a full C++ iterator interface, because we expect people to make + // different calls to advance the iterator based on *their own* state. + + simdjson_inline bool operator==(const token_iterator& other) const noexcept; + simdjson_inline bool operator!=(const token_iterator& other) const noexcept; + simdjson_inline bool operator>(const token_iterator& other) const noexcept; + simdjson_inline bool operator>=(const token_iterator& other) const noexcept; + simdjson_inline bool operator<(const token_iterator& other) const noexcept; + simdjson_inline bool operator<=(const token_iterator& other) const noexcept; + + protected: + simdjson_inline token_iterator(const uint8_t* buf, token_position position) noexcept; + + /** + * Get the index of the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_index(int32_t delta = 0) const noexcept; + /** + * Get the index of the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline uint32_t peek_index(token_position position) const noexcept; + + const uint8_t* buf{}; + token_position _position{}; + + friend class json_iterator; + friend class value_iterator; + friend class object; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::token_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H +/* end file simdjson/generic/ondemand/token_iterator.h for icelake */ +/* including simdjson/generic/ondemand/json_iterator.h for icelake: #include "simdjson/generic/ondemand/json_iterator.h" */ +/* begin file simdjson/generic/ondemand/json_iterator.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * Iterates through JSON tokens, keeping track of depth and string buffer. + * + * @private This is not intended for external use. + */ + class json_iterator { + protected: + token_iterator token{}; + ondemand::parser* parser{}; + /** + * Next free location in the string buffer. + * + * Used by raw_json_string::unescape() to have a place to unescape strings to. + */ + uint8_t* _string_buf_loc{}; + /** + * JSON error, if there is one. + * + * INCORRECT_TYPE and NO_SUCH_FIELD are *not* stored here, ever. + * + * PERF NOTE: we *hope* this will be elided into control flow, as it is only used (a) in the first + * iteration of the loop, or (b) for the final iteration after a missing comma is found in ++. If + * this is not elided, we should make sure it's at least not using up a register. Failing that, + * we should store it in document so there's only one of them. + */ + error_code error{ SUCCESS }; + /** + * Depth of the current token in the JSON. + * + * - 0 = finished with document + * - 1 = document root value (could be [ or {, not yet known) + * - 2 = , or } inside root array/object + * - 3 = key or value inside root array/object. + */ + depth_t _depth{}; + /** + * Beginning of the document indexes. + * Normally we have root == parser->implementation->structural_indexes.get() + * but this may differ, especially in streaming mode (where we have several + * documents); + */ + token_position _root{}; + /** + * Normally, a json_iterator operates over a single document, but in + * some cases, we may have a stream of documents. This attribute is meant + * as meta-data: the json_iterator works the same irrespective of the + * value of this attribute. + */ + bool _streaming{ false }; + + public: + simdjson_inline json_iterator() noexcept = default; + simdjson_inline json_iterator(json_iterator&& other) noexcept; + simdjson_inline json_iterator& operator=(json_iterator&& other) noexcept; + simdjson_inline explicit json_iterator(const json_iterator& other) noexcept = default; + simdjson_inline json_iterator& operator=(const json_iterator& other) noexcept = default; + /** + * Skips a JSON value, whether it is a scalar, array or object. + */ + simdjson_warn_unused simdjson_inline error_code skip_child(depth_t parent_depth) noexcept; + + /** + * Tell whether the iterator is still at the start + */ + simdjson_inline bool at_root() const noexcept; + + /** + * Tell whether we should be expected to run in streaming + * mode (iterating over many documents). It is pure metadata + * that does not affect how the iterator works. It is used by + * start_root_array() and start_root_object(). + */ + simdjson_inline bool streaming() const noexcept; + + /** + * Get the root value iterator + */ + simdjson_inline token_position root_position() const noexcept; + /** + * Assert that we are at the document depth (== 1) + */ + simdjson_inline void assert_at_document_depth() const noexcept; + /** + * Assert that we are at the root of the document + */ + simdjson_inline void assert_at_root() const noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is live (has not been moved). + */ + simdjson_inline bool is_alive() const noexcept; + + /** + * Abandon this iterator, setting depth to 0 (as if the document is finished). + */ + simdjson_inline void abandon() noexcept; + + /** + * Advance the current token without modifying depth. + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + + /** + * Returns true if there is a single token in the index (i.e., it is + * a JSON with a scalar value such as a single number). + * + * @return whether there is a single token + */ + simdjson_inline bool is_single_token() const noexcept; + + /** + * Assert that there are at least the given number of tokens left. + * + * Has no effect in release builds. + */ + simdjson_inline void assert_more_tokens(uint32_t required_tokens = 1) const noexcept; + /** + * Assert that the given position addresses an actual token (is within bounds). + * + * Has no effect in release builds. + */ + simdjson_inline void assert_valid_position(token_position position) const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + /** + * Get a pointer to the current location in the input buffer. + * + * This is not null-terminated; it is a view into the JSON. + * + * You may be pointing outside of the input buffer: it is not generally + * safe to dereference this pointer. + */ + simdjson_inline const uint8_t* unsafe_pointer() const noexcept; + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token to retrieve. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token to retrieve. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + /** + * Get the JSON text for the last token in the document. + * + * This is not null-terminated; it is a view into the JSON. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek_last() const noexcept; + + /** + * Ascend one level. + * + * Validates that the depth - 1 == parent_depth. + * + * @param parent_depth the expected parent depth. + */ + simdjson_inline void ascend_to(depth_t parent_depth) noexcept; + + /** + * Descend one level. + * + * Validates that the new depth == child_depth. + * + * @param child_depth the expected child depth. + */ + simdjson_inline void descend_to(depth_t child_depth) noexcept; + simdjson_inline void descend_to(depth_t child_depth, int32_t delta) noexcept; + + /** + * Get current depth. + */ + simdjson_inline depth_t depth() const noexcept; + + /** + * Get current (writeable) location in the string buffer. + */ + simdjson_inline uint8_t*& string_buf_loc() noexcept; + + /** + * Report an unrecoverable error, preventing further iteration. + * + * @param error The error to report. Must not be SUCCESS, UNINITIALIZED, INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + /** + * Log error, but don't stop iteration. + * @param error The error to report. Must be INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code optional_error(error_code error, const char* message) noexcept; + + /** + * Take an input in json containing max_len characters and attempt to copy it over to tmpbuf, a buffer with + * N bytes of capacity. It will return false if N is too small (smaller than max_len) of if it is zero. + * The buffer (tmpbuf) is padded with space characters. + */ + simdjson_warn_unused simdjson_inline bool copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept; + + simdjson_inline token_position position() const noexcept; + /** + * Write the raw_json_string to the string buffer and return a string_view. + * Each raw_json_string should be unescaped once, or else the string buffer might + * overflow. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, bool allow_replacement) noexcept; + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in) noexcept; + + simdjson_inline void reenter_child(token_position position, depth_t child_depth) noexcept; + + simdjson_inline error_code consume_character(char c) noexcept; +#if SIMDJSON_DEVELOPMENT_CHECKS + simdjson_inline token_position start_position(depth_t depth) const noexcept; + simdjson_inline void set_start_position(depth_t depth, token_position position) noexcept; +#endif + + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Updates this json iterator so that it is back at the beginning of the document, + * as if it had just been created. + */ + inline void rewind() noexcept; + /** + * This checks whether the {,},[,] are balanced so that the document + * ends with proper zero depth. This requires scanning the whole document + * and it may be expensive. It is expected that it will be rarely called. + * It does not attempt to match { with } and [ with ]. + */ + inline bool balanced() const noexcept; + protected: + simdjson_inline json_iterator(const uint8_t* buf, ondemand::parser* parser) noexcept; + /// The last token before the end + simdjson_inline token_position last_position() const noexcept; + /// The token *at* the end. This points at gibberish and should only be used for comparison. + simdjson_inline token_position end_position() const noexcept; + /// The end of the buffer. + simdjson_inline token_position end() const noexcept; + + friend class document; + friend class document_stream; + friend class object; + friend class array; + friend class value; + friend class raw_json_string; + friend class parser; + friend class value_iterator; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; // json_iterator + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::json_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H +/* end file simdjson/generic/ondemand/json_iterator.h for icelake */ +/* including simdjson/generic/ondemand/json_type.h for icelake: #include "simdjson/generic/ondemand/json_type.h" */ +/* begin file simdjson/generic/ondemand/json_type.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * The type of a JSON value. + */ + enum class json_type { + // Start at 1 to catch uninitialized / default values more easily + array = 1, ///< A JSON array ( [ 1, 2, 3 ... ] ) + object, ///< A JSON object ( { "a": 1, "b" 2, ... } ) + number, ///< A JSON number ( 1 or -2.3 or 4.5e6 ...) + string, ///< A JSON string ( "a" or "hello world\n" ...) + boolean, ///< A JSON boolean (true or false) + null ///< A JSON null (null) + }; + + /** + * A type representing a JSON number. + * The design of the struct is deliberately straight-forward. All + * functions return standard values with no error check. + */ + struct number { + + /** + * return the automatically determined type of + * the number: number_type::floating_point_number, + * number_type::signed_integer or number_type::unsigned_integer. + * + * enum class number_type { + * floating_point_number=1, /// a binary64 number + * signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + * unsigned_integer /// a positive integer larger or equal to 1<<63 + * }; + */ + simdjson_inline ondemand::number_type get_number_type() const noexcept; + /** + * return true if the automatically determined type of + * the number is number_type::unsigned_integer. + */ + simdjson_inline bool is_uint64() const noexcept; + /** + * return the value as a uint64_t, only valid if is_uint64() is true. + */ + simdjson_inline uint64_t get_uint64() const noexcept; + simdjson_inline operator uint64_t() const noexcept; + + /** + * return true if the automatically determined type of + * the number is number_type::signed_integer. + */ + simdjson_inline bool is_int64() const noexcept; + /** + * return the value as a int64_t, only valid if is_int64() is true. + */ + simdjson_inline int64_t get_int64() const noexcept; + simdjson_inline operator int64_t() const noexcept; + + + /** + * return true if the automatically determined type of + * the number is number_type::floating_point_number. + */ + simdjson_inline bool is_double() const noexcept; + /** + * return the value as a double, only valid if is_double() is true. + */ + simdjson_inline double get_double() const noexcept; + simdjson_inline operator double() const noexcept; + + /** + * Convert the number to a double. Though it always succeed, the conversion + * may be lossy if the number cannot be represented exactly. + */ + simdjson_inline double as_double() const noexcept; + + + protected: + /** + * The next block of declaration is designed so that we can call the number parsing + * functions on a number type. They are protected and should never be used outside + * of the core simdjson library. + */ + friend class value_iterator; + template + friend error_code numberparsing::slow_float_parsing(simdjson_unused const uint8_t* src, W writer); + template + friend error_code numberparsing::write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer); + template + friend error_code numberparsing::parse_number(const uint8_t* const src, W& writer); + /** Store a signed 64-bit value to the number. */ + simdjson_inline void append_s64(int64_t value) noexcept; + /** Store an unsigned 64-bit value to the number. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + /** Store a double value to the number. */ + simdjson_inline void append_double(double value) noexcept; + /** Specifies that the value is a double, but leave it undefined. */ + simdjson_inline void skip_double() noexcept; + /** + * End of friend declarations. + */ + + /** + * Our attributes are a union type (size = 64 bits) + * followed by a type indicator. + */ + union { + double floating_point_number; + int64_t signed_integer; + uint64_t unsigned_integer; + } payload{ 0 }; + number_type type{ number_type::signed_integer }; + }; + + /** + * Write the JSON type to the output stream + * + * @param out The output stream. + * @param type The json_type. + */ + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Send JSON type to an output stream. + * + * @param out The output stream. + * @param type The json_type. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false); +#endif + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::json_type&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H +/* end file simdjson/generic/ondemand/json_type.h for icelake */ +/* including simdjson/generic/ondemand/raw_json_string.h for icelake: #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * A string escaped per JSON rules, terminated with quote ("). They are used to represent + * unescaped keys inside JSON documents. + * + * (In other words, a pointer to the beginning of a string, just after the start quote, inside a + * JSON file.) + * + * This class is deliberately simplistic and has little functionality. You can + * compare a raw_json_string instance with an unescaped C string, but + * that is nearly all you can do. + * + * The raw_json_string is unescaped. If you wish to write an unescaped version of it to your own + * buffer, you may do so using the parser.unescape(string, buff) method, using an ondemand::parser + * instance. Doing so requires you to have a sufficiently large buffer. + * + * The raw_json_string instances originate typically from field instance which in turn represent + * key-value pairs from object instances. From a field instance, you get the raw_json_string + * instance by calling key(). You can, if you want a more usable string_view instance, call + * the unescaped_key() method on the field instance. You may also create a raw_json_string from + * any other string value, with the value.get_raw_json_string() method. Again, you can get + * a more usable string_view instance by calling get_string(). + * + */ + class raw_json_string { + public: + /** + * Create a new invalid raw_json_string. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline raw_json_string() noexcept = default; + + /** + * Create a new invalid raw_json_string pointed at the given location in the JSON. + * + * The given location must be just *after* the beginning quote (") in the JSON file. + * + * It *must* be terminated by a ", and be a valid JSON string. + */ + simdjson_inline raw_json_string(const uint8_t* _buf) noexcept; + /** + * Get the raw pointer to the beginning of the string in the JSON (just after the "). + * + * It is possible for this function to return a null pointer if the instance + * has outlived its existence. + */ + simdjson_inline const char* raw() const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done) on target.size() characters, + * and if the raw_json_string instance has a quote character at byte index target.size(). + * We never read more than length + 1 bytes in the raw_json_string instance. + * If length is smaller than target.size(), this will return false. + * + * The std::string_view instance may contain any characters. However, the caller + * is responsible for setting length so that length bytes may be read in the + * raw_json_string. + * + * Performance: the comparison may be done using memcmp which may be efficient + * for long strings. + */ + simdjson_inline bool unsafe_is_equal(size_t length, std::string_view target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The std::string_view instance should not contain unescaped quote characters: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * Performance: the comparison is done byte-by-byte which might be inefficient for + * long strings. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The provided C string should not contain an unescaped quote character: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(const char* target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(const char* target) const noexcept; + + /** + * Returns true if target is free from unescaped quote. If target is known at + * compile-time, we might expect the computation to happen at compile time with + * many compilers (not all!). + */ + static simdjson_inline bool is_free_from_unescaped_quote(std::string_view target) noexcept; + static simdjson_inline bool is_free_from_unescaped_quote(const char* target) noexcept; + + private: + + + /** + * This will set the inner pointer to zero, effectively making + * this instance unusable. + */ + simdjson_inline void consume() noexcept { buf = nullptr; } + + /** + * Checks whether the inner pointer is non-null and thus usable. + */ + simdjson_inline simdjson_warn_unused bool alive() const noexcept { return buf != nullptr; } + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result will be a valid UTF-8. + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + * @param allow_replacement Whether we allow replacement of invalid surrogate pairs. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape(json_iterator& iter, bool allow_replacement) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result may not be a valid UTF-8. https://simonsapin.github.io/wtf-8/ + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(json_iterator& iter) const noexcept; + const uint8_t* buf{}; + friend class object; + friend class field; + friend class parser; + friend struct simdjson_result; + }; + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream&, const raw_json_string&) noexcept; + + /** + * Comparisons between raw_json_string and std::string_view instances are potentially unsafe: the user is responsible + * for providing a string with no unescaped quote. Note that unescaped quotes cannot be present in valid JSON strings. + */ + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept; + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept; + + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::raw_json_string&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + + simdjson_inline simdjson_result raw() const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape(icelake::ondemand::json_iterator& iter, bool allow_replacement) const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(icelake::ondemand::json_iterator& iter) const noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H +/* end file simdjson/generic/ondemand/raw_json_string.h for icelake */ +/* including simdjson/generic/ondemand/parser.h for icelake: #include "simdjson/generic/ondemand/parser.h" */ +/* begin file simdjson/generic/ondemand/parser.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * The default batch size for document_stream instances for this On Demand kernel. + * Note that different On Demand kernel may use a different DEFAULT_BATCH_SIZE value + * in the future. + */ + static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; + /** + * Some adversary might try to set the batch size to 0 or 1, which might cause problems. + * We set a minimum of 32B since anything else is highly likely to be an error. In practice, + * most users will want a much larger batch size. + * + * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON + * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. + */ + static constexpr size_t MINIMAL_BATCH_SIZE = 32; + + /** + * A JSON fragment iterator. + * + * This holds the actual iterator as well as the buffer for writing strings. + */ + class parser { + public: + /** + * Create a JSON parser. + * + * The new parser will have zero capacity. + */ + inline explicit parser(size_t max_capacity = SIMDJSON_MAXSIZE_BYTES) noexcept; + + inline parser(parser&& other) noexcept = default; + simdjson_inline parser(const parser& other) = delete; + simdjson_inline parser& operator=(const parser& other) = delete; + simdjson_inline parser& operator=(parser&& other) noexcept = default; + + /** Deallocate the JSON parser. */ + inline ~parser() noexcept = default; + + /** + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * document doc = parser.iterate(json); + * + * It is expected that the content is a valid UTF-8 file, containing a valid JSON document. + * Otherwise the iterate method may return an error. In particular, the whole input should be + * valid: we do not attempt to tolerate incorrect content either before or after a JSON + * document. If there is a UTF-8 BOM, the parser skips it. + * + * ### IMPORTANT: Validate what you use + * + * Calling iterate on an invalid JSON document may not immediately trigger an error. The call to + * iterate does not parse and validate the whole document. + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * @param len The length of the JSON. + * @param capacity The number of bytes allocated in the JSON (must be at least len+SIMDJSON_PADDING). + * + * @return The document, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate(padded_string_view json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const char* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const uint8_t* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string_view json, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(padded_string&& json) & noexcept = delete; + + /** + * @private + * + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * json_iterator doc = parser.iterate(json); + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * The ondemand::document instance holds the iterator. The document must remain in scope + * while you are accessing instances of ondemand::value, ondemand::object, ondemand::array. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * + * @return The iterator, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate_raw(padded_string_view json) & noexcept; + + + /** + * Parse a buffer containing many JSON documents. + * + * auto json = R"({ "foo": 1 } { "foo": 2 } { "foo": 3 } )"_padded; + * ondemand::parser parser; + * ondemand::document_stream docs = parser.iterate_many(json); + * for (auto & doc : docs) { + * std::cout << doc["foo"] << std::endl; + * } + * // Prints 1 2 3 + * + * No copy of the input buffer is made. + * + * The function is lazy: it may be that no more than one JSON document at a time is parsed. + * + * The caller is responsabile to ensure that the input string data remains unchanged and is + * not deleted during the loop. + * + * ### Format + * + * The buffer must contain a series of one or more JSON documents, concatenated into a single + * buffer, separated by ASCII whitespace. It effectively parses until it has a fully valid document, + * then starts parsing the next document at that point. (It does this with more parallelism and + * lookahead than you might think, though.) + * + * documents that consist of an object or array may omit the whitespace between them, concatenating + * with no separator. Documents that consist of a single primitive (i.e. documents that are not + * arrays or objects) MUST be separated with ASCII whitespace. + * + * The characters inside a JSON document, and between JSON documents, must be valid Unicode (UTF-8). + * If there is a UTF-8 BOM, the parser skips it. + * + * The documents must not exceed batch_size bytes (by default 1MB) or they will fail to parse. + * Setting batch_size to excessively large or excessively small values may impact negatively the + * performance. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * ### Threads + * + * When compiled with SIMDJSON_THREADS_ENABLED, this method will use a single thread under the + * hood to do some lookahead. + * + * ### Parser Capacity + * + * If the parser's current capacity is less than batch_size, it will allocate enough capacity + * to handle it (up to max_capacity). + * + * @param buf The concatenated JSON to parse. + * @param len The length of the concatenated JSON. + * @param batch_size The batch size to use. MUST be larger than the largest document. The sweet + * spot is cache-related: small enough to fit in cache, yet big enough to + * parse as many documents as possible in one tight loop. + * Defaults to 10MB, which has been a reasonable sweet spot in our tests. + * @param allow_comma_separated (defaults on false) This allows a mode where the documents are + * separated by commas instead of whitespace. It comes with a performance + * penalty because the entire document is indexed at once (and the document must be + * less than 4 GB), and there is no multithreading. In this mode, the batch_size parameter + * is effectively ignored, as it is set to at least the document size. + * @return The stream, or an error. An empty input will yield 0 documents rather than an EMPTY error. Errors: + * - MEMALLOC if the parser does not have enough capacity and memory allocation fails + * - CAPACITY if the parser does not have enough capacity and batch_size > max_capacity. + * - other json errors if parsing fails. You should not rely on these errors to always the same for the + * same document: they may vary under runtime dispatch (so they may vary depending on your system and hardware). + */ + inline simdjson_result iterate_many(const uint8_t* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const char* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const std::string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const std::string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const padded_string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const padded_string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + + /** @private We do not want to allow implicit conversion from C string to std::string. */ + simdjson_result iterate_many(const char* buf, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept = delete; + + /** The capacity of this parser (the largest document it can process). */ + simdjson_inline size_t capacity() const noexcept; + /** The maximum capacity of this parser (the largest document it is allowed to process). */ + simdjson_inline size_t max_capacity() const noexcept; + simdjson_inline void set_max_capacity(size_t max_capacity) noexcept; + /** + * The maximum depth of this parser (the most deeply nested objects and arrays it can process). + * This parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + */ + simdjson_inline size_t max_depth() const noexcept; + + /** + * Ensure this parser has enough memory to process JSON documents up to `capacity` bytes in length + * and `max_depth` depth. + * + * The max_depth parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. Defaults to DEFAULT_MAX_DEPTH. + * @return The error, if there is one. + */ + simdjson_warn_unused error_code allocate(size_t capacity, size_t max_depth = DEFAULT_MAX_DEPTH) noexcept; + +#ifdef SIMDJSON_THREADS_ENABLED + /** + * The parser instance can use threads when they are available to speed up some + * operations. It is enabled by default. Changing this attribute will change the + * behavior of the parser for future operations. + */ + bool threaded{ true }; +#endif + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result must be valid UTF-8. + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @param allow_replacement Whether we allow a replacement if the input string contains unmatched surrogate pairs. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement = false) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result may not be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept; + + private: + /** @private [for benchmarking access] The implementation to use */ + std::unique_ptr implementation{}; + size_t _capacity{ 0 }; + size_t _max_capacity; + size_t _max_depth{ DEFAULT_MAX_DEPTH }; + std::unique_ptr string_buf{}; +#if SIMDJSON_DEVELOPMENT_CHECKS + std::unique_ptr start_positions{}; +#endif + + friend class json_iterator; + friend class document_stream; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::parser&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_H +/* end file simdjson/generic/ondemand/parser.h for icelake */ + +// All other declarations +/* including simdjson/generic/ondemand/array.h for icelake: #include "simdjson/generic/ondemand/array.h" */ +/* begin file simdjson/generic/ondemand/array.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * A forward-only JSON array. + */ + class array { + public: + /** + * Create a new invalid array. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline array() noexcept = default; + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an array is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the beginning of the array and checks whether the + * array is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result is_empty() & noexcept; + /** + * Reset the iterator so that we are pointing back at the + * beginning of the array. You should still consume values only once even if you + * can iterate through the array more than once. If you unescape a string + * within the array more than once, you have unsafe code. Note that rewinding + * an array means that you may need to reparse it anew: it is not a free + * operation. + * + * @returns true if the array contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"([ { "foo": { "a": [ 10, 20, 30 ] }} ])"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/0/foo/a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an array + * instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the array and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Get the value at the given index. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + protected: + /** + * Go to the end of the array, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + + /** + * Begin array iteration. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + */ + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + /** + * Begin array iteration from the root. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + * @error TAPE_ERROR if there is no closing ] at the end of the document. + */ + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + /** + * Begin array iteration. + * + * This version of the method should be called after the initial [ has been verified, and is + * intended for use by switch statements that check the type of a value. + * + * @param iter The iterator. Must be after the initial [. Will be *moved* into the resulting array. + */ + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + + /** + * Create an array at the given Internal array creation. Call array::start() or array::started() instead of this. + * + * @param iter The iterator. Must either be at the start of the first element with iter.is_alive() + * == true, or past the [] with is_alive() == false if the array is empty. Will be *moved* + * into the resulting array. + */ + simdjson_inline array(const value_iterator& iter) noexcept; + + /** + * Iterator marking current position. + * + * iter.is_alive() == false indicates iteration is complete. + */ + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + friend struct simdjson_result; + friend class array_iterator; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::array&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + inline simdjson_result count_elements() & noexcept; + inline simdjson_result is_empty() & noexcept; + inline simdjson_result reset() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_H +/* end file simdjson/generic/ondemand/array.h for icelake */ +/* including simdjson/generic/ondemand/array_iterator.h for icelake: #include "simdjson/generic/ondemand/array_iterator.h" */ +/* begin file simdjson/generic/ondemand/array_iterator.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * A forward-only JSON array. + * + * This is an input_iterator, meaning: + * - It is forward-only + * - * must be called exactly once per element. + * - ++ must be called exactly once in between each * (*, ++, *, ++, * ...) + */ + class array_iterator { + public: + /** Create a new, invalid array iterator. */ + simdjson_inline array_iterator() noexcept = default; + + // + // Iterator interface + // + + /** + * Get the current element. + * + * Part of the std::iterator interface. + */ + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + /** + * Check if we are at the end of the JSON. + * + * Part of the std::iterator interface. + * + * @return true if there are no more elements in the JSON array. + */ + simdjson_inline bool operator==(const array_iterator&) const noexcept; + /** + * Check if there are more elements in the JSON array. + * + * Part of the std::iterator interface. + * + * @return true if there are more elements in the JSON array. + */ + simdjson_inline bool operator!=(const array_iterator&) const noexcept; + /** + * Move to the next element. + * + * Part of the std::iterator interface. + */ + simdjson_inline array_iterator& operator++() noexcept; + + private: + value_iterator iter{}; + + simdjson_inline array_iterator(const value_iterator& iter) noexcept; + + friend class array; + friend class value; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::array_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H +/* end file simdjson/generic/ondemand/array_iterator.h for icelake */ +/* including simdjson/generic/ondemand/document.h for icelake: #include "simdjson/generic/ondemand/document.h" */ +/* begin file simdjson/generic/ondemand/document.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * A JSON document. It holds a json_iterator instance. + * + * Used by tokens to get text, and string buffer location. + * + * You must keep the document around during iteration. + */ + class document { + public: + /** + * Create a new invalid document. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline document() noexcept = default; + simdjson_inline document(const document& other) noexcept = delete; // pass your documents by reference, not by copy + simdjson_inline document(document&& other) noexcept = default; + simdjson_inline document& operator=(const document& other) noexcept = delete; + simdjson_inline document& operator=(document&& other) noexcept = default; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() & noexcept; + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() & noexcept; + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + /** + * Cast this JSON value (inside string) to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: Calling get_string() twice on the same document is an error. + * + * @param Whether to allow a replacement character for unmatched surrogate pairs. + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + /** + * Cast this JSON value to a string. + * + * The string is not guaranteed to be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * + * Important: Calling get_wobbly_string() twice on the same document is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is set to 1 (which is the case when building in Debug mode + * by default), and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value if a JSON array or object cannot be found. + * @returns SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result get_value() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() & noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + /** @overload template simdjson_result get() & noexcept */ + template simdjson_inline simdjson_result get() && noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool, value + * + * Be mindful that the document instance must remain in scope while you are accessing object, array and value instances. + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) & noexcept; + /** @overload template error_code get(T &out) & noexcept */ + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() & noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() & noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is defined, and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value value if a JSON array or object cannot be found. + * @exception SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline operator value() noexcept(false); +#endif + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) & noexcept; + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to + * a key a single time. Doing object["mykey"].to_string()and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the document is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the document is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the document is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. If this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view may be the padded buffer. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + /** + * Reset the iterator inside the document instance so we are pointing back at the + * beginning of the document, as if it had just been created. It invalidates all + * values, objects and arrays that you have created so far (including unescaped strings). + */ + inline void rewind() noexcept; + /** + * Returns debugging information. + */ + inline std::string to_debug_string() noexcept; + /** + * Some unrecoverable error conditions may render the document instance unusable. + * The is_alive() method returns true when the document is still suitable. + */ + inline bool is_alive() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Returns true if this document has been fully parsed. + * If you have consumed the whole document and at_end() returns + * false, then there may be trailing content. + */ + inline bool at_end() const noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() automatically calls rewind between each call. Thus + * all values, objects and arrays that you have created so far (including unescaped strings) + * are invalidated. After calling at_pointer, you need to consume the result: string values + * should be stored in your own variables, arrays should be decoded and stored in your own array-like + * structures and so forth. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + * - SCALAR_DOCUMENT_AS_VALUE if the json_pointer is empty and the document is not a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the document and returns a string_view instance corresponding to the + * document as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + protected: + /** + * Consumes the document. + */ + simdjson_inline error_code consume() noexcept; + + simdjson_inline document(ondemand::json_iterator&& iter) noexcept; + simdjson_inline const uint8_t* text(uint32_t idx) const noexcept; + + simdjson_inline value_iterator resume_value_iterator() noexcept; + simdjson_inline value_iterator get_root_value_iterator() noexcept; + simdjson_inline simdjson_result start_or_resume_object() noexcept; + static simdjson_inline document start(ondemand::json_iterator&& iter) noexcept; + + // + // Fields + // + json_iterator iter{}; ///< Current position in the document + static constexpr depth_t DOCUMENT_DEPTH = 0; ///< document depth is always 0 + + friend class array_iterator; + friend class value; + friend class ondemand::parser; + friend class object; + friend class array; + friend class field; + friend class token; + friend class document_stream; + friend class document_reference; + }; + + + /** + * A document_reference is a thin wrapper around a document reference instance. + */ + class document_reference { + public: + simdjson_inline document_reference() noexcept; + simdjson_inline document_reference(document& d) noexcept; + simdjson_inline document_reference(const document_reference& other) noexcept = default; + simdjson_inline document_reference& operator=(const document_reference& other) noexcept = default; + simdjson_inline void rewind() noexcept; + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + + simdjson_inline simdjson_result is_null() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + simdjson_inline operator document& () const noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator array() & noexcept(false); + simdjson_inline operator object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + private: + document* doc{ nullptr }; + }; + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::document&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() & noexcept; + template simdjson_inline simdjson_result get() && noexcept; + + template simdjson_inline error_code get(T& out) & noexcept; + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator icelake::ondemand::array() & noexcept(false); + simdjson_inline operator icelake::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator icelake::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator icelake::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool at_end() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + + + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::document_reference value, error_code error) noexcept; + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator icelake::ondemand::array() & noexcept(false); + simdjson_inline operator icelake::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator icelake::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator icelake::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document_reference::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H +/* end file simdjson/generic/ondemand/document.h for icelake */ +/* including simdjson/generic/ondemand/document_stream.h for icelake: #include "simdjson/generic/ondemand/document_stream.h" */ +/* begin file simdjson/generic/ondemand/document_stream.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#ifdef SIMDJSON_THREADS_ENABLED +#include +#include +#include +#endif + +namespace simdjson { + namespace icelake { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + /** @private Custom worker class **/ + struct stage1_worker { + stage1_worker() noexcept = default; + stage1_worker(const stage1_worker&) = delete; + stage1_worker(stage1_worker&&) = delete; + stage1_worker operator=(const stage1_worker&) = delete; + ~stage1_worker(); + /** + * We only start the thread when it is needed, not at object construction, this may throw. + * You should only call this once. + **/ + void start_thread(); + /** + * Start a stage 1 job. You should first call 'run', then 'finish'. + * You must call start_thread once before. + */ + void run(document_stream* ds, parser* stage1, size_t next_batch_start); + /** Wait for the run to finish (blocking). You should first call 'run', then 'finish'. **/ + void finish(); + + private: + + /** + * Normally, we would never stop the thread. But we do in the destructor. + * This function is only safe assuming that you are not waiting for results. You + * should have called run, then finish, and be done. + **/ + void stop_thread(); + + std::thread thread{}; + /** These three variables define the work done by the thread. **/ + ondemand::parser* stage1_thread_parser{}; + size_t _next_batch_start{}; + document_stream* owner{}; + /** + * We have two state variables. This could be streamlined to one variable in the future but + * we use two for clarity. + */ + bool has_work{ false }; + bool can_work{ true }; + + /** + * We lock using a mutex. + */ + std::mutex locking_mutex{}; + std::condition_variable cond_var{}; + + friend class document_stream; + }; +#endif // SIMDJSON_THREADS_ENABLED + + /** + * A forward-only stream of documents. + * + * Produced by parser::iterate_many. + * + */ + class document_stream { + public: + /** + * Construct an uninitialized document_stream. + * + * ```c++ + * document_stream docs; + * auto error = parser.iterate_many(json).get(docs); + * ``` + */ + simdjson_inline document_stream() noexcept; + /** Move one document_stream to another. */ + simdjson_inline document_stream(document_stream&& other) noexcept = default; + /** Move one document_stream to another. */ + simdjson_inline document_stream& operator=(document_stream&& other) noexcept = default; + + simdjson_inline ~document_stream() noexcept; + + /** + * Returns the input size in bytes. + */ + inline size_t size_in_bytes() const noexcept; + + /** + * After iterating through the stream, this method + * returns the number of bytes that were not parsed at the end + * of the stream. If truncated_bytes() differs from zero, + * then the input was truncated maybe because incomplete JSON + * documents were found at the end of the stream. You + * may need to process the bytes in the interval [size_in_bytes()-truncated_bytes(), size_in_bytes()). + * + * You should only call truncated_bytes() after streaming through all + * documents, like so: + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto & doc : stream) { + * // do something with doc + * } + * size_t truncated = stream.truncated_bytes(); + * + */ + inline size_t truncated_bytes() const noexcept; + + class iterator { + public: + using value_type = simdjson_result; + using reference = value_type; + + using difference_type = std::ptrdiff_t; + + using iterator_category = std::input_iterator_tag; + + /** + * Default constructor. + */ + simdjson_inline iterator() noexcept; + /** + * Get the current document (or error). + */ + simdjson_inline simdjson_result operator*() noexcept; + /** + * Advance to the next document (prefix). + */ + inline iterator& operator++() noexcept; + /** + * Check if we're at the end yet. + * @param other the end iterator to compare to. + */ + simdjson_inline bool operator!=(const iterator& other) const noexcept; + /** + * @private + * + * Gives the current index in the input document in bytes. + * + * document_stream stream = parser.parse_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * auto doc = *i; + * size_t index = i.current_index(); + * } + * + * This function (current_index()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + */ + simdjson_inline size_t current_index() const noexcept; + + /** + * @private + * + * Gives a view of the current document at the current position. + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * std::string_view v = i.source(); + * } + * + * The returned string_view instance is simply a map to the (unparsed) + * source string: it may thus include white-space characters and all manner + * of padding. + * + * This function (source()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + * + */ + simdjson_inline std::string_view source() const noexcept; + + /** + * Returns error of the stream (if any). + */ + inline error_code error() const noexcept; + + private: + simdjson_inline iterator(document_stream* s, bool finished) noexcept; + /** The document_stream we're iterating through. */ + document_stream* stream; + /** Whether we're finished or not. */ + bool finished; + + friend class document; + friend class document_stream; + friend class json_iterator; + }; + + /** + * Start iterating the documents in the stream. + */ + simdjson_inline iterator begin() noexcept; + /** + * The end of the stream, for iterator comparison purposes. + */ + simdjson_inline iterator end() noexcept; + + private: + + document_stream& operator=(const document_stream&) = delete; // Disallow copying + document_stream(const document_stream& other) = delete; // Disallow copying + + /** + * Construct a document_stream. Does not allocate or parse anything until the iterator is + * used. + * + * @param parser is a reference to the parser instance used to generate this document_stream + * @param buf is the raw byte buffer we need to process + * @param len is the length of the raw byte buffer in bytes + * @param batch_size is the size of the windows (must be strictly greater or equal to the largest JSON document) + */ + simdjson_inline document_stream( + ondemand::parser& parser, + const uint8_t* buf, + size_t len, + size_t batch_size, + bool allow_comma_separated + ) noexcept; + + /** + * Parse the first document in the buffer. Used by begin(), to handle allocation and + * initialization. + */ + inline void start() noexcept; + + /** + * Parse the next document found in the buffer previously given to document_stream. + * + * The content should be a valid JSON document encoded as UTF-8. If there is a + * UTF-8 BOM, the parser skips it. + * + * You do NOT need to pre-allocate a parser. This function takes care of + * pre-allocating a capacity defined by the batch_size defined when creating the + * document_stream object. + * + * The function returns simdjson::EMPTY if there is no more data to be parsed. + * + * The function returns simdjson::SUCCESS (as integer = 0) in case of success + * and indicates that the buffer has successfully been parsed to the end. + * Every document it contained has been parsed without error. + * + * The function returns an error code from simdjson/simdjson.h in case of failure + * such as simdjson::CAPACITY, simdjson::MEMALLOC, simdjson::DEPTH_ERROR and so forth; + * the simdjson::error_message function converts these error codes into a string). + * + * You can also check validity by calling parser.is_valid(). The same parser can + * and should be reused for the other documents in the buffer. + */ + inline void next() noexcept; + + /** Move the json_iterator of the document to the location of the next document in the stream. */ + inline void next_document() noexcept; + + /** Get the next document index. */ + inline size_t next_batch_start() const noexcept; + + /** Pass the next batch through stage 1 with the given parser. */ + inline error_code run_stage1(ondemand::parser& p, size_t batch_start) noexcept; + + // Fields + ondemand::parser* parser; + const uint8_t* buf; + size_t len; + size_t batch_size; + bool allow_comma_separated; + /** + * We are going to use just one document instance. The document owns + * the json_iterator. It implies that we only ever pass a reference + * to the document to the users. + */ + document doc{}; + /** The error (or lack thereof) from the current document. */ + error_code error; + size_t batch_start{ 0 }; + size_t doc_index{}; + +#ifdef SIMDJSON_THREADS_ENABLED + /** Indicates whether we use threads. Note that this needs to be a constant during the execution of the parsing. */ + bool use_thread; + + inline void load_from_stage1_thread() noexcept; + + /** Start a thread to run stage 1 on the next batch. */ + inline void start_stage1_thread() noexcept; + + /** Wait for the stage 1 thread to finish and capture the results. */ + inline void finish_stage1_thread() noexcept; + + /** The error returned from the stage 1 thread. */ + error_code stage1_thread_error{ UNINITIALIZED }; + /** The thread used to run stage 1 against the next batch in the background. */ + std::unique_ptr worker{ new(std::nothrow) stage1_worker() }; + /** + * The parser used to run stage 1 in the background. Will be swapped + * with the regular parser when finished. + */ + ondemand::parser stage1_thread_parser{}; + + friend struct stage1_worker; +#endif // SIMDJSON_THREADS_ENABLED + + friend class parser; + friend class document; + friend class json_iterator; + friend struct simdjson_result; + friend struct internal::simdjson_result_base; + }; // document_stream + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::document_stream&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H +/* end file simdjson/generic/ondemand/document_stream.h for icelake */ +/* including simdjson/generic/ondemand/field.h for icelake: #include "simdjson/generic/ondemand/field.h" */ +/* begin file simdjson/generic/ondemand/field.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * A JSON field (key/value pair) in an object. + * + * Returned from object iteration. + * + * Extends from std::pair so you can use C++ algorithms that rely on pairs. + */ + class field : public std::pair { + public: + /** + * Create a new invalid field. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline field() noexcept; + + /** + * Get the key as a string_view (for higher speed, consider raw_key). + * We deliberately use a more cumbersome name (unescaped_key) to force users + * to think twice about using it. + * + * This consumes the key: once you have called unescaped_key(), you cannot + * call it again nor can you call key(). + */ + simdjson_inline simdjson_warn_unused simdjson_result unescaped_key(bool allow_replacement) noexcept; + /** + * Get the key as a raw_json_string. Can be used for direct comparison with + * an unescaped C string: e.g., key() == "test". + */ + simdjson_inline raw_json_string key() const noexcept; + /** + * Get the field value. + */ + simdjson_inline ondemand::value& value() & noexcept; + /** + * @overload ondemand::value &ondemand::value() & noexcept + */ + simdjson_inline ondemand::value value() && noexcept; + + protected: + simdjson_inline field(raw_json_string key, ondemand::value&& value) noexcept; + static simdjson_inline simdjson_result start(value_iterator& parent_iter) noexcept; + static simdjson_inline simdjson_result start(const value_iterator& parent_iter, raw_json_string key) noexcept; + friend struct simdjson_result; + friend class object_iterator; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::field&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result unescaped_key(bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result key() noexcept; + simdjson_inline simdjson_result value() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_H +/* end file simdjson/generic/ondemand/field.h for icelake */ +/* including simdjson/generic/ondemand/object.h for icelake: #include "simdjson/generic/ondemand/object.h" */ +/* begin file simdjson/generic/ondemand/object.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * A forward-only JSON object field iterator. + */ + class object { + public: + /** + * Create a new invalid object. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a + * key a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an object + * instance: there is no rewind and no invalidation. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + /** + * Reset the iterator so that we are pointing back at the + * beginning of the object. You should still consume values only once even if you + * can iterate through the object more than once. If you unescape a string within + * the object more than once, you have unsafe code. Note that rewinding an object + * means that you may need to reparse it anew: it is not a free operation. + * + * @returns true if the object contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * This method scans the beginning of the object and checks whether the + * object is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + inline simdjson_result is_empty() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Consumes the object and returns a string_view instance corresponding to the + * object as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + protected: + /** + * Go to the end of the object, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + static simdjson_inline object resume(const value_iterator& iter) noexcept; + simdjson_inline object(const value_iterator& iter) noexcept; + + simdjson_warn_unused simdjson_inline error_code find_field_raw(const std::string_view key) noexcept; + + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::object&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + inline simdjson_result reset() noexcept; + inline simdjson_result is_empty() noexcept; + inline simdjson_result count_fields() & noexcept; + inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_H +/* end file simdjson/generic/ondemand/object.h for icelake */ +/* including simdjson/generic/ondemand/object_iterator.h for icelake: #include "simdjson/generic/ondemand/object_iterator.h" */ +/* begin file simdjson/generic/ondemand/object_iterator.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + class object_iterator { + public: + /** + * Create a new invalid object_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object_iterator() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline simdjson_result operator*() noexcept; + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const object_iterator&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const object_iterator&) const noexcept; + // Checks for ']' and ',' + simdjson_inline object_iterator& operator++() noexcept; + + private: + /** + * The underlying JSON iterator. + * + * PERF NOTE: expected to be elided in favor of the parent document: this is set when the object + * is first used, and never changes afterwards. + */ + value_iterator iter{}; + + simdjson_inline object_iterator(const value_iterator& iter) noexcept; + friend struct simdjson_result; + friend class object; + }; + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public icelake::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(icelake::ondemand::object_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + // Checks for ']' and ',' + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H +/* end file simdjson/generic/ondemand/object_iterator.h for icelake */ +/* including simdjson/generic/ondemand/serialization.h for icelake: #include "simdjson/generic/ondemand/serialization.h" */ +/* begin file simdjson/generic/ondemand/serialization.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Create a string-view instance out of a document instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(icelake::ondemand::document& x) noexcept; + /** + * Create a string-view instance out of a value instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. The value must + * not have been accessed previously. It does not + * validate the content. + */ + inline simdjson_result to_json_string(icelake::ondemand::value& x) noexcept; + /** + * Create a string-view instance out of an object instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(icelake::ondemand::object& x) noexcept; + /** + * Create a string-view instance out of an array instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(icelake::ondemand::array& x) noexcept; + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); +} // namespace simdjson + +/** + * We want to support argument-dependent lookup (ADL). + * Hence we should define operator<< in the namespace + * where the argument (here value, object, etc.) resides. + * Credit: @madhur4127 + * See https://github.com/simdjson/simdjson/issues/1768 + */ +namespace simdjson { + namespace icelake { + namespace ondemand { + + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The element. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::value x); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::array value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::document& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::document_reference& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The object. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::object value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + } + } +} // namespace simdjson::icelake::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H +/* end file simdjson/generic/ondemand/serialization.h for icelake */ + +// Inline definitions +/* including simdjson/generic/ondemand/array-inl.h for icelake: #include "simdjson/generic/ondemand/array-inl.h" */ +/* begin file simdjson/generic/ondemand/array-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter->depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the array is first found and the iterator is just past the `{`. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the `,` before the next value (or `]`). In this state, + // depth == iter->depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter->depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter->depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the array iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet element may be missing or not be an + // array--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter->depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between elements, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter->depth == depth, and at_start == false. + // + // ## Terminal State + // + // The terminal state has iter->depth < depth. at_start is always false. + // + // - Finished: When we have reached a `]` or have reported an error, we are finished. We signal this + // by decrementing depth. In this state, iter->depth < depth, at_start == false, and + // error == SUCCESS. + // + + simdjson_inline array::array(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result array::start(value_iterator& iter) noexcept { + // We don't need to know if the array is empty to start iteration, but we do want to know if there + // is an error--thus `simdjson_unused`. + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::start_root(value_iterator& iter) noexcept { + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_root_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::started(value_iterator& iter) noexcept { + bool has_value; + SIMDJSON_TRY(iter.started_array().get(has_value)); + return array(iter); + } + + simdjson_inline simdjson_result array::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return array_iterator(iter); + } + simdjson_inline simdjson_result array::end() noexcept { + return array_iterator(iter); + } + simdjson_inline error_code array::consume() noexcept { + auto error = iter.json_iter().skip_child(iter.depth() - 1); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result array::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter._json_iter->unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline simdjson_result array::count_elements() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the array after counting the number of elements. + iter.reset_array(); + return count; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline simdjson_result array::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_array().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + inline simdjson_result array::reset() & noexcept { + return iter.reset_array(); + } + + inline simdjson_result array::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + // - means "the append position" or "the element after the end of the array" + // We don't support this, because we're returning a real element, not a position. + if (json_pointer == "-") { return INDEX_OUT_OF_BOUNDS; } + + // Read the array index + size_t array_index = 0; + size_t i; + for (i = 0; i < json_pointer.length() && json_pointer[i] != '/'; i++) { + uint8_t digit = uint8_t(json_pointer[i] - '0'); + // Check for non-digit in array index. If it's there, we're trying to get a field in an object + if (digit > 9) { return INCORRECT_TYPE; } + array_index = array_index * 10 + digit; + } + + // 0 followed by other digits is invalid + if (i > 1 && json_pointer[0] == '0') { return INVALID_JSON_POINTER; } // "JSON pointer array index has other characters after 0" + + // Empty string is invalid; so is a "/" with no digits before it + if (i == 0) { return INVALID_JSON_POINTER; } // "Empty string in JSON pointer array index" + // Get the child + auto child = at(array_index); + // If there is an error, it ends here + if (child.error()) { + return child; + } + + // If there is a /, we're not done yet, call recursively. + if (i < json_pointer.length()) { + child = child.at_pointer(json_pointer.substr(i)); + } + return child; + } + + simdjson_inline simdjson_result array::at(size_t index) noexcept { + size_t i = 0; + for (auto value : *this) { + if (i == index) { return value; } + i++; + } + return INDEX_OUT_OF_BOUNDS; + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + icelake::ondemand::array&& value + ) noexcept + : implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept + : implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::is_empty() & noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H +/* end file simdjson/generic/ondemand/array-inl.h for icelake */ +/* including simdjson/generic/ondemand/array_iterator-inl.h for icelake: #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/array_iterator-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline array_iterator::array_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result array_iterator::operator*() noexcept { + if (iter.error()) { iter.abandon(); return iter.error(); } + return value(iter.child()); + } + simdjson_inline bool array_iterator::operator==(const array_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool array_iterator::operator!=(const array_iterator&) const noexcept { + return iter.is_open(); + } + simdjson_inline array_iterator& array_iterator::operator++() noexcept { + error_code error; + // PERF NOTE this is a safety rail ... users should exit loops as soon as they receive an error, so we'll never get here. + // However, it does not seem to make a perf difference, so we add it out of an abundance of caution. + if ((error = iter.error())) { return *this; } + if ((error = iter.skip_child())) { return *this; } + if ((error = iter.has_next_element().error())) { return *this; } + return *this; + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + icelake::ondemand::array_iterator&& value + ) noexcept + : icelake::implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : icelake::implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++(first); + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/array_iterator-inl.h for icelake */ +/* including simdjson/generic/ondemand/document-inl.h for icelake: #include "simdjson/generic/ondemand/document-inl.h" */ +/* begin file simdjson/generic/ondemand/document-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline document::document(ondemand::json_iterator&& _iter) noexcept + : iter{ std::forward(_iter) } + { + logger::log_start_value(iter, "document"); + } + + simdjson_inline document document::start(json_iterator&& iter) noexcept { + return document(std::forward(iter)); + } + + inline void document::rewind() noexcept { + iter.rewind(); + } + + inline std::string document::to_debug_string() noexcept { + return iter.to_string(); + } + + inline simdjson_result document::current_location() const noexcept { + return iter.current_location(); + } + + inline int32_t document::current_depth() const noexcept { + return iter.depth(); + } + + inline bool document::at_end() const noexcept { + return iter.at_end(); + } + + + inline bool document::is_alive() noexcept { + return iter.is_alive(); + } + simdjson_inline value_iterator document::resume_value_iterator() noexcept { + return value_iterator(&iter, 1, iter.root_position()); + } + simdjson_inline value_iterator document::get_root_value_iterator() noexcept { + return resume_value_iterator(); + } + simdjson_inline simdjson_result document::start_or_resume_object() noexcept { + if (iter.at_root()) { + return get_object(); + } + else { + return object::resume(resume_value_iterator()); + } + } + simdjson_inline simdjson_result document::get_value() noexcept { + // Make sure we start any arrays or objects before returning, so that start_root_() + // gets called. + + // It is the convention throughout the code that the macro `SIMDJSON_DEVELOPMENT_CHECKS` determines whether + // we check for OUT_OF_ORDER_ITERATION. Proper on::demand code should never trigger this error. +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.at_root()) { return OUT_OF_ORDER_ITERATION; } +#endif + // assert_at_root() serves two purposes: in Debug mode, whether or not + // SIMDJSON_DEVELOPMENT_CHECKS is set or not, it checks that we are at the root of + // the document (this will typically be redundant). In release mode, it generates + // SIMDJSON_ASSUME statements to allow the compiler to make assumptions. + iter.assert_at_root(); + switch (*iter.peek()) { + case '[': { + // The following lines check that the document ends with ]. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_array(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + case '{': { + // The following lines would check that the document ends with }. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_object(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + default: + // Unfortunately, scalar documents are a special case in simdjson and they cannot + // be safely converted to value instances. + return SCALAR_DOCUMENT_AS_VALUE; + } + } + simdjson_inline simdjson_result document::get_array() & noexcept { + auto value = get_root_value_iterator(); + return array::start_root(value); + } + simdjson_inline simdjson_result document::get_object() & noexcept { + auto value = get_root_value_iterator(); + return object::start_root(value); + } + + /** + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. We want to disallow trailing + * content. + * Thus, in several implementations below, we pass a 'true' parameter value to + * a get_root_value_iterator() method: this indicates that we disallow trailing content. + */ + + simdjson_inline simdjson_result document::get_uint64() noexcept { + return get_root_value_iterator().get_root_uint64(true); + } + simdjson_inline simdjson_result document::get_uint64_in_string() noexcept { + return get_root_value_iterator().get_root_uint64_in_string(true); + } + simdjson_inline simdjson_result document::get_int64() noexcept { + return get_root_value_iterator().get_root_int64(true); + } + simdjson_inline simdjson_result document::get_int64_in_string() noexcept { + return get_root_value_iterator().get_root_int64_in_string(true); + } + simdjson_inline simdjson_result document::get_double() noexcept { + return get_root_value_iterator().get_root_double(true); + } + simdjson_inline simdjson_result document::get_double_in_string() noexcept { + return get_root_value_iterator().get_root_double_in_string(true); + } + simdjson_inline simdjson_result document::get_string(bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(true, allow_replacement); + } + template + simdjson_inline error_code document::get_string(string_type& receiver, bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(receiver, true, allow_replacement); + } + simdjson_inline simdjson_result document::get_wobbly_string() noexcept { + return get_root_value_iterator().get_root_wobbly_string(true); + } + simdjson_inline simdjson_result document::get_raw_json_string() noexcept { + return get_root_value_iterator().get_root_raw_json_string(true); + } + simdjson_inline simdjson_result document::get_bool() noexcept { + return get_root_value_iterator().get_root_bool(true); + } + simdjson_inline simdjson_result document::is_null() noexcept { + return get_root_value_iterator().is_root_null(true); + } + + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_array(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_object(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_double(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_bool(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_value(); } + + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_double(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_uint64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_int64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_bool(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_value(); } + + template simdjson_inline error_code document::get(T& out) & noexcept { + return get().get(out); + } + template simdjson_inline error_code document::get(T& out) && noexcept { + return std::forward(*this).get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document::operator array() & noexcept(false) { return get_array(); } + simdjson_inline document::operator object() & noexcept(false) { return get_object(); } + simdjson_inline document::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document::operator double() noexcept(false) { return get_double(); } + simdjson_inline document::operator std::string_view() noexcept(false) { return get_string(false); } + simdjson_inline document::operator raw_json_string() noexcept(false) { return get_raw_json_string(); } + simdjson_inline document::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document::operator value() noexcept(false) { return get_value(); } + +#endif + simdjson_inline simdjson_result document::count_elements() & noexcept { + auto a = get_array(); + simdjson_result answer = a.count_elements(); + /* If there was an array, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::count_fields() & noexcept { + auto a = get_object(); + simdjson_result answer = a.count_fields(); + /* If there was an object, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::at(size_t index) & noexcept { + auto a = get_array(); + return a.at(index); + } + simdjson_inline simdjson_result document::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result document::end() & noexcept { + return {}; + } + + simdjson_inline simdjson_result document::find_field(std::string_view key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field(const char* key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field_unordered(std::string_view key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::find_field_unordered(const char* key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::operator[](std::string_view key) & noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result document::operator[](const char* key) & noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline error_code document::consume() noexcept { + auto error = iter.skip_child(0); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result document::raw_json() noexcept { + auto _iter = get_root_value_iterator(); + const uint8_t* starting_point{ _iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter.unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result document::type() noexcept { + return get_root_value_iterator().type(); + } + + simdjson_inline simdjson_result document::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool document::is_negative() noexcept { + return get_root_value_iterator().is_root_negative(); + } + + simdjson_inline simdjson_result document::is_integer() noexcept { + return get_root_value_iterator().is_root_integer(true); + } + + simdjson_inline simdjson_result document::get_number_type() noexcept { + return get_root_value_iterator().get_root_number_type(true); + } + + simdjson_inline simdjson_result document::get_number() noexcept { + return get_root_value_iterator().get_root_number(true); + } + + + simdjson_inline simdjson_result document::raw_json_token() noexcept { + auto _iter = get_root_value_iterator(); + return std::string_view(reinterpret_cast(_iter.peek_start()), _iter.peek_start_length()); + } + + simdjson_inline simdjson_result document::at_pointer(std::string_view json_pointer) noexcept { + rewind(); // Rewind the document each time at_pointer is called + if (json_pointer.empty()) { + return this->get_value(); + } + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + icelake::ondemand::document&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base( + error + ) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template + simdjson_inline simdjson_result simdjson_result::get() & noexcept { + if (error()) { return error(); } + return first.get(); + } + template + simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first).get(); + } + template + simdjson_inline error_code simdjson_result::get(T& out) & noexcept { + if (error()) { return error(); } + return first.get(out); + } + template + simdjson_inline error_code simdjson_result::get(T& out) && noexcept { + if (error()) { return error(); } + return std::forward(first).get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() & noexcept = delete; + template<> simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first); + } + template<> simdjson_inline error_code simdjson_result::get(icelake::ondemand::document& out) & noexcept = delete; + template<> simdjson_inline error_code simdjson_result::get(icelake::ondemand::document& out) && noexcept { + if (error()) { return error(); } + out = std::forward(first); + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + + + simdjson_inline bool simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } + + +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator icelake::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline bool simdjson_result::at_end() const noexcept { + if (error()) { return error(); } + return first.at_end(); + } + + + simdjson_inline int32_t simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline document_reference::document_reference() noexcept : doc{ nullptr } {} + simdjson_inline document_reference::document_reference(document& d) noexcept : doc(&d) {} + simdjson_inline void document_reference::rewind() noexcept { doc->rewind(); } + simdjson_inline simdjson_result document_reference::get_array() & noexcept { return doc->get_array(); } + simdjson_inline simdjson_result document_reference::get_object() & noexcept { return doc->get_object(); } + /** + * The document_reference instances are used primarily/solely for streams of JSON + * documents. + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. + * + * However, for streams of JSON documents, we want to be able to start from + * "321" "321" "321" + * and parse it successfully as a stream of JSON documents, calling get_uint64_in_string() + * successfully each time. + * + * To achieve this result, we pass a 'false' to a get_root_value_iterator() method: + * this indicates that we allow trailing content. + */ + simdjson_inline simdjson_result document_reference::get_uint64() noexcept { return doc->get_root_value_iterator().get_root_uint64(false); } + simdjson_inline simdjson_result document_reference::get_uint64_in_string() noexcept { return doc->get_root_value_iterator().get_root_uint64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_int64() noexcept { return doc->get_root_value_iterator().get_root_int64(false); } + simdjson_inline simdjson_result document_reference::get_int64_in_string() noexcept { return doc->get_root_value_iterator().get_root_int64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_double() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_double_in_string() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_string(bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(false, allow_replacement); } + template + simdjson_inline error_code document_reference::get_string(string_type& receiver, bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(receiver, false, allow_replacement); } + simdjson_inline simdjson_result document_reference::get_wobbly_string() noexcept { return doc->get_root_value_iterator().get_root_wobbly_string(false); } + simdjson_inline simdjson_result document_reference::get_raw_json_string() noexcept { return doc->get_root_value_iterator().get_root_raw_json_string(false); } + simdjson_inline simdjson_result document_reference::get_bool() noexcept { return doc->get_root_value_iterator().get_root_bool(false); } + simdjson_inline simdjson_result document_reference::get_value() noexcept { return doc->get_value(); } + simdjson_inline simdjson_result document_reference::is_null() noexcept { return doc->get_root_value_iterator().is_root_null(false); } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document_reference::operator array() & noexcept(false) { return array(*doc); } + simdjson_inline document_reference::operator object() & noexcept(false) { return object(*doc); } + simdjson_inline document_reference::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document_reference::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document_reference::operator double() noexcept(false) { return get_double(); } + simdjson_inline document_reference::operator std::string_view() noexcept(false) { return std::string_view(*doc); } + simdjson_inline document_reference::operator raw_json_string() noexcept(false) { return raw_json_string(*doc); } + simdjson_inline document_reference::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document_reference::operator value() noexcept(false) { return value(*doc); } +#endif + simdjson_inline simdjson_result document_reference::count_elements() & noexcept { return doc->count_elements(); } + simdjson_inline simdjson_result document_reference::count_fields() & noexcept { return doc->count_fields(); } + simdjson_inline simdjson_result document_reference::at(size_t index) & noexcept { return doc->at(index); } + simdjson_inline simdjson_result document_reference::begin() & noexcept { return doc->begin(); } + simdjson_inline simdjson_result document_reference::end() & noexcept { return doc->end(); } + simdjson_inline simdjson_result document_reference::find_field(std::string_view key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::find_field(const char* key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::operator[](std::string_view key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::operator[](const char* key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::find_field_unordered(std::string_view key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::find_field_unordered(const char* key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::type() noexcept { return doc->type(); } + simdjson_inline simdjson_result document_reference::is_scalar() noexcept { return doc->is_scalar(); } + simdjson_inline simdjson_result document_reference::current_location() noexcept { return doc->current_location(); } + simdjson_inline int32_t document_reference::current_depth() const noexcept { return doc->current_depth(); } + simdjson_inline bool document_reference::is_negative() noexcept { return doc->is_negative(); } + simdjson_inline simdjson_result document_reference::is_integer() noexcept { return doc->get_root_value_iterator().is_root_integer(false); } + simdjson_inline simdjson_result document_reference::get_number_type() noexcept { return doc->get_root_value_iterator().get_root_number_type(false); } + simdjson_inline simdjson_result document_reference::get_number() noexcept { return doc->get_root_value_iterator().get_root_number(false); } + simdjson_inline simdjson_result document_reference::raw_json_token() noexcept { return doc->raw_json_token(); } + simdjson_inline simdjson_result document_reference::at_pointer(std::string_view json_pointer) noexcept { return doc->at_pointer(json_pointer); } + simdjson_inline simdjson_result document_reference::raw_json() noexcept { return doc->raw_json(); } + simdjson_inline document_reference::operator document& () const noexcept { return *doc; } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + + + +namespace simdjson { + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::document_reference value, error_code error) + noexcept : implementation_simdjson_result_base(std::forward(value), error) {} + + + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator icelake::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H +/* end file simdjson/generic/ondemand/document-inl.h for icelake */ +/* including simdjson/generic/ondemand/document_stream-inl.h for icelake: #include "simdjson/generic/ondemand/document_stream-inl.h" */ +/* begin file simdjson/generic/ondemand/document_stream-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace icelake { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void stage1_worker::finish() { + // After calling "run" someone would call finish() to wait + // for the end of the processing. + // This function will wait until either the thread has done + // the processing or, else, the destructor has been called. + std::unique_lock lock(locking_mutex); + cond_var.wait(lock, [this] {return has_work == false; }); + } + + inline stage1_worker::~stage1_worker() { + // The thread may never outlive the stage1_worker instance + // and will always be stopped/joined before the stage1_worker + // instance is gone. + stop_thread(); + } + + inline void stage1_worker::start_thread() { + std::unique_lock lock(locking_mutex); + if (thread.joinable()) { + return; // This should never happen but we never want to create more than one thread. + } + thread = std::thread([this] { + while (true) { + std::unique_lock thread_lock(locking_mutex); + // We wait for either "run" or "stop_thread" to be called. + cond_var.wait(thread_lock, [this] {return has_work || !can_work; }); + // If, for some reason, the stop_thread() method was called (i.e., the + // destructor of stage1_worker is called, then we want to immediately destroy + // the thread (and not do any more processing). + if (!can_work) { + break; + } + this->owner->stage1_thread_error = this->owner->run_stage1(*this->stage1_thread_parser, + this->_next_batch_start); + this->has_work = false; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify "finish" + thread_lock.unlock(); + } + } + ); + } + + + inline void stage1_worker::stop_thread() { + std::unique_lock lock(locking_mutex); + // We have to make sure that all locks can be released. + can_work = false; + has_work = false; + cond_var.notify_all(); + lock.unlock(); + if (thread.joinable()) { + thread.join(); + } + } + + inline void stage1_worker::run(document_stream* ds, parser* stage1, size_t next_batch_start) { + std::unique_lock lock(locking_mutex); + owner = ds; + _next_batch_start = next_batch_start; + stage1_thread_parser = stage1; + has_work = true; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify the thread lock that we have work + lock.unlock(); + } + +#endif // SIMDJSON_THREADS_ENABLED + + simdjson_inline document_stream::document_stream( + ondemand::parser& _parser, + const uint8_t* _buf, + size_t _len, + size_t _batch_size, + bool _allow_comma_separated + ) noexcept + : parser{ &_parser }, + buf{ _buf }, + len{ _len }, + batch_size{ _batch_size <= MINIMAL_BATCH_SIZE ? MINIMAL_BATCH_SIZE : _batch_size }, + allow_comma_separated{ _allow_comma_separated }, + error{ SUCCESS } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(_parser.threaded) // we need to make a copy because _parser.threaded can change +#endif + { +#ifdef SIMDJSON_THREADS_ENABLED + if (worker.get() == nullptr) { + error = MEMALLOC; + } +#endif + } + + simdjson_inline document_stream::document_stream() noexcept + : parser{ nullptr }, + buf{ nullptr }, + len{ 0 }, + batch_size{ 0 }, + allow_comma_separated{ false }, + error{ UNINITIALIZED } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(false) +#endif + { + } + + simdjson_inline document_stream::~document_stream() noexcept + { +#ifdef SIMDJSON_THREADS_ENABLED + worker.reset(); +#endif + } + + inline size_t document_stream::size_in_bytes() const noexcept { + return len; + } + + inline size_t document_stream::truncated_bytes() const noexcept { + if (error == CAPACITY) { return len - batch_start; } + return parser->implementation->structural_indexes[parser->implementation->n_structural_indexes] - parser->implementation->structural_indexes[parser->implementation->n_structural_indexes + 1]; + } + + simdjson_inline document_stream::iterator::iterator() noexcept + : stream{ nullptr }, finished{ true } { + } + + simdjson_inline document_stream::iterator::iterator(document_stream* _stream, bool is_end) noexcept + : stream{ _stream }, finished{ is_end } { + } + + simdjson_inline simdjson_result document_stream::iterator::operator*() noexcept { + //if(stream->error) { return stream->error; } + return simdjson_result(stream->doc, stream->error); + } + + simdjson_inline document_stream::iterator& document_stream::iterator::operator++() noexcept { + // If there is an error, then we want the iterator + // to be finished, no matter what. (E.g., we do not + // keep generating documents with errors, or go beyond + // a document with errors.) + // + // Users do not have to call "operator*()" when they use operator++, + // so we need to end the stream in the operator++ function. + // + // Note that setting finished = true is essential otherwise + // we would enter an infinite loop. + if (stream->error) { finished = true; } + // Note that stream->error() is guarded against error conditions + // (it will immediately return if stream->error casts to false). + // In effect, this next function does nothing when (stream->error) + // is true (hence the risk of an infinite loop). + stream->next(); + // If that was the last document, we're finished. + // It is the only type of error we do not want to appear + // in operator*. + if (stream->error == EMPTY) { finished = true; } + // If we had any other kind of error (not EMPTY) then we want + // to pass it along to the operator* and we cannot mark the result + // as "finished" just yet. + return *this; + } + + simdjson_inline bool document_stream::iterator::operator!=(const document_stream::iterator& other) const noexcept { + return finished != other.finished; + } + + simdjson_inline document_stream::iterator document_stream::begin() noexcept { + start(); + // If there are no documents, we're finished. + return iterator(this, error == EMPTY); + } + + simdjson_inline document_stream::iterator document_stream::end() noexcept { + return iterator(this, true); + } + + inline void document_stream::start() noexcept { + if (error) { return; } + error = parser->allocate(batch_size); + if (error) { return; } + // Always run the first stage 1 parse immediately + batch_start = 0; + error = run_stage1(*parser, batch_start); + while (error == EMPTY) { + // In exceptional cases, we may start with an empty block + batch_start = next_batch_start(); + if (batch_start >= len) { return; } + error = run_stage1(*parser, batch_start); + } + if (error) { return; } + doc_index = batch_start; + doc = document(json_iterator(&buf[batch_start], parser)); + doc.iter._streaming = true; + +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread && next_batch_start() < len) { + // Kick off the first thread on next batch if needed + error = stage1_thread_parser.allocate(batch_size); + if (error) { return; } + worker->start_thread(); + start_stage1_thread(); + if (error) { return; } + } +#endif // SIMDJSON_THREADS_ENABLED + } + + inline void document_stream::next() noexcept { + // We always enter at once once in an error condition. + if (error) { return; } + next_document(); + if (error) { return; } + auto cur_struct_index = doc.iter._root - parser->implementation->structural_indexes.get(); + doc_index = batch_start + parser->implementation->structural_indexes[cur_struct_index]; + + // Check if at end of structural indexes (i.e. at end of batch) + if (cur_struct_index >= static_cast(parser->implementation->n_structural_indexes)) { + error = EMPTY; + // Load another batch (if available) + while (error == EMPTY) { + batch_start = next_batch_start(); + if (batch_start >= len) { break; } +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread) { + load_from_stage1_thread(); + } + else { + error = run_stage1(*parser, batch_start); + } +#else + error = run_stage1(*parser, batch_start); +#endif + /** + * Whenever we move to another window, we need to update all pointers to make + * it appear as if the input buffer started at the beginning of the window. + * + * Take this input: + * + * {"z":5} {"1":1,"2":2,"4":4} [7, 10, 9] [15, 11, 12, 13] [154, 110, 112, 1311] + * + * Say you process the following window... + * + * '{"z":5} {"1":1,"2":2,"4":4} [7, 10, 9]' + * + * When you do so, the json_iterator has a pointer at the beginning of the memory region + * (pointing at the beginning of '{"z"...'. + * + * When you move to the window that starts at... + * + * '[7, 10, 9] [15, 11, 12, 13] ... + * + * then it is not sufficient to just run stage 1. You also need to re-anchor the + * json_iterator so that it believes we are starting at '[7, 10, 9]...'. + * + * Under the DOM front-end, this gets done automatically because the parser owns + * the pointer the data, and when you call stage1 and then stage2 on the same + * parser, then stage2 will run on the pointer acquired by stage1. + * + * That is, stage1 calls "this->buf = _buf" so the parser remembers the buffer that + * we used. But json_iterator has no callback when stage1 is called on the parser. + * In fact, I think that the parser is unaware of json_iterator. + * + * + * So we need to re-anchor the json_iterator after each call to stage 1 so that + * all of the pointers are in sync. + */ + doc.iter = json_iterator(&buf[batch_start], parser); + doc.iter._streaming = true; + /** + * End of resync. + */ + + if (error) { continue; } // If the error was EMPTY, we may want to load another batch. + doc_index = batch_start; + } + } + } + + inline void document_stream::next_document() noexcept { + // Go to next place where depth=0 (document depth) + error = doc.iter.skip_child(0); + if (error) { return; } + // Always set depth=1 at the start of document + doc.iter._depth = 1; + // consume comma if comma separated is allowed + if (allow_comma_separated) { doc.iter.consume_character(','); } + // Resets the string buffer at the beginning, thus invalidating the strings. + doc.iter._string_buf_loc = parser->string_buf.get(); + doc.iter._root = doc.iter.position(); + } + + inline size_t document_stream::next_batch_start() const noexcept { + return batch_start + parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]; + } + + inline error_code document_stream::run_stage1(ondemand::parser& p, size_t _batch_start) noexcept { + // This code only updates the structural index in the parser, it does not update any json_iterator + // instance. + size_t remaining = len - _batch_start; + if (remaining <= batch_size) { + return p.implementation->stage1(&buf[_batch_start], remaining, stage1_mode::streaming_final); + } + else { + return p.implementation->stage1(&buf[_batch_start], batch_size, stage1_mode::streaming_partial); + } + } + + simdjson_inline size_t document_stream::iterator::current_index() const noexcept { + return stream->doc_index; + } + + simdjson_inline std::string_view document_stream::iterator::source() const noexcept { + auto depth = stream->doc.iter.depth(); + auto cur_struct_index = stream->doc.iter._root - stream->parser->implementation->structural_indexes.get(); + + // If at root, process the first token to determine if scalar value + if (stream->doc.iter.at_root()) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': // Depth=1 already at start of document + break; + case '}': case ']': + depth--; + break; + default: // Scalar value document + // TODO: Remove any trailing whitespaces + // This returns a string spanning from start of value to the beginning of the next document (excluded) + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[++cur_struct_index] - current_index() - 1); + } + cur_struct_index++; + } + + while (cur_struct_index <= static_cast(stream->parser->implementation->n_structural_indexes)) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': + depth++; + break; + case '}': case ']': + depth--; + break; + } + if (depth == 0) { break; } + cur_struct_index++; + } + + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[cur_struct_index] - current_index() + stream->batch_start + 1);; + } + + inline error_code document_stream::iterator::error() const noexcept { + return stream->error; + } + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void document_stream::load_from_stage1_thread() noexcept { + worker->finish(); + // Swap to the parser that was loaded up in the thread. Make sure the parser has + // enough memory to swap to, as well. + std::swap(stage1_thread_parser, *parser); + error = stage1_thread_error; + if (error) { return; } + + // If there's anything left, start the stage 1 thread! + if (next_batch_start() < len) { + start_stage1_thread(); + } + } + + inline void document_stream::start_stage1_thread() noexcept { + // we call the thread on a lambda that will update + // this->stage1_thread_error + // there is only one thread that may write to this value + // TODO this is NOT exception-safe. + this->stage1_thread_error = UNINITIALIZED; // In case something goes wrong, make sure it's an error + size_t _next_batch_start = this->next_batch_start(); + + worker->run(this, &this->stage1_thread_parser, _next_batch_start); + } + +#endif // SIMDJSON_THREADS_ENABLED + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result::simdjson_result( + icelake::ondemand::document_stream&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + +} + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H +/* end file simdjson/generic/ondemand/document_stream-inl.h for icelake */ +/* including simdjson/generic/ondemand/field-inl.h for icelake: #include "simdjson/generic/ondemand/field-inl.h" */ +/* begin file simdjson/generic/ondemand/field-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + // clang 6 doesn't think the default constructor can be noexcept, so we make it explicit + simdjson_inline field::field() noexcept : std::pair() {} + + simdjson_inline field::field(raw_json_string key, ondemand::value&& value) noexcept + : std::pair(key, std::forward(value)) + { + } + + simdjson_inline simdjson_result field::start(value_iterator& parent_iter) noexcept { + raw_json_string key; + SIMDJSON_TRY(parent_iter.field_key().get(key)); + SIMDJSON_TRY(parent_iter.field_value()); + return field::start(parent_iter, key); + } + + simdjson_inline simdjson_result field::start(const value_iterator& parent_iter, raw_json_string key) noexcept { + return field(key, parent_iter.child()); + } + + simdjson_inline simdjson_warn_unused simdjson_result field::unescaped_key(bool allow_replacement) noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() but Visual Studio won't let us. + simdjson_result answer = first.unescape(second.iter.json_iter(), allow_replacement); + first.consume(); + return answer; + } + + simdjson_inline raw_json_string field::key() const noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() by Visual Studio won't let us. + return first; + } + + simdjson_inline value& field::value() & noexcept { + return second; + } + + simdjson_inline value field::value() && noexcept { + return std::forward(*this).second; + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + icelake::ondemand::field&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::key() noexcept { + if (error()) { return error(); } + return first.key(); + } + simdjson_inline simdjson_result simdjson_result::unescaped_key(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.unescaped_key(allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::value() noexcept { + if (error()) { return error(); } + return std::move(first.value()); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H +/* end file simdjson/generic/ondemand/field-inl.h for icelake */ +/* including simdjson/generic/ondemand/json_iterator-inl.h for icelake: #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/json_iterator-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline json_iterator::json_iterator(json_iterator&& other) noexcept + : token(std::forward(other.token)), + parser{ other.parser }, + _string_buf_loc{ other._string_buf_loc }, + error{ other.error }, + _depth{ other._depth }, + _root{ other._root }, + _streaming{ other._streaming } + { + other.parser = nullptr; + } + simdjson_inline json_iterator& json_iterator::operator=(json_iterator&& other) noexcept { + token = other.token; + parser = other.parser; + _string_buf_loc = other._string_buf_loc; + error = other.error; + _depth = other._depth; + _root = other._root; + _streaming = other._streaming; + other.parser = nullptr; + return *this; + } + + simdjson_inline json_iterator::json_iterator(const uint8_t* buf, ondemand::parser* _parser) noexcept + : token(buf, &_parser->implementation->structural_indexes[0]), + parser{ _parser }, + _string_buf_loc{ parser->string_buf.get() }, + _depth{ 1 }, + _root{ parser->implementation->structural_indexes.get() }, + _streaming{ false } + + { + logger::log_headers(); +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif + } + + inline void json_iterator::rewind() noexcept { + token.set_position(root_position()); + logger::log_headers(); // We start again + _string_buf_loc = parser->string_buf.get(); + _depth = 1; + } + + inline bool json_iterator::balanced() const noexcept { + token_iterator ti(token); + int32_t count{ 0 }; + ti.set_position(root_position()); + while (ti.peek() <= peek_last()) { + switch (*ti.return_current_and_advance()) + { + case '[': case '{': + count++; + break; + case ']': case '}': + count--; + break; + default: + break; + } + } + return count == 0; + } + + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and parent_depth, which is a desired effect. The warning does not show up if the + // skip_child() function is not marked inline). + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline error_code json_iterator::skip_child(depth_t parent_depth) noexcept { + if (depth() <= parent_depth) { return SUCCESS; } + switch (*return_current_and_advance()) { + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + + // For the first open array/object in a value, we've already incremented depth, so keep it the same + // We never stop at colon, but if we did, it wouldn't affect depth + case '[': case '{': case ':': + logger::log_start_value(*this, "skip"); + break; + // If there is a comma, we have just finished a value in an array/object, and need to get back in + case ',': + logger::log_value(*this, "skip"); + break; + // ] or } means we just finished a value and need to jump out of the array/object + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } +#if SIMDJSON_CHECK_EOF + // If there are no more tokens, the parent is incomplete. + if (at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "Missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + break; + case '"': + if (*peek() == ':') { + // We are at a key!!! + // This might happen if you just started an object and you skip it immediately. + // Performance note: it would be nice to get rid of this check as it is somewhat + // expensive. + // https://github.com/simdjson/simdjson/issues/1742 + logger::log_value(*this, "key"); + return_current_and_advance(); // eat up the ':' + break; // important!!! + } + simdjson_fallthrough; + // Anything else must be a scalar value + default: + // For the first scalar, we will have incremented depth already, so we decrement it here. + logger::log_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + } + + // Now that we've considered the first value, we only increment/decrement for arrays/objects + while (position() < end_position()) { + switch (*return_current_and_advance()) { + case '[': case '{': + logger::log_start_value(*this, "skip"); + _depth++; + break; + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + default: + logger::log_value(*this, "skip", ""); + break; + } + } + + return report_error(TAPE_ERROR, "not enough close braces"); + } + + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool json_iterator::at_root() const noexcept { + return position() == root_position(); + } + + simdjson_inline bool json_iterator::is_single_token() const noexcept { + return parser->implementation->n_structural_indexes == 1; + } + + simdjson_inline bool json_iterator::streaming() const noexcept { + return _streaming; + } + + simdjson_inline token_position json_iterator::root_position() const noexcept { + return _root; + } + + simdjson_inline void json_iterator::assert_at_document_depth() const noexcept { + SIMDJSON_ASSUME(_depth == 1); + } + + simdjson_inline void json_iterator::assert_at_root() const noexcept { + SIMDJSON_ASSUME(_depth == 1); +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + // Under Visual Studio, the next SIMDJSON_ASSUME fails with: the argument + // has side effects that will be discarded. + SIMDJSON_ASSUME(token.position() == _root); +#endif + } + + simdjson_inline void json_iterator::assert_more_tokens(uint32_t required_tokens) const noexcept { + assert_valid_position(token._position + required_tokens - 1); + } + + simdjson_inline void json_iterator::assert_valid_position(token_position position) const noexcept { +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(position >= &parser->implementation->structural_indexes[0]); + SIMDJSON_ASSUME(position < &parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]); +#endif + } + + simdjson_inline bool json_iterator::at_end() const noexcept { + return position() == end_position(); + } + simdjson_inline token_position json_iterator::end_position() const noexcept { + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + return &parser->implementation->structural_indexes[n_structural_indexes]; + } + + inline std::string json_iterator::to_string() const noexcept { + if (!is_alive()) { return "dead json_iterator instance"; } + const char* current_structural = reinterpret_cast(token.peek()); + return std::string("json_iterator [ depth : ") + std::to_string(_depth) + + std::string(", structural : '") + std::string(current_structural, 1) + + std::string("', offset : ") + std::to_string(token.current_offset()) + + std::string("', error : ") + error_message(error) + + std::string(" ]"); + } + + inline simdjson_result json_iterator::current_location() const noexcept { + if (!is_alive()) { // Unrecoverable error + if (!at_root()) { + return reinterpret_cast(token.peek(-1)); + } + else { + return reinterpret_cast(token.peek()); + } + } + if (at_end()) { + return OUT_OF_BOUNDS; + } + return reinterpret_cast(token.peek()); + } + + simdjson_inline bool json_iterator::is_alive() const noexcept { + return parser; + } + + simdjson_inline void json_iterator::abandon() noexcept { + parser = nullptr; + _depth = 0; + } + + simdjson_inline const uint8_t* json_iterator::return_current_and_advance() noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif // SIMDJSON_CHECK_EOF + return token.return_current_and_advance(); + } + + simdjson_inline const uint8_t* json_iterator::unsafe_pointer() const noexcept { + // deliberately done without safety guard: + return token.peek(); + } + + simdjson_inline const uint8_t* json_iterator::peek(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // SIMDJSON_CHECK_EOF + return token.peek(delta); + } + + simdjson_inline uint32_t json_iterator::peek_length(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // #if SIMDJSON_CHECK_EOF + return token.peek_length(delta); + } + + simdjson_inline const uint8_t* json_iterator::peek(token_position position) const noexcept { + // todo: currently we require end-of-string buffering, but the following + // assert_valid_position should be turned on if/when we lift that condition. + // assert_valid_position(position); + // This is almost surely related to SIMDJSON_CHECK_EOF but given that SIMDJSON_CHECK_EOF + // is ON by default, we have no choice but to disable it for real with a comment. + return token.peek(position); + } + + simdjson_inline uint32_t json_iterator::peek_length(token_position position) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_valid_position(position); +#endif // SIMDJSON_CHECK_EOF + return token.peek_length(position); + } + + simdjson_inline token_position json_iterator::last_position() const noexcept { + // The following line fails under some compilers... + // SIMDJSON_ASSUME(parser->implementation->n_structural_indexes > 0); + // since it has side-effects. + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + SIMDJSON_ASSUME(n_structural_indexes > 0); + return &parser->implementation->structural_indexes[n_structural_indexes - 1]; + } + simdjson_inline const uint8_t* json_iterator::peek_last() const noexcept { + return token.peek(last_position()); + } + + simdjson_inline void json_iterator::ascend_to(depth_t parent_depth) noexcept { + SIMDJSON_ASSUME(parent_depth >= 0 && parent_depth < INT32_MAX - 1); + SIMDJSON_ASSUME(_depth == parent_depth + 1); + _depth = parent_depth; + } + + simdjson_inline void json_iterator::descend_to(depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); + _depth = child_depth; + } + + simdjson_inline depth_t json_iterator::depth() const noexcept { + return _depth; + } + + simdjson_inline uint8_t*& json_iterator::string_buf_loc() noexcept { + return _string_buf_loc; + } + + simdjson_inline error_code json_iterator::report_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error != SUCCESS && _error != UNINITIALIZED && _error != INCORRECT_TYPE && _error != NO_SUCH_FIELD); + logger::log_error(*this, message); + error = _error; + return error; + } + + simdjson_inline token_position json_iterator::position() const noexcept { + return token.position(); + } + + simdjson_inline simdjson_result json_iterator::unescape(raw_json_string in, bool allow_replacement) noexcept { + return parser->unescape(in, _string_buf_loc, allow_replacement); + } + + simdjson_inline simdjson_result json_iterator::unescape_wobbly(raw_json_string in) noexcept { + return parser->unescape_wobbly(in, _string_buf_loc); + } + + simdjson_inline void json_iterator::reenter_child(token_position position, depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); +#if SIMDJSON_DEVELOPMENT_CHECKS +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(size_t(child_depth) < parser->max_depth()); + SIMDJSON_ASSUME(position >= parser->start_positions[child_depth]); +#endif +#endif + token.set_position(position); + _depth = child_depth; + } + + simdjson_inline error_code json_iterator::consume_character(char c) noexcept { + if (*peek() == c) { + return_current_and_advance(); + return SUCCESS; + } + return TAPE_ERROR; + } + +#if SIMDJSON_DEVELOPMENT_CHECKS + + simdjson_inline token_position json_iterator::start_position(depth_t depth) const noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + return size_t(depth) < parser->max_depth() ? parser->start_positions[depth] : 0; + } + + simdjson_inline void json_iterator::set_start_position(depth_t depth, token_position position) noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + if (size_t(depth) < parser->max_depth()) { parser->start_positions[depth] = position; } + } + +#endif + + + simdjson_inline error_code json_iterator::optional_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error == INCORRECT_TYPE || _error == NO_SUCH_FIELD); + logger::log_error(*this, message); + return _error; + } + + + simdjson_warn_unused simdjson_inline bool json_iterator::copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept { + // This function is not expected to be called in performance-sensitive settings. + // Let us guard against silly cases: + if ((N < max_len) || (N == 0)) { return false; } + // Copy to the buffer. + std::memcpy(tmpbuf, json, max_len); + if (N > max_len) { // We pad whatever remains with ' '. + std::memset(tmpbuf + max_len, ' ', N - max_len); + } + return true; + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::json_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/json_iterator-inl.h for icelake */ +/* including simdjson/generic/ondemand/json_type-inl.h for icelake: #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* begin file simdjson/generic/ondemand/json_type-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept { + switch (type) { + case json_type::array: out << "array"; break; + case json_type::object: out << "object"; break; + case json_type::number: out << "number"; break; + case json_type::string: out << "string"; break; + case json_type::boolean: out << "boolean"; break; + case json_type::null: out << "null"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false) { + return out << type.value(); + } +#endif + + + + simdjson_inline number_type number::get_number_type() const noexcept { + return type; + } + + simdjson_inline bool number::is_uint64() const noexcept { + return get_number_type() == number_type::unsigned_integer; + } + + simdjson_inline uint64_t number::get_uint64() const noexcept { + return payload.unsigned_integer; + } + + simdjson_inline number::operator uint64_t() const noexcept { + return get_uint64(); + } + + + simdjson_inline bool number::is_int64() const noexcept { + return get_number_type() == number_type::signed_integer; + } + + simdjson_inline int64_t number::get_int64() const noexcept { + return payload.signed_integer; + } + + simdjson_inline number::operator int64_t() const noexcept { + return get_int64(); + } + + simdjson_inline bool number::is_double() const noexcept { + return get_number_type() == number_type::floating_point_number; + } + + simdjson_inline double number::get_double() const noexcept { + return payload.floating_point_number; + } + + simdjson_inline number::operator double() const noexcept { + return get_double(); + } + + simdjson_inline double number::as_double() const noexcept { + if (is_double()) { + return payload.floating_point_number; + } + if (is_int64()) { + return double(payload.signed_integer); + } + return double(payload.unsigned_integer); + } + + simdjson_inline void number::append_s64(int64_t value) noexcept { + payload.signed_integer = value; + type = number_type::signed_integer; + } + + simdjson_inline void number::append_u64(uint64_t value) noexcept { + payload.unsigned_integer = value; + type = number_type::unsigned_integer; + } + + simdjson_inline void number::append_double(double value) noexcept { + payload.floating_point_number = value; + type = number_type::floating_point_number; + } + + simdjson_inline void number::skip_double() noexcept { + type = number_type::floating_point_number; + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::json_type&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H +/* end file simdjson/generic/ondemand/json_type-inl.h for icelake */ +/* including simdjson/generic/ondemand/logger-inl.h for icelake: #include "simdjson/generic/ondemand/logger-inl.h" */ +/* begin file simdjson/generic/ondemand/logger-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace icelake { + namespace ondemand { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static int log_depth = 0; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + template + static inline std::string string_format(const std::string& format, const Args&... args) + { + SIMDJSON_PUSH_DISABLE_ALL_WARNINGS + int size_s = std::snprintf(nullptr, 0, format.c_str(), args...) + 1; + auto size = static_cast(size_s); + if (size <= 0) return std::string(); + std::unique_ptr buf(new char[size]); + std::snprintf(buf.get(), size, format.c_str(), args...); + SIMDJSON_POP_DISABLE_WARNINGS + return std::string(buf.get(), buf.get() + size - 1); + } + + static inline log_level get_log_level_from_env() + { + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe + char* lvl = getenv("SIMDJSON_LOG_LEVEL"); + SIMDJSON_POP_DISABLE_WARNINGS + if (lvl && simdjson_strcasecmp(lvl, "ERROR") == 0) { return log_level::error; } + return log_level::info; + } + + static inline log_level log_threshold() + { + static log_level threshold = get_log_level_from_env(); + return threshold; + } + + static inline bool should_log(log_level level) + { + return level >= log_threshold(); + } + + inline void log_event(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "", type, detail, log_level::info); + } + inline void log_value(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "+", type, detail, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + inline void log_start_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_line(iter, "+", type, "", delta, depth_delta, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + + inline void log_end_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + if (LOG_ENABLED) { log_depth--; } + log_line(iter, "-", type, "", delta, depth_delta, log_level::info); + } + + inline void log_error(const json_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_line(iter, "ERROR: ", error, detail, delta, depth_delta, log_level::error); + } + inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail) noexcept { + log_line(iter, index, depth, "ERROR: ", error, detail, log_level::error); + } + + inline void log_event(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_event(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_value(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_value(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_start_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_start_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_end_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_end_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_error(const value_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_error(iter.json_iter(), error, detail, delta, depth_delta); + } + + inline void log_headers() noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(log_level::info))) { + // Technically a static variable is not thread-safe, but if you are using threads and logging... well... + static bool displayed_hint{ false }; + log_depth = 0; + printf("\n"); + if (!displayed_hint) { + // We only print this helpful header once. + printf("# Logging provides the depth and position of the iterator user-visible steps:\n"); + printf("# +array says 'this is where we were when we discovered the start array'\n"); + printf( + "# -array says 'this is where we were when we ended the array'\n"); + printf("# skip says 'this is a structural or value I am skipping'\n"); + printf("# +/-skip says 'this is a start/end array or object I am skipping'\n"); + printf("#\n"); + printf("# The indentation of the terms (array, string,...) indicates the depth,\n"); + printf("# in addition to the depth being displayed.\n"); + printf("#\n"); + printf("# Every token in the document has a single depth determined by the tokens before it,\n"); + printf("# and is not affected by what the token actually is.\n"); + printf("#\n"); + printf("# Not all structural elements are presented as tokens in the logs.\n"); + printf("#\n"); + printf("# We never give control to the user within an empty array or an empty object.\n"); + printf("#\n"); + printf("# Inside an array, having a depth greater than the array's depth means that\n"); + printf("# we are pointing inside a value.\n"); + printf("# Having a depth equal to the array means that we are pointing right before a value.\n"); + printf("# Having a depth smaller than the array means that we have moved beyond the array.\n"); + displayed_hint = true; + } + printf("\n"); + printf("| %-*s ", LOG_EVENT_LEN, "Event"); + printf("| %-*s ", LOG_BUFFER_LEN, "Buffer"); + printf("| %-*s ", LOG_SMALL_BUFFER_LEN, "Next"); + // printf("| %-*s ", 5, "Next#"); + printf("| %-*s ", 5, "Depth"); + printf("| Detail "); + printf("|\n"); + + printf("|%.*s", LOG_EVENT_LEN + 2, DASHES); + printf("|%.*s", LOG_BUFFER_LEN + 2, DASHES); + printf("|%.*s", LOG_SMALL_BUFFER_LEN + 2, DASHES); + // printf("|%.*s", 5+2, DASHES); + printf("|%.*s", 5 + 2, DASHES); + printf("|--------"); + printf("|\n"); + fflush(stdout); + } + } + } + + template + inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, log_level level, Args&&... args) noexcept { + log_line(iter, iter.position() + delta, depth_t(iter.depth() + depth_delta), title_prefix, title, detail, level, std::forward(args)...); + } + + template + inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, log_level level, Args&&... args) noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(level))) { + const int indent = depth * 2; + const auto buf = iter.token.buf; + auto msg = string_format(title, std::forward(args)...); + printf("| %*s%s%-*s ", indent, "", title_prefix, + LOG_EVENT_LEN - indent - int(strlen(title_prefix)), msg.c_str()); + { + // Print the current structural. + printf("| "); + // Before we begin, the index might point right before the document. + // This could be unsafe, see https://github.com/simdjson/simdjson/discussions/1938 + if (index < iter._root) { + printf("%*s", LOG_BUFFER_LEN, ""); + } + else { + auto current_structural = &buf[*index]; + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current_structural[i])); + } + } + printf(" "); + } + { + // Print the next structural. + printf("| "); + auto next_structural = &buf[*(index + 1)]; + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next_structural[i])); + } + printf(" "); + } + // printf("| %5u ", *(index+1)); + printf("| %5i ", depth); + printf("| %6.*s ", int(detail.size()), detail.data()); + printf("|\n"); + fflush(stdout); + } + } + } + + } // namespace logger + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H +/* end file simdjson/generic/ondemand/logger-inl.h for icelake */ +/* including simdjson/generic/ondemand/object-inl.h for icelake: #include "simdjson/generic/ondemand/object-inl.h" */ +/* begin file simdjson/generic/ondemand/object-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) & noexcept { + return find_field_unordered(key); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) && noexcept { + return std::forward(*this).find_field_unordered(key); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + + simdjson_inline simdjson_result object::start(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_object().error()); + return object(iter); + } + simdjson_inline simdjson_result object::start_root(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_root_object().error()); + return object(iter); + } + simdjson_inline error_code object::consume() noexcept { + if (iter.is_at_key()) { + /** + * whenever you are pointing at a key, calling skip_child() is + * unsafe because you will hit a string and you will assume that + * it is string value, and this mistake will lead you to make bad + * depth computation. + */ + /** + * We want to 'consume' the key. We could really + * just do _json_iter->return_current_and_advance(); at this + * point, but, for clarity, we will use the high-level API to + * eat the key. We assume that the compiler optimizes away + * most of the work. + */ + simdjson_unused raw_json_string actual_key; + auto error = iter.field_key().get(actual_key); + if (error) { iter.abandon(); return error; }; + // Let us move to the value while we are at it. + if ((error = iter.field_value())) { iter.abandon(); return error; } + } + auto error_skip = iter.json_iter().skip_child(iter.depth() - 1); + if (error_skip) { iter.abandon(); } + return error_skip; + } + + simdjson_inline simdjson_result object::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + const uint8_t* final_point{ iter._json_iter->peek() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result object::started(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.started_object().error()); + return object(iter); + } + + simdjson_inline object object::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline object::object(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result object::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return object_iterator(iter); + } + simdjson_inline simdjson_result object::end() noexcept { + return object_iterator(iter); + } + + inline simdjson_result object::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + size_t slash = json_pointer.find('/'); + std::string_view key = json_pointer.substr(0, slash); + // Grab the child with the given key + simdjson_result child; + + // If there is an escape character in the key, unescape it and then get the child. + size_t escape = key.find('~'); + if (escape != std::string_view::npos) { + // Unescape the key + std::string unescaped(key); + do { + switch (unescaped[escape + 1]) { + case '0': + unescaped.replace(escape, 2, "~"); + break; + case '1': + unescaped.replace(escape, 2, "/"); + break; + default: + return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); + } + escape = unescaped.find('~', escape + 1); + } while (escape != std::string::npos); + child = find_field(unescaped); // Take note find_field does not unescape keys when matching + } + else { + child = find_field(key); + } + if (child.error()) { + return child; // we do not continue if there was an error + } + // If there is a /, we have to recurse and look up more of the path + if (slash != std::string_view::npos) { + child = child.at_pointer(json_pointer.substr(slash)); + } + return child; + } + + simdjson_inline simdjson_result object::count_fields() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the object after counting the number of elements. + iter.reset_object(); + return count; + } + + simdjson_inline simdjson_result object::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_object().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + simdjson_inline simdjson_result object::reset() & noexcept { + return iter.reset_object(); + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::object&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first)[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + inline simdjson_result simdjson_result::reset() noexcept { + if (error()) { return error(); } + return first.reset(); + } + + inline simdjson_result simdjson_result::is_empty() noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H +/* end file simdjson/generic/ondemand/object-inl.h for icelake */ +/* including simdjson/generic/ondemand/object_iterator-inl.h for icelake: #include "simdjson/generic/ondemand/object_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/object_iterator-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + // + // object_iterator + // + + simdjson_inline object_iterator::object_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result object_iterator::operator*() noexcept { + error_code error = iter.error(); + if (error) { iter.abandon(); return error; } + auto result = field::start(iter); + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (result.error()) { iter.abandon(); } + return result; + } + simdjson_inline bool object_iterator::operator==(const object_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool object_iterator::operator!=(const object_iterator&) const noexcept { + return iter.is_open(); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline object_iterator& object_iterator::operator++() noexcept { + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (!iter.is_open()) { return *this; } // Iterator will be released if there is an error + + simdjson_unused error_code error; + if ((error = iter.skip_child())) { return *this; } + + simdjson_unused bool has_value; + if ((error = iter.has_next_field().get(has_value))) { return *this; }; + return *this; + } + SIMDJSON_POP_DISABLE_WARNINGS + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter.depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the object is first found and the iterator is just past the {. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the , or } before the next value. In this state, + // depth == iter.depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter.depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter.depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the object iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet field may be missing or not be an + // object--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter.depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between fields, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter.depth == depth, and at_start == false. + // + // Errors that occur while reading a field to give to the user (such as when the key is not a + // string or the field is missing a colon) are yielded immediately. Depth is then decremented, + // moving to the Finished state without transitioning through an Error state at all. + // + // ## Terminal State + // + // The terminal state has iter.depth < depth. at_start is always false. + // + // - Finished: When we have reached a }, we are finished. We signal this by decrementing depth. + // In this state, iter.depth < depth, at_start == false, and error == SUCCESS. + // + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + icelake::ondemand::object_iterator&& value + ) noexcept + : implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + // Checks for ']' and ',' + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++first; + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/object_iterator-inl.h for icelake */ +/* including simdjson/generic/ondemand/parser-inl.h for icelake: #include "simdjson/generic/ondemand/parser-inl.h" */ +/* begin file simdjson/generic/ondemand/parser-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string_view.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/dom/base.h" // for MINIMAL_DOCUMENT_CAPACITY */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline parser::parser(size_t max_capacity) noexcept + : _max_capacity{ max_capacity } { + } + + simdjson_warn_unused simdjson_inline error_code parser::allocate(size_t new_capacity, size_t new_max_depth) noexcept { + if (new_capacity > max_capacity()) { return CAPACITY; } + if (string_buf && new_capacity == capacity() && new_max_depth == max_depth()) { return SUCCESS; } + + // string_capacity copied from document::allocate + _capacity = 0; + size_t string_capacity = SIMDJSON_ROUNDUP_N(5 * new_capacity / 3 + SIMDJSON_PADDING, 64); + string_buf.reset(new (std::nothrow) uint8_t[string_capacity]); +#if SIMDJSON_DEVELOPMENT_CHECKS + start_positions.reset(new (std::nothrow) token_position[new_max_depth]); +#endif + if (implementation) { + SIMDJSON_TRY(implementation->set_capacity(new_capacity)); + SIMDJSON_TRY(implementation->set_max_depth(new_max_depth)); + } + else { + SIMDJSON_TRY(simdjson::get_active_implementation()->create_dom_parser_implementation(new_capacity, new_max_depth, implementation)); + } + _capacity = new_capacity; + _max_depth = new_max_depth; + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length() || !string_buf) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return document::start({ reinterpret_cast(json.data()), this }); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const char* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const uint8_t* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string_view json, size_t allocated) & noexcept { + return iterate(padded_string_view(json, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string& json) & noexcept { + if (json.capacity() - json.size() < SIMDJSON_PADDING) { + json.reserve(json.size() + SIMDJSON_PADDING); + } + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const std::string& json) & noexcept { + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + padded_string_view json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + const padded_string& json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate_raw(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length()) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return json_iterator(reinterpret_cast(json.data()), this); + } + + inline simdjson_result parser::iterate_many(const uint8_t* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + if (allow_comma_separated && batch_size < len) { batch_size = len; } + return document_stream(*this, buf, len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const char* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(reinterpret_cast(buf), len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const std::string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const padded_string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + + simdjson_inline size_t parser::capacity() const noexcept { + return _capacity; + } + simdjson_inline size_t parser::max_capacity() const noexcept { + return _max_capacity; + } + simdjson_inline size_t parser::max_depth() const noexcept { + return _max_depth; + } + + simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { + if (max_capacity < dom::MINIMAL_DOCUMENT_CAPACITY) { + _max_capacity = max_capacity; + } + else { + _max_capacity = dom::MINIMAL_DOCUMENT_CAPACITY; + } + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement) const noexcept { + uint8_t* end = implementation->parse_string(in.buf, dst, allow_replacement); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept { + uint8_t* end = implementation->parse_wobbly_string(in.buf, dst); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::parser&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H +/* end file simdjson/generic/ondemand/parser-inl.h for icelake */ +/* including simdjson/generic/ondemand/raw_json_string-inl.h for icelake: #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + namespace icelake { + namespace ondemand { + + simdjson_inline raw_json_string::raw_json_string(const uint8_t* _buf) noexcept : buf{ _buf } {} + + simdjson_inline const char* raw_json_string::raw() const noexcept { return reinterpret_cast(buf); } + + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(std::string_view target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; pos < target.size() && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(const char* target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; target[pos] && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; target[pos]; pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(size_t length, std::string_view target) const noexcept { + // If we are going to call memcmp, then we must know something about the length of the raw_json_string. + return (length >= target.size()) && (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + + simdjson_inline bool raw_json_string::unsafe_is_equal(std::string_view target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + if (target.size() <= SIMDJSON_PADDING) { + return (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + const char* r{ raw() }; + size_t pos{ 0 }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(std::string_view target) const noexcept { + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(const char* target) const noexcept { + // Assumptions: 'target' does not contain unescaped quote characters, is null terminated and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(const char* target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept { + return a.unsafe_is_equal(c); + } + + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept { + return a == c; + } + + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept { + return !(a == c); + } + + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept { + return !(a == c); + } + + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape(json_iterator& iter, bool allow_replacement) const noexcept { + return iter.unescape(*this, allow_replacement); + } + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape_wobbly(json_iterator& iter) const noexcept { + return iter.unescape_wobbly(*this); + } + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream& out, const raw_json_string& str) noexcept { + bool in_escape = false; + const char* s = str.raw(); + while (true) { + switch (*s) { + case '\\': in_escape = !in_escape; break; + case '"': if (in_escape) { in_escape = false; } + else { return out; } break; + default: if (in_escape) { in_escape = false; } + } + out << *s; + s++; + } + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::raw_json_string&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::raw() const noexcept { + if (error()) { return error(); } + return first.raw(); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape(icelake::ondemand::json_iterator& iter, bool allow_replacement) const noexcept { + if (error()) { return error(); } + return first.unescape(iter, allow_replacement); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape_wobbly(icelake::ondemand::json_iterator& iter) const noexcept { + if (error()) { return error(); } + return first.unescape_wobbly(iter); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H +/* end file simdjson/generic/ondemand/raw_json_string-inl.h for icelake */ +/* including simdjson/generic/ondemand/serialization-inl.h for icelake: #include "simdjson/generic/ondemand/serialization-inl.h" */ +/* begin file simdjson/generic/ondemand/serialization-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/serialization.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + inline std::string_view trim(const std::string_view str) noexcept { + // We can almost surely do better by rolling our own find_first_not_of function. + size_t first = str.find_first_not_of(" \t\n\r"); + // If we have the empty string (just white space), then no trimming is possible, and + // we return the empty string_view. + if (std::string_view::npos == first) { return std::string_view(); } + size_t last = str.find_last_not_of(" \t\n\r"); + return str.substr(first, (last - first + 1)); + } + + + inline simdjson_result to_json_string(icelake::ondemand::document& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(icelake::ondemand::document_reference& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(icelake::ondemand::value& x) noexcept { + /** + * If we somehow receive a value that has already been consumed, + * then the following code could be in trouble. E.g., we create + * an array as needed, but if an array was already created, then + * it could be bad. + */ + using namespace icelake::ondemand; + icelake::ondemand::json_type t; + auto error = x.type().get(t); + if (error != SUCCESS) { return error; } + switch (t) + { + case json_type::array: + { + icelake::ondemand::array array; + error = x.get_array().get(array); + if (error) { return error; } + return to_json_string(array); + } + case json_type::object: + { + icelake::ondemand::object object; + error = x.get_object().get(object); + if (error) { return error; } + return to_json_string(object); + } + default: + return trim(x.raw_json_token()); + } + } + + inline simdjson_result to_json_string(icelake::ondemand::object& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(icelake::ondemand::array& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } +} // namespace simdjson + +namespace simdjson { + namespace icelake { + namespace ondemand { + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::document_reference& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::icelake::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + } + } +} // namespace simdjson::icelake::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H +/* end file simdjson/generic/ondemand/serialization-inl.h for icelake */ +/* including simdjson/generic/ondemand/token_iterator-inl.h for icelake: #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/token_iterator-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline token_iterator::token_iterator( + const uint8_t* _buf, + token_position position + ) noexcept : buf{ _buf }, _position{ position } + { + } + + simdjson_inline uint32_t token_iterator::current_offset() const noexcept { + return *(_position); + } + + + simdjson_inline const uint8_t* token_iterator::return_current_and_advance() noexcept { + return &buf[*(_position++)]; + } + + simdjson_inline const uint8_t* token_iterator::peek(token_position position) const noexcept { + return &buf[*position]; + } + simdjson_inline uint32_t token_iterator::peek_index(token_position position) const noexcept { + return *position; + } + simdjson_inline uint32_t token_iterator::peek_length(token_position position) const noexcept { + return *(position + 1) - *position; + } + + simdjson_inline const uint8_t* token_iterator::peek(int32_t delta) const noexcept { + return &buf[*(_position + delta)]; + } + simdjson_inline uint32_t token_iterator::peek_index(int32_t delta) const noexcept { + return *(_position + delta); + } + simdjson_inline uint32_t token_iterator::peek_length(int32_t delta) const noexcept { + return *(_position + delta + 1) - *(_position + delta); + } + + simdjson_inline token_position token_iterator::position() const noexcept { + return _position; + } + simdjson_inline void token_iterator::set_position(token_position target_position) noexcept { + _position = target_position; + } + + simdjson_inline bool token_iterator::operator==(const token_iterator& other) const noexcept { + return _position == other._position; + } + simdjson_inline bool token_iterator::operator!=(const token_iterator& other) const noexcept { + return _position != other._position; + } + simdjson_inline bool token_iterator::operator>(const token_iterator& other) const noexcept { + return _position > other._position; + } + simdjson_inline bool token_iterator::operator>=(const token_iterator& other) const noexcept { + return _position >= other._position; + } + simdjson_inline bool token_iterator::operator<(const token_iterator& other) const noexcept { + return _position < other._position; + } + simdjson_inline bool token_iterator::operator<=(const token_iterator& other) const noexcept { + return _position <= other._position; + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::token_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/token_iterator-inl.h for icelake */ +/* including simdjson/generic/ondemand/value-inl.h for icelake: #include "simdjson/generic/ondemand/value-inl.h" */ +/* begin file simdjson/generic/ondemand/value-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline value::value(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + simdjson_inline value value::start(const value_iterator& iter) noexcept { + return iter; + } + simdjson_inline value value::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline simdjson_result value::get_array() noexcept { + return array::start(iter); + } + simdjson_inline simdjson_result value::get_object() noexcept { + return object::start(iter); + } + simdjson_inline simdjson_result value::start_or_resume_object() noexcept { + if (iter.at_start()) { + return get_object(); + } + else { + return object::resume(iter); + } + } + + simdjson_inline simdjson_result value::get_raw_json_string() noexcept { + return iter.get_raw_json_string(); + } + simdjson_inline simdjson_result value::get_string(bool allow_replacement) noexcept { + return iter.get_string(allow_replacement); + } + template + simdjson_inline error_code value::get_string(string_type& receiver, bool allow_replacement) noexcept { + return iter.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result value::get_wobbly_string() noexcept { + return iter.get_wobbly_string(); + } + simdjson_inline simdjson_result value::get_double() noexcept { + return iter.get_double(); + } + simdjson_inline simdjson_result value::get_double_in_string() noexcept { + return iter.get_double_in_string(); + } + simdjson_inline simdjson_result value::get_uint64() noexcept { + return iter.get_uint64(); + } + simdjson_inline simdjson_result value::get_uint64_in_string() noexcept { + return iter.get_uint64_in_string(); + } + simdjson_inline simdjson_result value::get_int64() noexcept { + return iter.get_int64(); + } + simdjson_inline simdjson_result value::get_int64_in_string() noexcept { + return iter.get_int64_in_string(); + } + simdjson_inline simdjson_result value::get_bool() noexcept { + return iter.get_bool(); + } + simdjson_inline simdjson_result value::is_null() noexcept { + return iter.is_null(); + } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_array(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_object(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_number(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_double(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_bool(); } + + template simdjson_inline error_code value::get(T& out) noexcept { + return get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline value::operator array() noexcept(false) { + return get_array(); + } + simdjson_inline value::operator object() noexcept(false) { + return get_object(); + } + simdjson_inline value::operator uint64_t() noexcept(false) { + return get_uint64(); + } + simdjson_inline value::operator int64_t() noexcept(false) { + return get_int64(); + } + simdjson_inline value::operator double() noexcept(false) { + return get_double(); + } + simdjson_inline value::operator std::string_view() noexcept(false) { + return get_string(false); + } + simdjson_inline value::operator raw_json_string() noexcept(false) { + return get_raw_json_string(); + } + simdjson_inline value::operator bool() noexcept(false) { + return get_bool(); + } +#endif + + simdjson_inline simdjson_result value::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result value::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result value::count_elements() & noexcept { + simdjson_result answer; + auto a = get_array(); + answer = a.count_elements(); + // count_elements leaves you pointing inside the array, at the first element. + // We need to move back so that the user can create a new array (which requires that + // we point at '['). + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::count_fields() & noexcept { + simdjson_result answer; + auto a = get_object(); + answer = a.count_fields(); + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::at(size_t index) noexcept { + auto a = get_array(); + return a.at(index); + } + + simdjson_inline simdjson_result value::find_field(std::string_view key) noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result value::find_field(const char* key) noexcept { + return start_or_resume_object().find_field(key); + } + + simdjson_inline simdjson_result value::find_field_unordered(std::string_view key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result value::find_field_unordered(const char* key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + + simdjson_inline simdjson_result value::operator[](std::string_view key) noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result value::operator[](const char* key) noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline simdjson_result value::type() noexcept { + return iter.type(); + } + + simdjson_inline simdjson_result value::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool value::is_negative() noexcept { + return iter.is_negative(); + } + + simdjson_inline simdjson_result value::is_integer() noexcept { + return iter.is_integer(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number_type() noexcept { + return iter.get_number_type(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number() noexcept { + return iter.get_number(); + } + + simdjson_inline std::string_view value::raw_json_token() noexcept { + return std::string_view(reinterpret_cast(iter.peek_start()), iter.peek_start_length()); + } + + simdjson_inline simdjson_result value::raw_json() noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: { + ondemand::array array; + SIMDJSON_TRY(get_array().get(array)); + return array.raw_json(); + } + case json_type::object: { + ondemand::object object; + SIMDJSON_TRY(get_object().get(object)); + return object.raw_json(); + } + default: + return raw_json_token(); + } + } + + simdjson_inline simdjson_result value::current_location() noexcept { + return iter.json_iter().current_location(); + } + + simdjson_inline int32_t value::current_depth() const noexcept { + return iter.json_iter().depth(); + } + + simdjson_inline simdjson_result value::at_pointer(std::string_view json_pointer) noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + icelake::ondemand::value&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + if (error()) { return error(); } + return {}; + } + + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) noexcept { + if (error()) { return error(); } + return first[key]; + } + + simdjson_inline simdjson_result simdjson_result::get_array() noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return first.get(); + } + template simdjson_inline error_code simdjson_result::get(T& out) noexcept { + if (error()) { return error(); } + return first.get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return std::move(first); + } + template<> simdjson_inline error_code simdjson_result::get(icelake::ondemand::value& out) noexcept { + if (error()) { return error(); } + out = first; + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator icelake::ondemand::array() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::object() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator icelake::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H +/* end file simdjson/generic/ondemand/value-inl.h for icelake */ +/* including simdjson/generic/ondemand/value_iterator-inl.h for icelake: #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/value_iterator-inl.h for icelake */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/atomparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace icelake { + namespace ondemand { + + simdjson_inline value_iterator::value_iterator( + json_iterator* json_iter, + depth_t depth, + token_position start_position + ) noexcept : _json_iter{ json_iter }, _depth{ depth }, _start_position{ start_position } + { + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_root_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_object() noexcept { + assert_at_container_start(); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + if (*_json_iter->peek() == '}') { + logger::log_value(*_json_iter, "empty object"); + _json_iter->return_current_and_advance(); + end_container(); + return false; + } + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_object() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // object: e.g., `{"a":2} foo }`. Users concerned with garbage content should + // call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != '}') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing } at end"); + } + // If the last character is } *and* the first gibberish character is also '}' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == '}') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed object. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_object() noexcept { + auto error = check_root_object(); + if (error) { return error; } + return started_object(); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::end_container() noexcept { +#if SIMDJSON_CHECK_EOF + if (depth() > 1 && at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing parent ] or }"); } + // if (depth() <= 1 && !at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + _json_iter->ascend_to(depth() - 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_field() noexcept { + assert_at_next(); + + // It's illegal to call this unless there are more tokens: anything that ends in } or ] is + // obligated to verify there are more tokens if they are not the top level. + switch (*_json_iter->return_current_and_advance()) { + case '}': + logger::log_end_value(*_json_iter, "object"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between object fields"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_raw(const std::string_view key) noexcept { + error_code error; + bool has_value; + // + // Initially, the object can be in one of a few different places: + // + // 1. The start of the object, at the first field: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + if (at_first_field()) { + has_value = true; + + // + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + return false; + + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + if ((error = skip_child())) { abandon(); return error; } + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + while (has_value) { + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + //if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); // Skip the value entirely + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + + // If the loop ended, we're out of fields to look at. + return false; + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_unordered_raw(const std::string_view key) noexcept { + /** + * When find_field_unordered_raw is called, we can either be pointing at the + * first key, pointing outside (at the closing brace) or if a key was matched + * we can be either pointing right afterthe ':' right before the value (that we need skip), + * or we may have consumed the value and we might be at a comma or at the + * final brace (ready for a call to has_next_field()). + */ + error_code error; + bool has_value; + + // First, we scan from that point to the end. + // If we don't find a match, we may loop back around, and scan from the beginning to that point. + token_position search_start = _json_iter->position(); + + // We want to know whether we need to go back to the beginning. + bool at_first = at_first_field(); + /////////////// + // Initially, the object can be in one of a few different places: + // + // 1. At the first key: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + // + if (at_first) { + has_value = true; + + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { + +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + SIMDJSON_TRY(reset_object().get(has_value)); + at_first = true; + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + // If someone queried a key but they not did access the value, then we are left pointing + // at the ':' and we need to move forward through the value... If the value was + // processed then skip_child() does not move the iterator (but may adjust the depth). + if ((error = skip_child())) { abandon(); return error; } + search_start = _json_iter->position(); + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + + // After initial processing, we will be in one of two states: + // + // ``` + // // At the beginning of a field + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // At the end of the object + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // ``` + // + // Next, we find a match starting from the current position. + while (has_value) { + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + // Performance note: it maybe wasteful to rewind to the beginning when there might be + // no other query following. Indeed, it would require reskipping the whole object. + // Instead, you can just stay where you are. If there is a new query, there is always time + // to rewind. + if (at_first) { return false; } + + // If we reach the end without finding a match, search the rest of the fields starting at the + // beginning of the object. + // (We have already run through the object before, so we've already validated its structure. We + // don't check errors in this bit.) + SIMDJSON_TRY(reset_object().get(has_value)); + while (true) { + SIMDJSON_ASSUME(has_value); // we should reach search_start before ever reaching the end of the object + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + error = field_key().get(actual_key); SIMDJSON_ASSUME(!error); + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + error = field_value(); SIMDJSON_ASSUME(!error); + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // If we reached the end of the key-value pair we started from, then we know + // that the key is not there so we return false. We are either right before + // the next comma or the final brace. + if (_json_iter->position() == search_start) { return false; } + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + error = has_next_field().get(has_value); SIMDJSON_ASSUME(!error); + // If we make the mistake of exiting here, then we could be left pointing at a key + // in the middle of an object. That's not an allowable state. + } + // If the loop ended, we're out of fields to look at. The program should + // never reach this point. + return false; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::field_key() noexcept { + assert_at_next(); + + const uint8_t* key = _json_iter->return_current_and_advance(); + if (*(key++) != '"') { return report_error(TAPE_ERROR, "Object key is not a string"); } + return raw_json_string(key); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::field_value() noexcept { + assert_at_next(); + + if (*_json_iter->return_current_and_advance() != ':') { return report_error(TAPE_ERROR, "Missing colon in object field"); } + _json_iter->descend_to(depth() + 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_root_array(); + } + + inline std::string value_iterator::to_string() const noexcept { + auto answer = std::string("value_iterator [ depth : ") + std::to_string(_depth) + std::string(", "); + if (_json_iter != nullptr) { answer += _json_iter->to_string(); } + answer += std::string(" ]"); + return answer; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_array() noexcept { + assert_at_container_start(); + if (*_json_iter->peek() == ']') { + logger::log_value(*_json_iter, "empty array"); + _json_iter->return_current_and_advance(); + SIMDJSON_TRY(end_container()); + return false; + } + _json_iter->descend_to(depth() + 1); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_array() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // array: e.g., `[1, 2] foo]`. Users concerned with garbage content should + // also call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != ']') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing ] at end"); + } + // If the last character is ] *and* the first gibberish character is also ']' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == ']') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed array. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_array() noexcept { + auto error = check_root_array(); + if (error) { return error; } + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_element() noexcept { + assert_at_next(); + + logger::log_event(*this, "has_next_element"); + switch (*_json_iter->return_current_and_advance()) { + case ']': + logger::log_end_value(*_json_iter, "array"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + _json_iter->descend_to(depth() + 1); + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between array elements"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_bool(const uint8_t* json) const noexcept { + auto not_true = atomparsing::str4ncmp(json, "true"); + auto not_false = atomparsing::str4ncmp(json, "fals") | (json[4] ^ 'e'); + bool error = (not_true && not_false) || jsoncharutils::is_not_structural_or_whitespace(json[not_true ? 5 : 4]); + if (error) { return incorrect_type_error("Not a boolean"); } + return simdjson_result(!not_true); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_null(const uint8_t* json) const noexcept { + bool is_null_string = !atomparsing::str4ncmp(json, "null") && jsoncharutils::is_structural_or_whitespace(json[4]); + // if we start with 'n', we must be a null + if (!is_null_string && json[0] == 'n') { return incorrect_type_error("Not a null but starts with n"); } + return is_null_string; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_string(bool allow_replacement) noexcept { + return get_raw_json_string().unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_string(string_type& receiver, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_string(allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_wobbly_string() noexcept { + return get_raw_json_string().unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_raw_json_string() noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64() noexcept { + auto result = numberparsing::parse_unsigned(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64_in_string() noexcept { + auto result = numberparsing::parse_unsigned_in_string(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64() noexcept { + auto result = numberparsing::parse_integer(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64_in_string() noexcept { + auto result = numberparsing::parse_integer_in_string(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double() noexcept { + auto result = numberparsing::parse_double(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double_in_string() noexcept { + auto result = numberparsing::parse_double_in_string(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_bool() noexcept { + auto result = parse_bool(peek_non_root_scalar("bool")); + if (result.error() == SUCCESS) { advance_non_root_scalar("bool"); } + return result; + } + simdjson_inline simdjson_result value_iterator::is_null() noexcept { + bool is_null_value; + SIMDJSON_TRY(parse_null(peek_non_root_scalar("null")).get(is_null_value)); + if (is_null_value) { advance_non_root_scalar("null"); } + return is_null_value; + } + simdjson_inline bool value_iterator::is_negative() noexcept { + return numberparsing::is_negative(peek_non_root_scalar("numbersign")); + } + simdjson_inline bool value_iterator::is_root_negative() noexcept { + return numberparsing::is_negative(peek_root_scalar("numbersign")); + } + simdjson_inline simdjson_result value_iterator::is_integer() noexcept { + return numberparsing::is_integer(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number_type() noexcept { + return numberparsing::get_number_type(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number() noexcept { + number num; + error_code error = numberparsing::parse_number(peek_non_root_scalar("number"), num); + if (error) { return error; } + return num; + } + + simdjson_inline simdjson_result value_iterator::is_root_integer(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("is_root_integer"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + return false; // if there are more than 20 characters, it cannot be represented as an integer. + } + auto answer = numberparsing::is_integer(tmpbuf); + // If the parsing was a success, we must still check that it is + // a single scalar. Note that we parse first because of cases like '[]' where + // getting TRAILING_CONTENT is wrong. + if (check_trailing && (answer.error() == SUCCESS) && (!_json_iter->is_single_token())) { return TRAILING_CONTENT; } + return answer; + } + + simdjson_inline simdjson_result value_iterator::get_root_number_type(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto answer = numberparsing::get_number_type(tmpbuf); + if (check_trailing && (answer.error() == SUCCESS) && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + return answer; + } + simdjson_inline simdjson_result value_iterator::get_root_number(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + number num; + error_code error = numberparsing::parse_number(tmpbuf, num); + if (error) { return error; } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("number"); + return num; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_string(bool check_trailing, bool allow_replacement) noexcept { + return get_root_raw_json_string(check_trailing).unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_root_string(check_trailing, allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_wobbly_string(bool check_trailing) noexcept { + return get_root_raw_json_string(check_trailing).unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_raw_json_string(bool check_trailing) noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_bool(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("bool"); + uint8_t tmpbuf[5 + 1 + 1]; // +1 for null termination + tmpbuf[5 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 5 + 1)) { return incorrect_type_error("Not a boolean"); } + auto result = parse_bool(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("bool"); + } + return result; + } + simdjson_inline simdjson_result value_iterator::is_root_null(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("null"); + bool result = (max_len >= 4 && !atomparsing::str4ncmp(json, "null") && + (max_len == 4 || jsoncharutils::is_structural_or_whitespace(json[4]))); + if (result) { // we have something that looks like a null. + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("null"); + } + return result; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::skip_child() noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth >= _depth); + + return _json_iter->skip_child(depth()); + } + + simdjson_inline value_iterator value_iterator::child() const noexcept { + assert_at_child(); + return { _json_iter, depth() + 1, _json_iter->token.position() }; + } + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and iterator depth, which is a desired effect. It does not happen if is_open is + // marked non-inline. + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline bool value_iterator::is_open() const noexcept { + return _json_iter->depth() >= depth(); + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool value_iterator::at_end() const noexcept { + return _json_iter->at_end(); + } + + simdjson_inline bool value_iterator::at_start() const noexcept { + return _json_iter->token.position() == start_position(); + } + + simdjson_inline bool value_iterator::at_first_field() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + return _json_iter->token.position() == start_position() + 1; + } + + simdjson_inline void value_iterator::abandon() noexcept { + _json_iter->abandon(); + } + + simdjson_warn_unused simdjson_inline depth_t value_iterator::depth() const noexcept { + return _depth; + } + simdjson_warn_unused simdjson_inline error_code value_iterator::error() const noexcept { + return _json_iter->error; + } + simdjson_warn_unused simdjson_inline uint8_t*& value_iterator::string_buf_loc() noexcept { + return _json_iter->string_buf_loc(); + } + simdjson_warn_unused simdjson_inline const json_iterator& value_iterator::json_iter() const noexcept { + return *_json_iter; + } + simdjson_warn_unused simdjson_inline json_iterator& value_iterator::json_iter() noexcept { + return *_json_iter; + } + + simdjson_inline const uint8_t* value_iterator::peek_start() const noexcept { + return _json_iter->peek(start_position()); + } + simdjson_inline uint32_t value_iterator::peek_start_length() const noexcept { + return _json_iter->peek_length(start_position()); + } + + simdjson_inline const uint8_t* value_iterator::peek_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return peek_start(); } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return; } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept { + logger::log_start_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + const uint8_t* json; + if (!is_at_start()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + json = peek_start(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + } + else { + assert_at_start(); + /** + * We should be prudent. Let us peek. If it is not the right type, we + * return an error. Only once we have determined that we have the right + * type are we allowed to advance! + */ + json = _json_iter->peek(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + _json_iter->return_current_and_advance(); + } + + + return SUCCESS; + } + + + simdjson_inline const uint8_t* value_iterator::peek_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_root(); + return _json_iter->peek(); + } + simdjson_inline const uint8_t* value_iterator::peek_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_non_root_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_root(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + simdjson_inline void value_iterator::advance_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_non_root_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::incorrect_type_error(const char* message) const noexcept { + logger::log_error(*_json_iter, start_position(), depth(), message); + return INCORRECT_TYPE; + } + + simdjson_inline bool value_iterator::is_at_start() const noexcept { + return position() == start_position(); + } + + simdjson_inline bool value_iterator::is_at_key() const noexcept { + // Keys are at the same depth as the object. + // Note here that we could be safer and check that we are within an object, + // but we do not. + return _depth == _json_iter->_depth && *_json_iter->peek() == '"'; + } + + simdjson_inline bool value_iterator::is_at_iterator_start() const noexcept { + // We can legitimately be either at the first value ([1]), or after the array if it's empty ([]). + auto delta = position() - start_position(); + return delta == 1 || delta == 2; + } + + inline void value_iterator::assert_at_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_container_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position + 1); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_next() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + simdjson_inline void value_iterator::move_at_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position); + } + + simdjson_inline void value_iterator::move_at_container_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position + 1); + } + + simdjson_inline simdjson_result value_iterator::reset_array() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_array(); + } + + simdjson_inline simdjson_result value_iterator::reset_object() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_object(); + } + + inline void value_iterator::assert_at_child() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth + 1); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_root() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth == 1); + } + + inline void value_iterator::assert_at_non_root_start() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth > 1); + } + + inline void value_iterator::assert_is_valid() const noexcept { + SIMDJSON_ASSUME(_json_iter != nullptr); + } + + simdjson_inline bool value_iterator::is_valid() const noexcept { + return _json_iter != nullptr; + } + + simdjson_inline simdjson_result value_iterator::type() const noexcept { + switch (*peek_start()) { + case '{': + return json_type::object; + case '[': + return json_type::array; + case '"': + return json_type::string; + case 'n': + return json_type::null; + case 't': case 'f': + return json_type::boolean; + case '-': + case '0': case '1': case '2': case '3': case '4': + case '5': case '6': case '7': case '8': case '9': + return json_type::number; + default: + return TAPE_ERROR; + } + } + + simdjson_inline token_position value_iterator::start_position() const noexcept { + return _start_position; + } + + simdjson_inline token_position value_iterator::position() const noexcept { + return _json_iter->position(); + } + + simdjson_inline token_position value_iterator::end_position() const noexcept { + return _json_iter->end_position(); + } + + simdjson_inline token_position value_iterator::last_position() const noexcept { + return _json_iter->last_position(); + } + + simdjson_inline error_code value_iterator::report_error(error_code error, const char* message) noexcept { + return _json_iter->report_error(error, message); + } + + } // namespace ondemand + } // namespace icelake +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(icelake::ondemand::value_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/value_iterator-inl.h for icelake */ +/* end file simdjson/generic/ondemand/amalgamated.h for icelake */ +/* including simdjson/icelake/end.h: #include "simdjson/icelake/end.h" */ +/* begin file simdjson/icelake/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/icelake/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_ICELAKE +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "icelake" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/icelake/end.h */ + +#endif // SIMDJSON_ICELAKE_ONDEMAND_H +/* end file simdjson/icelake/ondemand.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(ppc64) +/* including simdjson/ppc64/ondemand.h: #include "simdjson/ppc64/ondemand.h" */ +/* begin file simdjson/ppc64/ondemand.h */ +#ifndef SIMDJSON_PPC64_ONDEMAND_H +#define SIMDJSON_PPC64_ONDEMAND_H + +/* including simdjson/ppc64/begin.h: #include "simdjson/ppc64/begin.h" */ +/* begin file simdjson/ppc64/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "ppc64" */ +#define SIMDJSON_IMPLEMENTATION ppc64 +/* including simdjson/ppc64/base.h: #include "simdjson/ppc64/base.h" */ +/* begin file simdjson/ppc64/base.h */ +#ifndef SIMDJSON_PPC64_BASE_H +#define SIMDJSON_PPC64_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Implementation for ALTIVEC (PPC64). + */ + namespace ppc64 { + + class implementation; + + namespace { + namespace simd { + template struct simd8; + template struct simd8x64; + } // namespace simd + } // unnamed namespace + + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_BASE_H +/* end file simdjson/ppc64/base.h */ +/* including simdjson/ppc64/intrinsics.h: #include "simdjson/ppc64/intrinsics.h" */ +/* begin file simdjson/ppc64/intrinsics.h */ +#ifndef SIMDJSON_PPC64_INTRINSICS_H +#define SIMDJSON_PPC64_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// This should be the correct header whether +// you use visual studio or other compilers. +#include + +// These are defined by altivec.h in GCC toolchain, it is safe to undef them. +#ifdef bool +#undef bool +#endif + +#ifdef vector +#undef vector +#endif + +static_assert(sizeof(__vector unsigned char) <= simdjson::SIMDJSON_PADDING, "insufficient padding for ppc64"); + +#endif // SIMDJSON_PPC64_INTRINSICS_H +/* end file simdjson/ppc64/intrinsics.h */ +/* including simdjson/ppc64/bitmanipulation.h: #include "simdjson/ppc64/bitmanipulation.h" */ +/* begin file simdjson/ppc64/bitmanipulation.h */ +#ifndef SIMDJSON_PPC64_BITMANIPULATION_H +#define SIMDJSON_PPC64_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline int count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num); // Visual Studio wants two underscores + } +#else + simdjson_inline int count_ones(uint64_t input_num) { + return __builtin_popcountll(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + * result = value1 + value2; + return *result < value1; +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_BITMANIPULATION_H +/* end file simdjson/ppc64/bitmanipulation.h */ +/* including simdjson/ppc64/bitmask.h: #include "simdjson/ppc64/bitmask.h" */ +/* begin file simdjson/ppc64/bitmask.h */ +#ifndef SIMDJSON_PPC64_BITMASK_H +#define SIMDJSON_PPC64_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is + // encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(uint64_t bitmask) { + // You can use the version below, however gcc sometimes miscompiles + // vec_pmsum_be, it happens somewhere around between 8 and 9th version. + // The performance boost was not noticeable, falling back to a usual + // implementation. + // __vector unsigned long long all_ones = {~0ull, ~0ull}; + // __vector unsigned long long mask = {bitmask, 0}; + // // Clang and GCC return different values for pmsum for ull so cast it to one. + // // Generally it is not specified by ALTIVEC ISA what is returned by + // // vec_pmsum_be. + // #if defined(__LITTLE_ENDIAN__) + // return (uint64_t)(((__vector unsigned long long)vec_pmsum_be(all_ones, mask))[0]); + // #else + // return (uint64_t)(((__vector unsigned long long)vec_pmsum_be(all_ones, mask))[1]); + // #endif + bitmask ^= bitmask << 1; + bitmask ^= bitmask << 2; + bitmask ^= bitmask << 4; + bitmask ^= bitmask << 8; + bitmask ^= bitmask << 16; + bitmask ^= bitmask << 32; + return bitmask; + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif +/* end file simdjson/ppc64/bitmask.h */ +/* including simdjson/ppc64/numberparsing_defs.h: #include "simdjson/ppc64/numberparsing_defs.h" */ +/* begin file simdjson/ppc64/numberparsing_defs.h */ +#ifndef SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +#define SIMDJSON_PPC64_NUMBERPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/intrinsics.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +#if defined(__linux__) +#include +#elif defined(__FreeBSD__) +#include +#endif + +namespace simdjson { + namespace ppc64 { + namespace numberparsing { + + // we don't have appropriate instructions, so let us use a scalar function + // credit: https://johnnylee-sde.github.io/Fast-numeric-string-to-int/ + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + uint64_t val; + std::memcpy(&val, chars, sizeof(uint64_t)); +#ifdef __BIG_ENDIAN__ +#if defined(__linux__) + val = bswap_64(val); +#elif defined(__FreeBSD__) + val = bswap64(val); +#endif +#endif + val = (val & 0x0F0F0F0F0F0F0F0F) * 2561 >> 8; + val = (val & 0x00FF00FF00FF00FF) * 6553601 >> 16; + return uint32_t((val & 0x0000FFFF0000FFFF) * 42949672960001 >> 32); + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace ppc64 +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_PPC64_NUMBERPARSING_DEFS_H +/* end file simdjson/ppc64/numberparsing_defs.h */ +/* including simdjson/ppc64/simd.h: #include "simdjson/ppc64/simd.h" */ +/* begin file simdjson/ppc64/simd.h */ +#ifndef SIMDJSON_PPC64_SIMD_H +#define SIMDJSON_PPC64_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace ppc64 { + namespace { + namespace simd { + + using __m128i = __vector unsigned char; + + template struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { + return this->value; + } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { + return vec_or(this->value, (__m128i)other); + } + simdjson_inline Child operator&(const Child other) const { + return vec_and(this->value, (__m128i)other); + } + simdjson_inline Child operator^(const Child other) const { + return vec_xor(this->value, (__m128i)other); + } + simdjson_inline Child bit_andnot(const Child other) const { + return vec_andc(this->value, (__m128i)other); + } + simdjson_inline Child& operator|=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast | other; + return *this_cast; + } + simdjson_inline Child& operator&=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast & other; + return *this_cast; + } + simdjson_inline Child& operator^=(const Child other) { + auto this_cast = static_cast(this); + *this_cast = *this_cast ^ other; + return *this_cast; + } + }; + + template > + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { + return (__m128i)vec_cmpeq(lhs.value, (__m128i)rhs); + } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(simd8 prev_chunk) const { + __m128i chunk = this->value; +#ifdef __LITTLE_ENDIAN__ + chunk = (__m128i)vec_reve(this->value); + prev_chunk = (__m128i)vec_reve((__m128i)prev_chunk); +#endif + chunk = (__m128i)vec_sld((__m128i)prev_chunk, (__m128i)chunk, 16 - N); +#ifdef __LITTLE_ENDIAN__ + chunk = (__m128i)vec_reve((__m128i)chunk); +#endif + return chunk; + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template <> struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { + return (__m128i)vec_splats((unsigned char)(-(!!_value))); + } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) + : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) + : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { + __vector unsigned long long result; + const __m128i perm_mask = { 0x78, 0x70, 0x68, 0x60, 0x58, 0x50, 0x48, 0x40, + 0x38, 0x30, 0x28, 0x20, 0x18, 0x10, 0x08, 0x00 }; + + result = ((__vector unsigned long long)vec_vbpermq((__m128i)this->value, + (__m128i)perm_mask)); +#ifdef __LITTLE_ENDIAN__ + return static_cast(result[1]); +#else + return static_cast(result[0]); +#endif + } + simdjson_inline bool any() const { + return !vec_all_eq(this->value, (__m128i)vec_splats(0)); + } + simdjson_inline simd8 operator~() const { + return this->value ^ (__m128i)splat(true); + } + }; + + template struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T value) { + (void)value; + return (__m128i)vec_splats(value); + } + static simdjson_inline simd8 zero() { return splat(0); } + static simdjson_inline simd8 load(const T values[16]) { + return (__m128i)(vec_vsx_ld(0, reinterpret_cast(values))); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16(T v0, T v1, T v2, T v3, T v4, + T v5, T v6, T v7, T v8, T v9, + T v10, T v11, T v12, T v13, + T v14, T v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, v13, + v14, v15); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) + : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { + vec_vsx_st(this->value, 0, reinterpret_cast<__m128i*>(dst)); + } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { + return (__m128i)((__m128i)this->value + (__m128i)other); + } + simdjson_inline simd8 operator-(const simd8 other) const { + return (__m128i)((__m128i)this->value - (__m128i)other); + } + simdjson_inline simd8& operator+=(const simd8 other) { + *this = *this + other; + return *static_cast *>(this); + } + simdjson_inline simd8& operator-=(const simd8 other) { + *this = *this - other; + return *static_cast *>(this); + } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior + // for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return (__m128i)vec_perm((__m128i)lookup_table, (__m128i)lookup_table, this->value); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted + // as a bitset). Passing a 0 value for mask would be equivalent to writing out + // every byte to output. Only the first 16 - count_ones(mask) bytes of the + // result are significant but 16 bytes get written. Design consideration: it + // seems like a function with the signature simd8 compress(uint32_t mask) + // would be sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + using internal::thintable_epi8; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. +#ifdef __LITTLE_ENDIAN__ + __m128i shufmask = (__m128i)(__vector unsigned long long) { + thintable_epi8[mask1], thintable_epi8[mask2] + }; +#else + __m128i shufmask = (__m128i)(__vector unsigned long long) { + thintable_epi8[mask2], thintable_epi8[mask1] + }; + shufmask = (__m128i)vec_reve((__m128i)shufmask); +#endif + // we increment by 0x08 the second half of the mask + shufmask = ((__m128i)shufmask) + + ((__m128i)(__vector int) { 0, 0, 0x08080808, 0x08080808 }); + + // this is the version "nearly pruned" + __m128i pruned = vec_perm(this->value, this->value, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + vec_vsx_ld(0, reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = vec_perm(pruned, (__m128i)vec_splats(0), compactmask); + vec_vsx_st(answer, 0, reinterpret_cast<__m128i*>(output)); + } + + template + simdjson_inline simd8 + lookup_16(L replace0, L replace1, L replace2, L replace3, L replace4, + L replace5, L replace6, L replace7, L replace8, L replace9, + L replace10, L replace11, L replace12, L replace13, L replace14, + L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, replace4, replace5, replace6, + replace7, replace8, replace9, replace10, replace11, replace12, + replace13, replace14, replace15)); + } + }; + + // Signed bytes + template <> struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) + : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8(int8_t v0, int8_t v1, int8_t v2, int8_t v3, + int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, + int8_t v12, int8_t v13, int8_t v14, int8_t v15) + : simd8((__m128i)(__vector signed char) { + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, + v15 + }) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, + int8_t v6, int8_t v7, int8_t v8, int8_t v9, int8_t v10, int8_t v11, + int8_t v12, int8_t v13, int8_t v14, int8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } + + // Order-sensitive comparisons + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return (__m128i)vec_cmpgt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return (__m128i)vec_cmplt((__vector signed char)this->value, + (__vector signed char)(__m128i)other); + } + }; + + // Unsigned bytes + template <> struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) + : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline + simd8(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, + uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, uint8_t v10, + uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15) + : simd8((__m128i) { + v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15 + }) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 + repeat_16(uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, + uint8_t v5, uint8_t v6, uint8_t v7, uint8_t v8, uint8_t v9, + uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, + uint8_t v15) { + return simd8(v0, v1, v2, v3, v4, v5, v6, v7, v8, v9, v10, v11, v12, + v13, v14, v15); + } + + // Saturated math + simdjson_inline simd8 + saturating_add(const simd8 other) const { + return (__m128i)vec_adds(this->value, (__m128i)other); + } + simdjson_inline simd8 + saturating_sub(const simd8 other) const { + return (__m128i)vec_subs(this->value, (__m128i)other); + } + + // Order-specific operations + simdjson_inline simd8 + max_val(const simd8 other) const { + return (__m128i)vec_max(this->value, (__m128i)other); + } + simdjson_inline simd8 + min_val(const simd8 other) const { + return (__m128i)vec_min(this->value, (__m128i)other); + } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + gt_bits(const simd8 other) const { + return this->saturating_sub(other); + } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 + lt_bits(const simd8 other) const { + return other.saturating_sub(*this); + } + simdjson_inline simd8 + operator<=(const simd8 other) const { + return other.max_val(*this) == other; + } + simdjson_inline simd8 + operator>=(const simd8 other) const { + return other.min_val(*this) == other; + } + simdjson_inline simd8 + operator>(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } + simdjson_inline simd8 + operator<(const simd8 other) const { + return this->gt_bits(other).any_bits_set(); + } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { + return (__m128i)vec_cmpeq(this->value, (__m128i)vec_splats(uint8_t(0))); + } + simdjson_inline simd8 bits_not_set(simd8 bits) const { + return (*this & bits).bits_not_set(); + } + simdjson_inline simd8 any_bits_set() const { + return ~this->bits_not_set(); + } + simdjson_inline simd8 any_bits_set(simd8 bits) const { + return ~this->bits_not_set(bits); + } + simdjson_inline bool bits_not_set_anywhere() const { + return vec_all_eq(this->value, (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere() const { + return !bits_not_set_anywhere(); + } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { + return vec_all_eq(vec_and(this->value, (__m128i)bits), + (__m128i)vec_splats(0)); + } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { + return !bits_not_set_anywhere(bits); + } + template simdjson_inline simd8 shr() const { + return simd8( + (__m128i)vec_sr(this->value, (__m128i)vec_splat_u8(N))); + } + template simdjson_inline simd8 shl() const { + return simd8( + (__m128i)vec_sl(this->value, (__m128i)vec_splat_u8(N))); + } + }; + + template struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, + "PPC64 kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& + operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, + const simd8 chunk2, const simd8 chunk3) + : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) + : chunks{ simd8::load(ptr), simd8::load(ptr + 16), + simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | + (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), + output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), + output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), + output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64(this->chunks[0] == mask, this->chunks[1] == mask, + this->chunks[2] == mask, this->chunks[3] == mask) + .to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64(this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3]) + .to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64(this->chunks[0] <= mask, this->chunks[1] <= mask, + this->chunks[2] <= mask, this->chunks[3] <= mask) + .to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_SIMD_INPUT_H +/* end file simdjson/ppc64/simd.h */ +/* including simdjson/ppc64/stringparsing_defs.h: #include "simdjson/ppc64/stringparsing_defs.h" */ +/* begin file simdjson/ppc64/stringparsing_defs.h */ +#ifndef SIMDJSON_PPC64_STRINGPARSING_DEFS_H +#define SIMDJSON_PPC64_STRINGPARSING_DEFS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/simd.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote + copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { + return ((bs_bits - 1) & quote_bits) != 0; + } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { + return trailing_zeroes(quote_bits); + } + simdjson_inline int backslash_index() { + return trailing_zeroes(bs_bits); + } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote + backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), + "backslash and quote finder must process fewer than " + "SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + sizeof(v0)); + v0.store(dst); + v1.store(dst + sizeof(v0)); + + // Getting a 64-bit bitmask is much cheaper than multiple 16-bit bitmasks on + // PPC; therefore, we smash them together into a 64-byte mask and get the + // bitmask from there. + uint64_t bs_and_quote = + simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_PPC64_STRINGPARSING_DEFS_H +/* end file simdjson/ppc64/stringparsing_defs.h */ + +#define SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT 1 +/* end file simdjson/ppc64/begin.h */ +/* including simdjson/generic/ondemand/amalgamated.h for ppc64: #include "simdjson/generic/ondemand/amalgamated.h" */ +/* begin file simdjson/generic/ondemand/amalgamated.h for ppc64 */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H) +#error simdjson/generic/ondemand/dependencies.h must be included before simdjson/generic/ondemand/amalgamated.h! +#endif + +// Stuff other things depend on +/* including simdjson/generic/ondemand/base.h for ppc64: #include "simdjson/generic/ondemand/base.h" */ +/* begin file simdjson/generic/ondemand/base.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + /** + * A fast, simple, DOM-like interface that parses JSON as you use it. + * + * Designed for maximum speed and a lower memory profile. + */ + namespace ondemand { + + /** Represents the depth of a JSON value (number of nested arrays/objects). */ + using depth_t = int32_t; + + /** @copydoc simdjson::ppc64::number_type */ + using number_type = simdjson::ppc64::number_type; + + /** @private Position in the JSON buffer indexes */ + using token_position = const uint32_t*; + + class array; + class array_iterator; + class document; + class document_reference; + class document_stream; + class field; + class json_iterator; + enum class json_type; + struct number; + class object; + class object_iterator; + class parser; + class raw_json_string; + class token_iterator; + class value; + class value_iterator; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_BASE_H +/* end file simdjson/generic/ondemand/base.h for ppc64 */ +/* including simdjson/generic/ondemand/value_iterator.h for ppc64: #include "simdjson/generic/ondemand/value_iterator.h" */ +/* begin file simdjson/generic/ondemand/value_iterator.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * Iterates through a single JSON value at a particular depth. + * + * Does not keep track of the type of value: provides methods for objects, arrays and scalars and expects + * the caller to call the right ones. + * + * @private This is not intended for external use. + */ + class value_iterator { + protected: + /** The underlying JSON iterator */ + json_iterator* _json_iter{}; + /** The depth of this value */ + depth_t _depth{}; + /** + * The starting token index for this value + */ + token_position _start_position{}; + + public: + simdjson_inline value_iterator() noexcept = default; + + /** + * Denote that we're starting a document. + */ + simdjson_inline void start_document() noexcept; + + /** + * Skips a non-iterated or partially-iterated JSON value, whether it is a scalar, array or object. + * + * Optimized for scalars. + */ + simdjson_warn_unused simdjson_inline error_code skip_child() noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is at the start of the value + */ + simdjson_inline bool at_start() const noexcept; + + /** + * Tell whether the value is open--if the value has not been used, or the array/object is still open. + */ + simdjson_inline bool is_open() const noexcept; + + /** + * Tell whether the value is at an object's first field (just after the {). + */ + simdjson_inline bool at_first_field() const noexcept; + + /** + * Abandon all iteration. + */ + simdjson_inline void abandon() noexcept; + + /** + * Get the child value as a value_iterator. + */ + simdjson_inline value_iterator child_value() const noexcept; + + /** + * Get the depth of this value. + */ + simdjson_inline int32_t depth() const noexcept; + + /** + * Get the JSON type of this value. + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() const noexcept; + + /** + * @addtogroup object Object iteration + * + * Methods to iterate and find object fields. These methods generally *assume* the value is + * actually an object; the caller is responsible for keeping track of that fact. + * + * @{ + */ + + /** + * Start an object iteration. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + */ + simdjson_warn_unused simdjson_inline simdjson_result start_object() noexcept; + /** + * Start an object iteration from the root. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_object() noexcept; + /** + * Checks whether an object could be started from the root. May be called by start_root_object. + * + * @returns SUCCESS if it is possible to safely start an object from the root (document level). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_object() noexcept; + /** + * Start an object iteration after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_object() noexcept; + /** + * Start an object iteration from the root, after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_object() noexcept; + + /** + * Moves to the next field in an object. + * + * Looks for , and }. If } is found, the object is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return whether there is another field in the object. + * @error TAPE_ERROR If there is a comma missing between fields. + * @error TAPE_ERROR If there is a comma, but not enough tokens remaining to have a key, :, and value. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_field() noexcept; + + /** + * Get the current field's key. + */ + simdjson_warn_unused simdjson_inline simdjson_result field_key() noexcept; + + /** + * Pass the : in the field and move to its value. + */ + simdjson_warn_unused simdjson_inline error_code field_value() noexcept; + + /** + * Find the next field with the given key. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline error_code find_field(const std::string_view key) noexcept; + + /** + * Find the next field with the given key, *without* unescaping. This assumes object order: it + * will not find the field if it was already passed when looking for some *other* field. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_raw(const std::string_view key) noexcept; + + /** + * Find the field with the given key without regard to order, and *without* unescaping. + * + * This is an unordered object lookup: if the field is not found initially, it will cycle around and scan from the beginning. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_unordered_raw(const std::string_view key) noexcept; + + /** @} */ + + /** + * @addtogroup array Array iteration + * Methods to iterate over array elements. These methods generally *assume* the value is actually + * an object; the caller is responsible for keeping track of that fact. + * @{ + */ + + /** + * Check for an opening [ and start an array iteration. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + */ + simdjson_warn_unused simdjson_inline simdjson_result start_array() noexcept; + /** + * Check for an opening [ and start an array iteration while at the root. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_array() noexcept; + /** + * Checks whether an array could be started from the root. May be called by start_root_array. + * + * @returns SUCCESS if it is possible to safely start an array from the root (document level). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_array() noexcept; + /** + * Start an array iteration, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_array() noexcept; + /** + * Start an array iteration from the root, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_array() noexcept; + + /** + * Moves to the next element in an array. + * + * Looks for , and ]. If ] is found, the array is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return Whether there is another element in the array. + * @error TAPE_ERROR If there is a comma missing between elements. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_element() noexcept; + + /** + * Get a child value iterator. + */ + simdjson_warn_unused simdjson_inline value_iterator child() const noexcept; + + /** @} */ + + /** + * @defgroup scalar Scalar values + * @addtogroup scalar + * @{ + */ + + simdjson_warn_unused simdjson_inline simdjson_result get_string(bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_bool() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_null() noexcept; + simdjson_warn_unused simdjson_inline bool is_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_integer() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + simdjson_warn_unused simdjson_inline simdjson_result get_root_string(bool check_trailing, bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_wobbly_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_raw_json_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_bool(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline bool is_root_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_integer(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number_type(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_null(bool check_trailing) noexcept; + + simdjson_inline error_code error() const noexcept; + simdjson_inline uint8_t*& string_buf_loc() noexcept; + simdjson_inline const json_iterator& json_iter() const noexcept; + simdjson_inline json_iterator& json_iter() noexcept; + + simdjson_inline void assert_is_valid() const noexcept; + simdjson_inline bool is_valid() const noexcept; + + /** @} */ + protected: + /** + * Restarts an array iteration. + * @returns Whether the array has any elements (returns false for empty). + */ + simdjson_inline simdjson_result reset_array() noexcept; + /** + * Restarts an object iteration. + * @returns Whether the object has any fields (returns false for empty). + */ + simdjson_inline simdjson_result reset_object() noexcept; + /** + * move_at_start(): moves us so that we are pointing at the beginning of + * the container. It updates the index so that at_start() is true and it + * syncs the depth. The user can then create a new container instance. + * + * Usage: used with value::count_elements(). + **/ + simdjson_inline void move_at_start() noexcept; + + /** + * move_at_container_start(): moves us so that we are pointing at the beginning of + * the container so that assert_at_container_start() passes. + * + * Usage: used with reset_array() and reset_object(). + **/ + simdjson_inline void move_at_container_start() noexcept; + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + simdjson_inline value_iterator(json_iterator* json_iter, depth_t depth, token_position start_index) noexcept; + + simdjson_inline simdjson_result parse_null(const uint8_t* json) const noexcept; + simdjson_inline simdjson_result parse_bool(const uint8_t* json) const noexcept; + simdjson_inline const uint8_t* peek_start() const noexcept; + simdjson_inline uint32_t peek_start_length() const noexcept; + + /** + * The general idea of the advance_... methods and the peek_* methods + * is that you first peek and check that you have desired type. If you do, + * and only if you do, then you advance. + * + * We used to unconditionally advance. But this made reasoning about our + * current state difficult. + * Suppose you always advance. Look at the 'value' matching the key + * "shadowable" in the following example... + * + * ({"globals":{"a":{"shadowable":[}}}}) + * + * If the user thinks it is a Boolean and asks for it, then we check the '[', + * decide it is not a Boolean, but still move into the next character ('}'). Now + * we are left pointing at '}' right after a '['. And we have not yet reported + * an error, only that we do not have a Boolean. + * + * If, instead, you just stand your ground until it is content that you know, then + * you will only even move beyond the '[' if the user tells you that you have an + * array. So you will be at the '}' character inside the array and, hopefully, you + * will then catch the error because an array cannot start with '}', but the code + * processing Boolean values does not know this. + * + * So the contract is: first call 'peek_...' and then call 'advance_...' only + * if you have determined that it is a type you can handle. + * + * Unfortunately, it makes the code more verbose, longer and maybe more error prone. + */ + + simdjson_inline void advance_scalar(const char* type) noexcept; + simdjson_inline void advance_root_scalar(const char* type) noexcept; + simdjson_inline void advance_non_root_scalar(const char* type) noexcept; + + simdjson_inline const uint8_t* peek_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_root_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_non_root_scalar(const char* type) noexcept; + + + simdjson_inline error_code start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept; + simdjson_inline error_code end_container() noexcept; + + /** + * Advance to a place expecting a value (increasing depth). + * + * @return The current token (the one left behind). + * @error TAPE_ERROR If the document ended early. + */ + simdjson_inline simdjson_result advance_to_value() noexcept; + + simdjson_inline error_code incorrect_type_error(const char* message) const noexcept; + simdjson_inline error_code error_unless_more_tokens(uint32_t tokens = 1) const noexcept; + + simdjson_inline bool is_at_start() const noexcept; + /** + * is_at_iterator_start() returns true on an array or object after it has just been + * created, whether the instance is empty or not. + * + * Usage: used by array::begin() in debug mode (SIMDJSON_DEVELOPMENT_CHECKS) + */ + simdjson_inline bool is_at_iterator_start() const noexcept; + + /** + * Assuming that we are within an object, this returns true if we + * are pointing at a key. + * + * Usage: the skip_child() method should never be used while we are pointing + * at a key inside an object. + */ + simdjson_inline bool is_at_key() const noexcept; + + inline void assert_at_start() const noexcept; + inline void assert_at_container_start() const noexcept; + inline void assert_at_root() const noexcept; + inline void assert_at_child() const noexcept; + inline void assert_at_next() const noexcept; + inline void assert_at_non_root_start() const noexcept; + + /** Get the starting position of this value */ + simdjson_inline token_position start_position() const noexcept; + + /** @copydoc error_code json_iterator::position() const noexcept; */ + simdjson_inline token_position position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position last_position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position end_position() const noexcept; + /** @copydoc error_code json_iterator::report_error(error_code error, const char *message) noexcept; */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + friend class document; + friend class object; + friend class array; + friend class value; + }; // value_iterator + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::value_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H +/* end file simdjson/generic/ondemand/value_iterator.h for ppc64 */ +/* including simdjson/generic/ondemand/value.h for ppc64: #include "simdjson/generic/ondemand/value.h" */ +/* begin file simdjson/generic/ondemand/value.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * An ephemeral JSON value returned during iteration. It is only valid for as long as you do + * not access more data in the JSON document. + */ + class value { + public: + /** + * Create a new invalid value. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline value() noexcept = default; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) noexcept; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() noexcept; + + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() noexcept; + + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + + /** + * Cast this JSON value (inside string) to a unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + + /** + * Cast this JSON value to a "wobbly" string. + * + * The string is may not be a valid UTF-8 string. + * See https://simonsapin.github.io/wtf-8/ + * + * Important: a value should be consumed once. Calling get_wobbly_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); +#endif + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + * + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * Performance hint: You should only call count_elements() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method on the object instance. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @return The type of JSON value (json_type::array, json_type::object, json_type::string, + * json_type::number, json_type::boolean, or json_type::null). + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the value is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the value is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the value is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * Performance note: if you call this function systematically + * before parsing a number, you may have fallen for a performance + * anti-pattern. + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + * + * Performance note: this is designed with performance in mind. When + * calling 'get_number()', you scan the number string only once, determining + * efficiently the type and storing it in an efficient manner. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. However, if this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view is guaranteed to be + * a non-space token. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + * + * See also value::raw_json(). + */ + simdjson_inline std::string_view raw_json_token() noexcept; + + /** + * Get a string_view pointing at this value in the JSON document. + * If this element is an array or an object, it consumes the array or the object + * and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + * If this element is a scalar (string, number, Boolean, null), it returns what + * raw_json_token() would return. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + simdjson_inline simdjson_result current_location() noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. + * + * Calling at_pointer() on non-document instances (e.g., arrays and objects) is not + * standardized (by RFC 6901). We provide some experimental support for JSON pointers + * on non-document instances. Yet it is not the case when calling at_pointer on an array + * or an object instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + protected: + /** + * Create a value. + */ + simdjson_inline value(const value_iterator& iter) noexcept; + + /** + * Skip this value, allowing iteration to continue. + */ + simdjson_inline void skip() noexcept; + + /** + * Start a value at the current position. + * + * (It should already be started; this is just a self-documentation method.) + */ + static simdjson_inline value start(const value_iterator& iter) noexcept; + + /** + * Resume a value. + */ + static simdjson_inline value resume(const value_iterator& iter) noexcept; + + /** + * Get the object, starting or resuming it as necessary + */ + simdjson_inline simdjson_result start_or_resume_object() noexcept; + + // simdjson_inline void log_value(const char *type) const noexcept; + // simdjson_inline void log_error(const char *message) const noexcept; + + value_iterator iter{}; + + friend class document; + friend class array_iterator; + friend class field; + friend class object; + friend struct simdjson_result; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::value&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result get_array() noexcept; + simdjson_inline simdjson_result get_object() noexcept; + + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() noexcept; + + template simdjson_inline error_code get(T& out) noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator ppc64::ondemand::array() noexcept(false); + simdjson_inline operator ppc64::ondemand::object() noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator ppc64::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + */ + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + + /** @copydoc simdjson_inline std::string_view value::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + /** @copydoc simdjson_inline simdjson_result current_location() noexcept */ + simdjson_inline simdjson_result current_location() noexcept; + /** @copydoc simdjson_inline int32_t current_depth() const noexcept */ + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_H +/* end file simdjson/generic/ondemand/value.h for ppc64 */ +/* including simdjson/generic/ondemand/logger.h for ppc64: #include "simdjson/generic/ondemand/logger.h" */ +/* begin file simdjson/generic/ondemand/logger.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + // Logging should be free unless SIMDJSON_VERBOSE_LOGGING is set. Importantly, it is critical + // that the call to the log functions be side-effect free. Thus, for example, you should not + // create temporary std::string instances. + namespace logger { + + enum class log_level : int32_t { + info = 0, + error = 1 + }; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + + // We do not want these functions to be 'really inlined' since real inlining is + // for performance purposes and if you are using the loggers, you do not care about + // performance (or should not). + static inline void log_headers() noexcept; + // If args are provided, title will be treated as format string + template + static inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + template + static inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + static inline void log_event(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_value(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_start_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail = "") noexcept; + static inline void log_error(const json_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_event(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_error(const value_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + } // namespace logger + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_H +/* end file simdjson/generic/ondemand/logger.h for ppc64 */ +/* including simdjson/generic/ondemand/token_iterator.h for ppc64: #include "simdjson/generic/ondemand/token_iterator.h" */ +/* begin file simdjson/generic/ondemand/token_iterator.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * Iterates through JSON tokens (`{` `}` `[` `]` `,` `:` `""` `123` `true` `false` `null`) + * detected by stage 1. + * + * @private This is not intended for external use. + */ + class token_iterator { + public: + /** + * Create a new invalid token_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline token_iterator() noexcept = default; + simdjson_inline token_iterator(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator& operator=(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator(const token_iterator& other) noexcept = default; + simdjson_inline token_iterator& operator=(const token_iterator& other) noexcept = default; + + /** + * Advance to the next token (returning the current one). + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + /** + * Reports the current offset in bytes from the start of the underlying buffer. + */ + simdjson_inline uint32_t current_offset() const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + + /** + * Return the current index. + */ + simdjson_inline token_position position() const noexcept; + /** + * Reset to a previously saved index. + */ + simdjson_inline void set_position(token_position target_position) noexcept; + + // NOTE: we don't support a full C++ iterator interface, because we expect people to make + // different calls to advance the iterator based on *their own* state. + + simdjson_inline bool operator==(const token_iterator& other) const noexcept; + simdjson_inline bool operator!=(const token_iterator& other) const noexcept; + simdjson_inline bool operator>(const token_iterator& other) const noexcept; + simdjson_inline bool operator>=(const token_iterator& other) const noexcept; + simdjson_inline bool operator<(const token_iterator& other) const noexcept; + simdjson_inline bool operator<=(const token_iterator& other) const noexcept; + + protected: + simdjson_inline token_iterator(const uint8_t* buf, token_position position) noexcept; + + /** + * Get the index of the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_index(int32_t delta = 0) const noexcept; + /** + * Get the index of the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline uint32_t peek_index(token_position position) const noexcept; + + const uint8_t* buf{}; + token_position _position{}; + + friend class json_iterator; + friend class value_iterator; + friend class object; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::token_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H +/* end file simdjson/generic/ondemand/token_iterator.h for ppc64 */ +/* including simdjson/generic/ondemand/json_iterator.h for ppc64: #include "simdjson/generic/ondemand/json_iterator.h" */ +/* begin file simdjson/generic/ondemand/json_iterator.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * Iterates through JSON tokens, keeping track of depth and string buffer. + * + * @private This is not intended for external use. + */ + class json_iterator { + protected: + token_iterator token{}; + ondemand::parser* parser{}; + /** + * Next free location in the string buffer. + * + * Used by raw_json_string::unescape() to have a place to unescape strings to. + */ + uint8_t* _string_buf_loc{}; + /** + * JSON error, if there is one. + * + * INCORRECT_TYPE and NO_SUCH_FIELD are *not* stored here, ever. + * + * PERF NOTE: we *hope* this will be elided into control flow, as it is only used (a) in the first + * iteration of the loop, or (b) for the final iteration after a missing comma is found in ++. If + * this is not elided, we should make sure it's at least not using up a register. Failing that, + * we should store it in document so there's only one of them. + */ + error_code error{ SUCCESS }; + /** + * Depth of the current token in the JSON. + * + * - 0 = finished with document + * - 1 = document root value (could be [ or {, not yet known) + * - 2 = , or } inside root array/object + * - 3 = key or value inside root array/object. + */ + depth_t _depth{}; + /** + * Beginning of the document indexes. + * Normally we have root == parser->implementation->structural_indexes.get() + * but this may differ, especially in streaming mode (where we have several + * documents); + */ + token_position _root{}; + /** + * Normally, a json_iterator operates over a single document, but in + * some cases, we may have a stream of documents. This attribute is meant + * as meta-data: the json_iterator works the same irrespective of the + * value of this attribute. + */ + bool _streaming{ false }; + + public: + simdjson_inline json_iterator() noexcept = default; + simdjson_inline json_iterator(json_iterator&& other) noexcept; + simdjson_inline json_iterator& operator=(json_iterator&& other) noexcept; + simdjson_inline explicit json_iterator(const json_iterator& other) noexcept = default; + simdjson_inline json_iterator& operator=(const json_iterator& other) noexcept = default; + /** + * Skips a JSON value, whether it is a scalar, array or object. + */ + simdjson_warn_unused simdjson_inline error_code skip_child(depth_t parent_depth) noexcept; + + /** + * Tell whether the iterator is still at the start + */ + simdjson_inline bool at_root() const noexcept; + + /** + * Tell whether we should be expected to run in streaming + * mode (iterating over many documents). It is pure metadata + * that does not affect how the iterator works. It is used by + * start_root_array() and start_root_object(). + */ + simdjson_inline bool streaming() const noexcept; + + /** + * Get the root value iterator + */ + simdjson_inline token_position root_position() const noexcept; + /** + * Assert that we are at the document depth (== 1) + */ + simdjson_inline void assert_at_document_depth() const noexcept; + /** + * Assert that we are at the root of the document + */ + simdjson_inline void assert_at_root() const noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is live (has not been moved). + */ + simdjson_inline bool is_alive() const noexcept; + + /** + * Abandon this iterator, setting depth to 0 (as if the document is finished). + */ + simdjson_inline void abandon() noexcept; + + /** + * Advance the current token without modifying depth. + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + + /** + * Returns true if there is a single token in the index (i.e., it is + * a JSON with a scalar value such as a single number). + * + * @return whether there is a single token + */ + simdjson_inline bool is_single_token() const noexcept; + + /** + * Assert that there are at least the given number of tokens left. + * + * Has no effect in release builds. + */ + simdjson_inline void assert_more_tokens(uint32_t required_tokens = 1) const noexcept; + /** + * Assert that the given position addresses an actual token (is within bounds). + * + * Has no effect in release builds. + */ + simdjson_inline void assert_valid_position(token_position position) const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + /** + * Get a pointer to the current location in the input buffer. + * + * This is not null-terminated; it is a view into the JSON. + * + * You may be pointing outside of the input buffer: it is not generally + * safe to dereference this pointer. + */ + simdjson_inline const uint8_t* unsafe_pointer() const noexcept; + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token to retrieve. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token to retrieve. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + /** + * Get the JSON text for the last token in the document. + * + * This is not null-terminated; it is a view into the JSON. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek_last() const noexcept; + + /** + * Ascend one level. + * + * Validates that the depth - 1 == parent_depth. + * + * @param parent_depth the expected parent depth. + */ + simdjson_inline void ascend_to(depth_t parent_depth) noexcept; + + /** + * Descend one level. + * + * Validates that the new depth == child_depth. + * + * @param child_depth the expected child depth. + */ + simdjson_inline void descend_to(depth_t child_depth) noexcept; + simdjson_inline void descend_to(depth_t child_depth, int32_t delta) noexcept; + + /** + * Get current depth. + */ + simdjson_inline depth_t depth() const noexcept; + + /** + * Get current (writeable) location in the string buffer. + */ + simdjson_inline uint8_t*& string_buf_loc() noexcept; + + /** + * Report an unrecoverable error, preventing further iteration. + * + * @param error The error to report. Must not be SUCCESS, UNINITIALIZED, INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + /** + * Log error, but don't stop iteration. + * @param error The error to report. Must be INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code optional_error(error_code error, const char* message) noexcept; + + /** + * Take an input in json containing max_len characters and attempt to copy it over to tmpbuf, a buffer with + * N bytes of capacity. It will return false if N is too small (smaller than max_len) of if it is zero. + * The buffer (tmpbuf) is padded with space characters. + */ + simdjson_warn_unused simdjson_inline bool copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept; + + simdjson_inline token_position position() const noexcept; + /** + * Write the raw_json_string to the string buffer and return a string_view. + * Each raw_json_string should be unescaped once, or else the string buffer might + * overflow. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, bool allow_replacement) noexcept; + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in) noexcept; + + simdjson_inline void reenter_child(token_position position, depth_t child_depth) noexcept; + + simdjson_inline error_code consume_character(char c) noexcept; +#if SIMDJSON_DEVELOPMENT_CHECKS + simdjson_inline token_position start_position(depth_t depth) const noexcept; + simdjson_inline void set_start_position(depth_t depth, token_position position) noexcept; +#endif + + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Updates this json iterator so that it is back at the beginning of the document, + * as if it had just been created. + */ + inline void rewind() noexcept; + /** + * This checks whether the {,},[,] are balanced so that the document + * ends with proper zero depth. This requires scanning the whole document + * and it may be expensive. It is expected that it will be rarely called. + * It does not attempt to match { with } and [ with ]. + */ + inline bool balanced() const noexcept; + protected: + simdjson_inline json_iterator(const uint8_t* buf, ondemand::parser* parser) noexcept; + /// The last token before the end + simdjson_inline token_position last_position() const noexcept; + /// The token *at* the end. This points at gibberish and should only be used for comparison. + simdjson_inline token_position end_position() const noexcept; + /// The end of the buffer. + simdjson_inline token_position end() const noexcept; + + friend class document; + friend class document_stream; + friend class object; + friend class array; + friend class value; + friend class raw_json_string; + friend class parser; + friend class value_iterator; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; // json_iterator + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::json_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H +/* end file simdjson/generic/ondemand/json_iterator.h for ppc64 */ +/* including simdjson/generic/ondemand/json_type.h for ppc64: #include "simdjson/generic/ondemand/json_type.h" */ +/* begin file simdjson/generic/ondemand/json_type.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * The type of a JSON value. + */ + enum class json_type { + // Start at 1 to catch uninitialized / default values more easily + array = 1, ///< A JSON array ( [ 1, 2, 3 ... ] ) + object, ///< A JSON object ( { "a": 1, "b" 2, ... } ) + number, ///< A JSON number ( 1 or -2.3 or 4.5e6 ...) + string, ///< A JSON string ( "a" or "hello world\n" ...) + boolean, ///< A JSON boolean (true or false) + null ///< A JSON null (null) + }; + + /** + * A type representing a JSON number. + * The design of the struct is deliberately straight-forward. All + * functions return standard values with no error check. + */ + struct number { + + /** + * return the automatically determined type of + * the number: number_type::floating_point_number, + * number_type::signed_integer or number_type::unsigned_integer. + * + * enum class number_type { + * floating_point_number=1, /// a binary64 number + * signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + * unsigned_integer /// a positive integer larger or equal to 1<<63 + * }; + */ + simdjson_inline ondemand::number_type get_number_type() const noexcept; + /** + * return true if the automatically determined type of + * the number is number_type::unsigned_integer. + */ + simdjson_inline bool is_uint64() const noexcept; + /** + * return the value as a uint64_t, only valid if is_uint64() is true. + */ + simdjson_inline uint64_t get_uint64() const noexcept; + simdjson_inline operator uint64_t() const noexcept; + + /** + * return true if the automatically determined type of + * the number is number_type::signed_integer. + */ + simdjson_inline bool is_int64() const noexcept; + /** + * return the value as a int64_t, only valid if is_int64() is true. + */ + simdjson_inline int64_t get_int64() const noexcept; + simdjson_inline operator int64_t() const noexcept; + + + /** + * return true if the automatically determined type of + * the number is number_type::floating_point_number. + */ + simdjson_inline bool is_double() const noexcept; + /** + * return the value as a double, only valid if is_double() is true. + */ + simdjson_inline double get_double() const noexcept; + simdjson_inline operator double() const noexcept; + + /** + * Convert the number to a double. Though it always succeed, the conversion + * may be lossy if the number cannot be represented exactly. + */ + simdjson_inline double as_double() const noexcept; + + + protected: + /** + * The next block of declaration is designed so that we can call the number parsing + * functions on a number type. They are protected and should never be used outside + * of the core simdjson library. + */ + friend class value_iterator; + template + friend error_code numberparsing::slow_float_parsing(simdjson_unused const uint8_t* src, W writer); + template + friend error_code numberparsing::write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer); + template + friend error_code numberparsing::parse_number(const uint8_t* const src, W& writer); + /** Store a signed 64-bit value to the number. */ + simdjson_inline void append_s64(int64_t value) noexcept; + /** Store an unsigned 64-bit value to the number. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + /** Store a double value to the number. */ + simdjson_inline void append_double(double value) noexcept; + /** Specifies that the value is a double, but leave it undefined. */ + simdjson_inline void skip_double() noexcept; + /** + * End of friend declarations. + */ + + /** + * Our attributes are a union type (size = 64 bits) + * followed by a type indicator. + */ + union { + double floating_point_number; + int64_t signed_integer; + uint64_t unsigned_integer; + } payload{ 0 }; + number_type type{ number_type::signed_integer }; + }; + + /** + * Write the JSON type to the output stream + * + * @param out The output stream. + * @param type The json_type. + */ + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Send JSON type to an output stream. + * + * @param out The output stream. + * @param type The json_type. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false); +#endif + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::json_type&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H +/* end file simdjson/generic/ondemand/json_type.h for ppc64 */ +/* including simdjson/generic/ondemand/raw_json_string.h for ppc64: #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * A string escaped per JSON rules, terminated with quote ("). They are used to represent + * unescaped keys inside JSON documents. + * + * (In other words, a pointer to the beginning of a string, just after the start quote, inside a + * JSON file.) + * + * This class is deliberately simplistic and has little functionality. You can + * compare a raw_json_string instance with an unescaped C string, but + * that is nearly all you can do. + * + * The raw_json_string is unescaped. If you wish to write an unescaped version of it to your own + * buffer, you may do so using the parser.unescape(string, buff) method, using an ondemand::parser + * instance. Doing so requires you to have a sufficiently large buffer. + * + * The raw_json_string instances originate typically from field instance which in turn represent + * key-value pairs from object instances. From a field instance, you get the raw_json_string + * instance by calling key(). You can, if you want a more usable string_view instance, call + * the unescaped_key() method on the field instance. You may also create a raw_json_string from + * any other string value, with the value.get_raw_json_string() method. Again, you can get + * a more usable string_view instance by calling get_string(). + * + */ + class raw_json_string { + public: + /** + * Create a new invalid raw_json_string. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline raw_json_string() noexcept = default; + + /** + * Create a new invalid raw_json_string pointed at the given location in the JSON. + * + * The given location must be just *after* the beginning quote (") in the JSON file. + * + * It *must* be terminated by a ", and be a valid JSON string. + */ + simdjson_inline raw_json_string(const uint8_t* _buf) noexcept; + /** + * Get the raw pointer to the beginning of the string in the JSON (just after the "). + * + * It is possible for this function to return a null pointer if the instance + * has outlived its existence. + */ + simdjson_inline const char* raw() const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done) on target.size() characters, + * and if the raw_json_string instance has a quote character at byte index target.size(). + * We never read more than length + 1 bytes in the raw_json_string instance. + * If length is smaller than target.size(), this will return false. + * + * The std::string_view instance may contain any characters. However, the caller + * is responsible for setting length so that length bytes may be read in the + * raw_json_string. + * + * Performance: the comparison may be done using memcmp which may be efficient + * for long strings. + */ + simdjson_inline bool unsafe_is_equal(size_t length, std::string_view target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The std::string_view instance should not contain unescaped quote characters: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * Performance: the comparison is done byte-by-byte which might be inefficient for + * long strings. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The provided C string should not contain an unescaped quote character: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(const char* target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(const char* target) const noexcept; + + /** + * Returns true if target is free from unescaped quote. If target is known at + * compile-time, we might expect the computation to happen at compile time with + * many compilers (not all!). + */ + static simdjson_inline bool is_free_from_unescaped_quote(std::string_view target) noexcept; + static simdjson_inline bool is_free_from_unescaped_quote(const char* target) noexcept; + + private: + + + /** + * This will set the inner pointer to zero, effectively making + * this instance unusable. + */ + simdjson_inline void consume() noexcept { buf = nullptr; } + + /** + * Checks whether the inner pointer is non-null and thus usable. + */ + simdjson_inline simdjson_warn_unused bool alive() const noexcept { return buf != nullptr; } + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result will be a valid UTF-8. + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + * @param allow_replacement Whether we allow replacement of invalid surrogate pairs. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape(json_iterator& iter, bool allow_replacement) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result may not be a valid UTF-8. https://simonsapin.github.io/wtf-8/ + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(json_iterator& iter) const noexcept; + const uint8_t* buf{}; + friend class object; + friend class field; + friend class parser; + friend struct simdjson_result; + }; + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream&, const raw_json_string&) noexcept; + + /** + * Comparisons between raw_json_string and std::string_view instances are potentially unsafe: the user is responsible + * for providing a string with no unescaped quote. Note that unescaped quotes cannot be present in valid JSON strings. + */ + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept; + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept; + + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::raw_json_string&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + + simdjson_inline simdjson_result raw() const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape(ppc64::ondemand::json_iterator& iter, bool allow_replacement) const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(ppc64::ondemand::json_iterator& iter) const noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H +/* end file simdjson/generic/ondemand/raw_json_string.h for ppc64 */ +/* including simdjson/generic/ondemand/parser.h for ppc64: #include "simdjson/generic/ondemand/parser.h" */ +/* begin file simdjson/generic/ondemand/parser.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * The default batch size for document_stream instances for this On Demand kernel. + * Note that different On Demand kernel may use a different DEFAULT_BATCH_SIZE value + * in the future. + */ + static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; + /** + * Some adversary might try to set the batch size to 0 or 1, which might cause problems. + * We set a minimum of 32B since anything else is highly likely to be an error. In practice, + * most users will want a much larger batch size. + * + * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON + * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. + */ + static constexpr size_t MINIMAL_BATCH_SIZE = 32; + + /** + * A JSON fragment iterator. + * + * This holds the actual iterator as well as the buffer for writing strings. + */ + class parser { + public: + /** + * Create a JSON parser. + * + * The new parser will have zero capacity. + */ + inline explicit parser(size_t max_capacity = SIMDJSON_MAXSIZE_BYTES) noexcept; + + inline parser(parser&& other) noexcept = default; + simdjson_inline parser(const parser& other) = delete; + simdjson_inline parser& operator=(const parser& other) = delete; + simdjson_inline parser& operator=(parser&& other) noexcept = default; + + /** Deallocate the JSON parser. */ + inline ~parser() noexcept = default; + + /** + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * document doc = parser.iterate(json); + * + * It is expected that the content is a valid UTF-8 file, containing a valid JSON document. + * Otherwise the iterate method may return an error. In particular, the whole input should be + * valid: we do not attempt to tolerate incorrect content either before or after a JSON + * document. If there is a UTF-8 BOM, the parser skips it. + * + * ### IMPORTANT: Validate what you use + * + * Calling iterate on an invalid JSON document may not immediately trigger an error. The call to + * iterate does not parse and validate the whole document. + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * @param len The length of the JSON. + * @param capacity The number of bytes allocated in the JSON (must be at least len+SIMDJSON_PADDING). + * + * @return The document, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate(padded_string_view json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const char* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const uint8_t* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string_view json, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(padded_string&& json) & noexcept = delete; + + /** + * @private + * + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * json_iterator doc = parser.iterate(json); + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * The ondemand::document instance holds the iterator. The document must remain in scope + * while you are accessing instances of ondemand::value, ondemand::object, ondemand::array. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * + * @return The iterator, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate_raw(padded_string_view json) & noexcept; + + + /** + * Parse a buffer containing many JSON documents. + * + * auto json = R"({ "foo": 1 } { "foo": 2 } { "foo": 3 } )"_padded; + * ondemand::parser parser; + * ondemand::document_stream docs = parser.iterate_many(json); + * for (auto & doc : docs) { + * std::cout << doc["foo"] << std::endl; + * } + * // Prints 1 2 3 + * + * No copy of the input buffer is made. + * + * The function is lazy: it may be that no more than one JSON document at a time is parsed. + * + * The caller is responsabile to ensure that the input string data remains unchanged and is + * not deleted during the loop. + * + * ### Format + * + * The buffer must contain a series of one or more JSON documents, concatenated into a single + * buffer, separated by ASCII whitespace. It effectively parses until it has a fully valid document, + * then starts parsing the next document at that point. (It does this with more parallelism and + * lookahead than you might think, though.) + * + * documents that consist of an object or array may omit the whitespace between them, concatenating + * with no separator. Documents that consist of a single primitive (i.e. documents that are not + * arrays or objects) MUST be separated with ASCII whitespace. + * + * The characters inside a JSON document, and between JSON documents, must be valid Unicode (UTF-8). + * If there is a UTF-8 BOM, the parser skips it. + * + * The documents must not exceed batch_size bytes (by default 1MB) or they will fail to parse. + * Setting batch_size to excessively large or excessively small values may impact negatively the + * performance. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * ### Threads + * + * When compiled with SIMDJSON_THREADS_ENABLED, this method will use a single thread under the + * hood to do some lookahead. + * + * ### Parser Capacity + * + * If the parser's current capacity is less than batch_size, it will allocate enough capacity + * to handle it (up to max_capacity). + * + * @param buf The concatenated JSON to parse. + * @param len The length of the concatenated JSON. + * @param batch_size The batch size to use. MUST be larger than the largest document. The sweet + * spot is cache-related: small enough to fit in cache, yet big enough to + * parse as many documents as possible in one tight loop. + * Defaults to 10MB, which has been a reasonable sweet spot in our tests. + * @param allow_comma_separated (defaults on false) This allows a mode where the documents are + * separated by commas instead of whitespace. It comes with a performance + * penalty because the entire document is indexed at once (and the document must be + * less than 4 GB), and there is no multithreading. In this mode, the batch_size parameter + * is effectively ignored, as it is set to at least the document size. + * @return The stream, or an error. An empty input will yield 0 documents rather than an EMPTY error. Errors: + * - MEMALLOC if the parser does not have enough capacity and memory allocation fails + * - CAPACITY if the parser does not have enough capacity and batch_size > max_capacity. + * - other json errors if parsing fails. You should not rely on these errors to always the same for the + * same document: they may vary under runtime dispatch (so they may vary depending on your system and hardware). + */ + inline simdjson_result iterate_many(const uint8_t* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const char* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const std::string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const std::string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const padded_string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const padded_string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + + /** @private We do not want to allow implicit conversion from C string to std::string. */ + simdjson_result iterate_many(const char* buf, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept = delete; + + /** The capacity of this parser (the largest document it can process). */ + simdjson_inline size_t capacity() const noexcept; + /** The maximum capacity of this parser (the largest document it is allowed to process). */ + simdjson_inline size_t max_capacity() const noexcept; + simdjson_inline void set_max_capacity(size_t max_capacity) noexcept; + /** + * The maximum depth of this parser (the most deeply nested objects and arrays it can process). + * This parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + */ + simdjson_inline size_t max_depth() const noexcept; + + /** + * Ensure this parser has enough memory to process JSON documents up to `capacity` bytes in length + * and `max_depth` depth. + * + * The max_depth parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. Defaults to DEFAULT_MAX_DEPTH. + * @return The error, if there is one. + */ + simdjson_warn_unused error_code allocate(size_t capacity, size_t max_depth = DEFAULT_MAX_DEPTH) noexcept; + +#ifdef SIMDJSON_THREADS_ENABLED + /** + * The parser instance can use threads when they are available to speed up some + * operations. It is enabled by default. Changing this attribute will change the + * behavior of the parser for future operations. + */ + bool threaded{ true }; +#endif + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result must be valid UTF-8. + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @param allow_replacement Whether we allow a replacement if the input string contains unmatched surrogate pairs. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement = false) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result may not be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept; + + private: + /** @private [for benchmarking access] The implementation to use */ + std::unique_ptr implementation{}; + size_t _capacity{ 0 }; + size_t _max_capacity; + size_t _max_depth{ DEFAULT_MAX_DEPTH }; + std::unique_ptr string_buf{}; +#if SIMDJSON_DEVELOPMENT_CHECKS + std::unique_ptr start_positions{}; +#endif + + friend class json_iterator; + friend class document_stream; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::parser&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_H +/* end file simdjson/generic/ondemand/parser.h for ppc64 */ + +// All other declarations +/* including simdjson/generic/ondemand/array.h for ppc64: #include "simdjson/generic/ondemand/array.h" */ +/* begin file simdjson/generic/ondemand/array.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * A forward-only JSON array. + */ + class array { + public: + /** + * Create a new invalid array. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline array() noexcept = default; + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an array is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the beginning of the array and checks whether the + * array is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result is_empty() & noexcept; + /** + * Reset the iterator so that we are pointing back at the + * beginning of the array. You should still consume values only once even if you + * can iterate through the array more than once. If you unescape a string + * within the array more than once, you have unsafe code. Note that rewinding + * an array means that you may need to reparse it anew: it is not a free + * operation. + * + * @returns true if the array contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"([ { "foo": { "a": [ 10, 20, 30 ] }} ])"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/0/foo/a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an array + * instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the array and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Get the value at the given index. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + protected: + /** + * Go to the end of the array, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + + /** + * Begin array iteration. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + */ + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + /** + * Begin array iteration from the root. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + * @error TAPE_ERROR if there is no closing ] at the end of the document. + */ + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + /** + * Begin array iteration. + * + * This version of the method should be called after the initial [ has been verified, and is + * intended for use by switch statements that check the type of a value. + * + * @param iter The iterator. Must be after the initial [. Will be *moved* into the resulting array. + */ + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + + /** + * Create an array at the given Internal array creation. Call array::start() or array::started() instead of this. + * + * @param iter The iterator. Must either be at the start of the first element with iter.is_alive() + * == true, or past the [] with is_alive() == false if the array is empty. Will be *moved* + * into the resulting array. + */ + simdjson_inline array(const value_iterator& iter) noexcept; + + /** + * Iterator marking current position. + * + * iter.is_alive() == false indicates iteration is complete. + */ + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + friend struct simdjson_result; + friend class array_iterator; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::array&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + inline simdjson_result count_elements() & noexcept; + inline simdjson_result is_empty() & noexcept; + inline simdjson_result reset() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_H +/* end file simdjson/generic/ondemand/array.h for ppc64 */ +/* including simdjson/generic/ondemand/array_iterator.h for ppc64: #include "simdjson/generic/ondemand/array_iterator.h" */ +/* begin file simdjson/generic/ondemand/array_iterator.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * A forward-only JSON array. + * + * This is an input_iterator, meaning: + * - It is forward-only + * - * must be called exactly once per element. + * - ++ must be called exactly once in between each * (*, ++, *, ++, * ...) + */ + class array_iterator { + public: + /** Create a new, invalid array iterator. */ + simdjson_inline array_iterator() noexcept = default; + + // + // Iterator interface + // + + /** + * Get the current element. + * + * Part of the std::iterator interface. + */ + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + /** + * Check if we are at the end of the JSON. + * + * Part of the std::iterator interface. + * + * @return true if there are no more elements in the JSON array. + */ + simdjson_inline bool operator==(const array_iterator&) const noexcept; + /** + * Check if there are more elements in the JSON array. + * + * Part of the std::iterator interface. + * + * @return true if there are more elements in the JSON array. + */ + simdjson_inline bool operator!=(const array_iterator&) const noexcept; + /** + * Move to the next element. + * + * Part of the std::iterator interface. + */ + simdjson_inline array_iterator& operator++() noexcept; + + private: + value_iterator iter{}; + + simdjson_inline array_iterator(const value_iterator& iter) noexcept; + + friend class array; + friend class value; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::array_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H +/* end file simdjson/generic/ondemand/array_iterator.h for ppc64 */ +/* including simdjson/generic/ondemand/document.h for ppc64: #include "simdjson/generic/ondemand/document.h" */ +/* begin file simdjson/generic/ondemand/document.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * A JSON document. It holds a json_iterator instance. + * + * Used by tokens to get text, and string buffer location. + * + * You must keep the document around during iteration. + */ + class document { + public: + /** + * Create a new invalid document. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline document() noexcept = default; + simdjson_inline document(const document& other) noexcept = delete; // pass your documents by reference, not by copy + simdjson_inline document(document&& other) noexcept = default; + simdjson_inline document& operator=(const document& other) noexcept = delete; + simdjson_inline document& operator=(document&& other) noexcept = default; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() & noexcept; + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() & noexcept; + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + /** + * Cast this JSON value (inside string) to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: Calling get_string() twice on the same document is an error. + * + * @param Whether to allow a replacement character for unmatched surrogate pairs. + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + /** + * Cast this JSON value to a string. + * + * The string is not guaranteed to be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * + * Important: Calling get_wobbly_string() twice on the same document is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is set to 1 (which is the case when building in Debug mode + * by default), and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value if a JSON array or object cannot be found. + * @returns SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result get_value() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() & noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + /** @overload template simdjson_result get() & noexcept */ + template simdjson_inline simdjson_result get() && noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool, value + * + * Be mindful that the document instance must remain in scope while you are accessing object, array and value instances. + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) & noexcept; + /** @overload template error_code get(T &out) & noexcept */ + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() & noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() & noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is defined, and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value value if a JSON array or object cannot be found. + * @exception SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline operator value() noexcept(false); +#endif + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) & noexcept; + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to + * a key a single time. Doing object["mykey"].to_string()and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the document is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the document is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the document is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. If this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view may be the padded buffer. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + /** + * Reset the iterator inside the document instance so we are pointing back at the + * beginning of the document, as if it had just been created. It invalidates all + * values, objects and arrays that you have created so far (including unescaped strings). + */ + inline void rewind() noexcept; + /** + * Returns debugging information. + */ + inline std::string to_debug_string() noexcept; + /** + * Some unrecoverable error conditions may render the document instance unusable. + * The is_alive() method returns true when the document is still suitable. + */ + inline bool is_alive() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Returns true if this document has been fully parsed. + * If you have consumed the whole document and at_end() returns + * false, then there may be trailing content. + */ + inline bool at_end() const noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() automatically calls rewind between each call. Thus + * all values, objects and arrays that you have created so far (including unescaped strings) + * are invalidated. After calling at_pointer, you need to consume the result: string values + * should be stored in your own variables, arrays should be decoded and stored in your own array-like + * structures and so forth. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + * - SCALAR_DOCUMENT_AS_VALUE if the json_pointer is empty and the document is not a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the document and returns a string_view instance corresponding to the + * document as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + protected: + /** + * Consumes the document. + */ + simdjson_inline error_code consume() noexcept; + + simdjson_inline document(ondemand::json_iterator&& iter) noexcept; + simdjson_inline const uint8_t* text(uint32_t idx) const noexcept; + + simdjson_inline value_iterator resume_value_iterator() noexcept; + simdjson_inline value_iterator get_root_value_iterator() noexcept; + simdjson_inline simdjson_result start_or_resume_object() noexcept; + static simdjson_inline document start(ondemand::json_iterator&& iter) noexcept; + + // + // Fields + // + json_iterator iter{}; ///< Current position in the document + static constexpr depth_t DOCUMENT_DEPTH = 0; ///< document depth is always 0 + + friend class array_iterator; + friend class value; + friend class ondemand::parser; + friend class object; + friend class array; + friend class field; + friend class token; + friend class document_stream; + friend class document_reference; + }; + + + /** + * A document_reference is a thin wrapper around a document reference instance. + */ + class document_reference { + public: + simdjson_inline document_reference() noexcept; + simdjson_inline document_reference(document& d) noexcept; + simdjson_inline document_reference(const document_reference& other) noexcept = default; + simdjson_inline document_reference& operator=(const document_reference& other) noexcept = default; + simdjson_inline void rewind() noexcept; + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + + simdjson_inline simdjson_result is_null() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + simdjson_inline operator document& () const noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator array() & noexcept(false); + simdjson_inline operator object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + private: + document* doc{ nullptr }; + }; + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::document&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() & noexcept; + template simdjson_inline simdjson_result get() && noexcept; + + template simdjson_inline error_code get(T& out) & noexcept; + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator ppc64::ondemand::array() & noexcept(false); + simdjson_inline operator ppc64::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator ppc64::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator ppc64::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool at_end() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + + + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::document_reference value, error_code error) noexcept; + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator ppc64::ondemand::array() & noexcept(false); + simdjson_inline operator ppc64::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator ppc64::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator ppc64::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document_reference::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H +/* end file simdjson/generic/ondemand/document.h for ppc64 */ +/* including simdjson/generic/ondemand/document_stream.h for ppc64: #include "simdjson/generic/ondemand/document_stream.h" */ +/* begin file simdjson/generic/ondemand/document_stream.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#ifdef SIMDJSON_THREADS_ENABLED +#include +#include +#include +#endif + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + /** @private Custom worker class **/ + struct stage1_worker { + stage1_worker() noexcept = default; + stage1_worker(const stage1_worker&) = delete; + stage1_worker(stage1_worker&&) = delete; + stage1_worker operator=(const stage1_worker&) = delete; + ~stage1_worker(); + /** + * We only start the thread when it is needed, not at object construction, this may throw. + * You should only call this once. + **/ + void start_thread(); + /** + * Start a stage 1 job. You should first call 'run', then 'finish'. + * You must call start_thread once before. + */ + void run(document_stream* ds, parser* stage1, size_t next_batch_start); + /** Wait for the run to finish (blocking). You should first call 'run', then 'finish'. **/ + void finish(); + + private: + + /** + * Normally, we would never stop the thread. But we do in the destructor. + * This function is only safe assuming that you are not waiting for results. You + * should have called run, then finish, and be done. + **/ + void stop_thread(); + + std::thread thread{}; + /** These three variables define the work done by the thread. **/ + ondemand::parser* stage1_thread_parser{}; + size_t _next_batch_start{}; + document_stream* owner{}; + /** + * We have two state variables. This could be streamlined to one variable in the future but + * we use two for clarity. + */ + bool has_work{ false }; + bool can_work{ true }; + + /** + * We lock using a mutex. + */ + std::mutex locking_mutex{}; + std::condition_variable cond_var{}; + + friend class document_stream; + }; +#endif // SIMDJSON_THREADS_ENABLED + + /** + * A forward-only stream of documents. + * + * Produced by parser::iterate_many. + * + */ + class document_stream { + public: + /** + * Construct an uninitialized document_stream. + * + * ```c++ + * document_stream docs; + * auto error = parser.iterate_many(json).get(docs); + * ``` + */ + simdjson_inline document_stream() noexcept; + /** Move one document_stream to another. */ + simdjson_inline document_stream(document_stream&& other) noexcept = default; + /** Move one document_stream to another. */ + simdjson_inline document_stream& operator=(document_stream&& other) noexcept = default; + + simdjson_inline ~document_stream() noexcept; + + /** + * Returns the input size in bytes. + */ + inline size_t size_in_bytes() const noexcept; + + /** + * After iterating through the stream, this method + * returns the number of bytes that were not parsed at the end + * of the stream. If truncated_bytes() differs from zero, + * then the input was truncated maybe because incomplete JSON + * documents were found at the end of the stream. You + * may need to process the bytes in the interval [size_in_bytes()-truncated_bytes(), size_in_bytes()). + * + * You should only call truncated_bytes() after streaming through all + * documents, like so: + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto & doc : stream) { + * // do something with doc + * } + * size_t truncated = stream.truncated_bytes(); + * + */ + inline size_t truncated_bytes() const noexcept; + + class iterator { + public: + using value_type = simdjson_result; + using reference = value_type; + + using difference_type = std::ptrdiff_t; + + using iterator_category = std::input_iterator_tag; + + /** + * Default constructor. + */ + simdjson_inline iterator() noexcept; + /** + * Get the current document (or error). + */ + simdjson_inline simdjson_result operator*() noexcept; + /** + * Advance to the next document (prefix). + */ + inline iterator& operator++() noexcept; + /** + * Check if we're at the end yet. + * @param other the end iterator to compare to. + */ + simdjson_inline bool operator!=(const iterator& other) const noexcept; + /** + * @private + * + * Gives the current index in the input document in bytes. + * + * document_stream stream = parser.parse_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * auto doc = *i; + * size_t index = i.current_index(); + * } + * + * This function (current_index()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + */ + simdjson_inline size_t current_index() const noexcept; + + /** + * @private + * + * Gives a view of the current document at the current position. + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * std::string_view v = i.source(); + * } + * + * The returned string_view instance is simply a map to the (unparsed) + * source string: it may thus include white-space characters and all manner + * of padding. + * + * This function (source()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + * + */ + simdjson_inline std::string_view source() const noexcept; + + /** + * Returns error of the stream (if any). + */ + inline error_code error() const noexcept; + + private: + simdjson_inline iterator(document_stream* s, bool finished) noexcept; + /** The document_stream we're iterating through. */ + document_stream* stream; + /** Whether we're finished or not. */ + bool finished; + + friend class document; + friend class document_stream; + friend class json_iterator; + }; + + /** + * Start iterating the documents in the stream. + */ + simdjson_inline iterator begin() noexcept; + /** + * The end of the stream, for iterator comparison purposes. + */ + simdjson_inline iterator end() noexcept; + + private: + + document_stream& operator=(const document_stream&) = delete; // Disallow copying + document_stream(const document_stream& other) = delete; // Disallow copying + + /** + * Construct a document_stream. Does not allocate or parse anything until the iterator is + * used. + * + * @param parser is a reference to the parser instance used to generate this document_stream + * @param buf is the raw byte buffer we need to process + * @param len is the length of the raw byte buffer in bytes + * @param batch_size is the size of the windows (must be strictly greater or equal to the largest JSON document) + */ + simdjson_inline document_stream( + ondemand::parser& parser, + const uint8_t* buf, + size_t len, + size_t batch_size, + bool allow_comma_separated + ) noexcept; + + /** + * Parse the first document in the buffer. Used by begin(), to handle allocation and + * initialization. + */ + inline void start() noexcept; + + /** + * Parse the next document found in the buffer previously given to document_stream. + * + * The content should be a valid JSON document encoded as UTF-8. If there is a + * UTF-8 BOM, the parser skips it. + * + * You do NOT need to pre-allocate a parser. This function takes care of + * pre-allocating a capacity defined by the batch_size defined when creating the + * document_stream object. + * + * The function returns simdjson::EMPTY if there is no more data to be parsed. + * + * The function returns simdjson::SUCCESS (as integer = 0) in case of success + * and indicates that the buffer has successfully been parsed to the end. + * Every document it contained has been parsed without error. + * + * The function returns an error code from simdjson/simdjson.h in case of failure + * such as simdjson::CAPACITY, simdjson::MEMALLOC, simdjson::DEPTH_ERROR and so forth; + * the simdjson::error_message function converts these error codes into a string). + * + * You can also check validity by calling parser.is_valid(). The same parser can + * and should be reused for the other documents in the buffer. + */ + inline void next() noexcept; + + /** Move the json_iterator of the document to the location of the next document in the stream. */ + inline void next_document() noexcept; + + /** Get the next document index. */ + inline size_t next_batch_start() const noexcept; + + /** Pass the next batch through stage 1 with the given parser. */ + inline error_code run_stage1(ondemand::parser& p, size_t batch_start) noexcept; + + // Fields + ondemand::parser* parser; + const uint8_t* buf; + size_t len; + size_t batch_size; + bool allow_comma_separated; + /** + * We are going to use just one document instance. The document owns + * the json_iterator. It implies that we only ever pass a reference + * to the document to the users. + */ + document doc{}; + /** The error (or lack thereof) from the current document. */ + error_code error; + size_t batch_start{ 0 }; + size_t doc_index{}; + +#ifdef SIMDJSON_THREADS_ENABLED + /** Indicates whether we use threads. Note that this needs to be a constant during the execution of the parsing. */ + bool use_thread; + + inline void load_from_stage1_thread() noexcept; + + /** Start a thread to run stage 1 on the next batch. */ + inline void start_stage1_thread() noexcept; + + /** Wait for the stage 1 thread to finish and capture the results. */ + inline void finish_stage1_thread() noexcept; + + /** The error returned from the stage 1 thread. */ + error_code stage1_thread_error{ UNINITIALIZED }; + /** The thread used to run stage 1 against the next batch in the background. */ + std::unique_ptr worker{ new(std::nothrow) stage1_worker() }; + /** + * The parser used to run stage 1 in the background. Will be swapped + * with the regular parser when finished. + */ + ondemand::parser stage1_thread_parser{}; + + friend struct stage1_worker; +#endif // SIMDJSON_THREADS_ENABLED + + friend class parser; + friend class document; + friend class json_iterator; + friend struct simdjson_result; + friend struct internal::simdjson_result_base; + }; // document_stream + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::document_stream&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H +/* end file simdjson/generic/ondemand/document_stream.h for ppc64 */ +/* including simdjson/generic/ondemand/field.h for ppc64: #include "simdjson/generic/ondemand/field.h" */ +/* begin file simdjson/generic/ondemand/field.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * A JSON field (key/value pair) in an object. + * + * Returned from object iteration. + * + * Extends from std::pair so you can use C++ algorithms that rely on pairs. + */ + class field : public std::pair { + public: + /** + * Create a new invalid field. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline field() noexcept; + + /** + * Get the key as a string_view (for higher speed, consider raw_key). + * We deliberately use a more cumbersome name (unescaped_key) to force users + * to think twice about using it. + * + * This consumes the key: once you have called unescaped_key(), you cannot + * call it again nor can you call key(). + */ + simdjson_inline simdjson_warn_unused simdjson_result unescaped_key(bool allow_replacement) noexcept; + /** + * Get the key as a raw_json_string. Can be used for direct comparison with + * an unescaped C string: e.g., key() == "test". + */ + simdjson_inline raw_json_string key() const noexcept; + /** + * Get the field value. + */ + simdjson_inline ondemand::value& value() & noexcept; + /** + * @overload ondemand::value &ondemand::value() & noexcept + */ + simdjson_inline ondemand::value value() && noexcept; + + protected: + simdjson_inline field(raw_json_string key, ondemand::value&& value) noexcept; + static simdjson_inline simdjson_result start(value_iterator& parent_iter) noexcept; + static simdjson_inline simdjson_result start(const value_iterator& parent_iter, raw_json_string key) noexcept; + friend struct simdjson_result; + friend class object_iterator; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::field&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result unescaped_key(bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result key() noexcept; + simdjson_inline simdjson_result value() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_H +/* end file simdjson/generic/ondemand/field.h for ppc64 */ +/* including simdjson/generic/ondemand/object.h for ppc64: #include "simdjson/generic/ondemand/object.h" */ +/* begin file simdjson/generic/ondemand/object.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * A forward-only JSON object field iterator. + */ + class object { + public: + /** + * Create a new invalid object. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a + * key a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an object + * instance: there is no rewind and no invalidation. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + /** + * Reset the iterator so that we are pointing back at the + * beginning of the object. You should still consume values only once even if you + * can iterate through the object more than once. If you unescape a string within + * the object more than once, you have unsafe code. Note that rewinding an object + * means that you may need to reparse it anew: it is not a free operation. + * + * @returns true if the object contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * This method scans the beginning of the object and checks whether the + * object is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + inline simdjson_result is_empty() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Consumes the object and returns a string_view instance corresponding to the + * object as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + protected: + /** + * Go to the end of the object, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + static simdjson_inline object resume(const value_iterator& iter) noexcept; + simdjson_inline object(const value_iterator& iter) noexcept; + + simdjson_warn_unused simdjson_inline error_code find_field_raw(const std::string_view key) noexcept; + + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::object&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + inline simdjson_result reset() noexcept; + inline simdjson_result is_empty() noexcept; + inline simdjson_result count_fields() & noexcept; + inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_H +/* end file simdjson/generic/ondemand/object.h for ppc64 */ +/* including simdjson/generic/ondemand/object_iterator.h for ppc64: #include "simdjson/generic/ondemand/object_iterator.h" */ +/* begin file simdjson/generic/ondemand/object_iterator.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + class object_iterator { + public: + /** + * Create a new invalid object_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object_iterator() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline simdjson_result operator*() noexcept; + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const object_iterator&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const object_iterator&) const noexcept; + // Checks for ']' and ',' + simdjson_inline object_iterator& operator++() noexcept; + + private: + /** + * The underlying JSON iterator. + * + * PERF NOTE: expected to be elided in favor of the parent document: this is set when the object + * is first used, and never changes afterwards. + */ + value_iterator iter{}; + + simdjson_inline object_iterator(const value_iterator& iter) noexcept; + friend struct simdjson_result; + friend class object; + }; + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public ppc64::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(ppc64::ondemand::object_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + // Checks for ']' and ',' + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H +/* end file simdjson/generic/ondemand/object_iterator.h for ppc64 */ +/* including simdjson/generic/ondemand/serialization.h for ppc64: #include "simdjson/generic/ondemand/serialization.h" */ +/* begin file simdjson/generic/ondemand/serialization.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Create a string-view instance out of a document instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(ppc64::ondemand::document& x) noexcept; + /** + * Create a string-view instance out of a value instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. The value must + * not have been accessed previously. It does not + * validate the content. + */ + inline simdjson_result to_json_string(ppc64::ondemand::value& x) noexcept; + /** + * Create a string-view instance out of an object instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(ppc64::ondemand::object& x) noexcept; + /** + * Create a string-view instance out of an array instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(ppc64::ondemand::array& x) noexcept; + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); +} // namespace simdjson + +/** + * We want to support argument-dependent lookup (ADL). + * Hence we should define operator<< in the namespace + * where the argument (here value, object, etc.) resides. + * Credit: @madhur4127 + * See https://github.com/simdjson/simdjson/issues/1768 + */ +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The element. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::value x); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::array value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::document& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::document_reference& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The object. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::object value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + } + } +} // namespace simdjson::ppc64::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H +/* end file simdjson/generic/ondemand/serialization.h for ppc64 */ + +// Inline definitions +/* including simdjson/generic/ondemand/array-inl.h for ppc64: #include "simdjson/generic/ondemand/array-inl.h" */ +/* begin file simdjson/generic/ondemand/array-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter->depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the array is first found and the iterator is just past the `{`. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the `,` before the next value (or `]`). In this state, + // depth == iter->depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter->depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter->depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the array iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet element may be missing or not be an + // array--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter->depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between elements, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter->depth == depth, and at_start == false. + // + // ## Terminal State + // + // The terminal state has iter->depth < depth. at_start is always false. + // + // - Finished: When we have reached a `]` or have reported an error, we are finished. We signal this + // by decrementing depth. In this state, iter->depth < depth, at_start == false, and + // error == SUCCESS. + // + + simdjson_inline array::array(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result array::start(value_iterator& iter) noexcept { + // We don't need to know if the array is empty to start iteration, but we do want to know if there + // is an error--thus `simdjson_unused`. + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::start_root(value_iterator& iter) noexcept { + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_root_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::started(value_iterator& iter) noexcept { + bool has_value; + SIMDJSON_TRY(iter.started_array().get(has_value)); + return array(iter); + } + + simdjson_inline simdjson_result array::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return array_iterator(iter); + } + simdjson_inline simdjson_result array::end() noexcept { + return array_iterator(iter); + } + simdjson_inline error_code array::consume() noexcept { + auto error = iter.json_iter().skip_child(iter.depth() - 1); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result array::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter._json_iter->unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline simdjson_result array::count_elements() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the array after counting the number of elements. + iter.reset_array(); + return count; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline simdjson_result array::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_array().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + inline simdjson_result array::reset() & noexcept { + return iter.reset_array(); + } + + inline simdjson_result array::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + // - means "the append position" or "the element after the end of the array" + // We don't support this, because we're returning a real element, not a position. + if (json_pointer == "-") { return INDEX_OUT_OF_BOUNDS; } + + // Read the array index + size_t array_index = 0; + size_t i; + for (i = 0; i < json_pointer.length() && json_pointer[i] != '/'; i++) { + uint8_t digit = uint8_t(json_pointer[i] - '0'); + // Check for non-digit in array index. If it's there, we're trying to get a field in an object + if (digit > 9) { return INCORRECT_TYPE; } + array_index = array_index * 10 + digit; + } + + // 0 followed by other digits is invalid + if (i > 1 && json_pointer[0] == '0') { return INVALID_JSON_POINTER; } // "JSON pointer array index has other characters after 0" + + // Empty string is invalid; so is a "/" with no digits before it + if (i == 0) { return INVALID_JSON_POINTER; } // "Empty string in JSON pointer array index" + // Get the child + auto child = at(array_index); + // If there is an error, it ends here + if (child.error()) { + return child; + } + + // If there is a /, we're not done yet, call recursively. + if (i < json_pointer.length()) { + child = child.at_pointer(json_pointer.substr(i)); + } + return child; + } + + simdjson_inline simdjson_result array::at(size_t index) noexcept { + size_t i = 0; + for (auto value : *this) { + if (i == index) { return value; } + i++; + } + return INDEX_OUT_OF_BOUNDS; + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + ppc64::ondemand::array&& value + ) noexcept + : implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept + : implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::is_empty() & noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H +/* end file simdjson/generic/ondemand/array-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/array_iterator-inl.h for ppc64: #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/array_iterator-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline array_iterator::array_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result array_iterator::operator*() noexcept { + if (iter.error()) { iter.abandon(); return iter.error(); } + return value(iter.child()); + } + simdjson_inline bool array_iterator::operator==(const array_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool array_iterator::operator!=(const array_iterator&) const noexcept { + return iter.is_open(); + } + simdjson_inline array_iterator& array_iterator::operator++() noexcept { + error_code error; + // PERF NOTE this is a safety rail ... users should exit loops as soon as they receive an error, so we'll never get here. + // However, it does not seem to make a perf difference, so we add it out of an abundance of caution. + if ((error = iter.error())) { return *this; } + if ((error = iter.skip_child())) { return *this; } + if ((error = iter.has_next_element().error())) { return *this; } + return *this; + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + ppc64::ondemand::array_iterator&& value + ) noexcept + : ppc64::implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : ppc64::implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++(first); + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/array_iterator-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/document-inl.h for ppc64: #include "simdjson/generic/ondemand/document-inl.h" */ +/* begin file simdjson/generic/ondemand/document-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline document::document(ondemand::json_iterator&& _iter) noexcept + : iter{ std::forward(_iter) } + { + logger::log_start_value(iter, "document"); + } + + simdjson_inline document document::start(json_iterator&& iter) noexcept { + return document(std::forward(iter)); + } + + inline void document::rewind() noexcept { + iter.rewind(); + } + + inline std::string document::to_debug_string() noexcept { + return iter.to_string(); + } + + inline simdjson_result document::current_location() const noexcept { + return iter.current_location(); + } + + inline int32_t document::current_depth() const noexcept { + return iter.depth(); + } + + inline bool document::at_end() const noexcept { + return iter.at_end(); + } + + + inline bool document::is_alive() noexcept { + return iter.is_alive(); + } + simdjson_inline value_iterator document::resume_value_iterator() noexcept { + return value_iterator(&iter, 1, iter.root_position()); + } + simdjson_inline value_iterator document::get_root_value_iterator() noexcept { + return resume_value_iterator(); + } + simdjson_inline simdjson_result document::start_or_resume_object() noexcept { + if (iter.at_root()) { + return get_object(); + } + else { + return object::resume(resume_value_iterator()); + } + } + simdjson_inline simdjson_result document::get_value() noexcept { + // Make sure we start any arrays or objects before returning, so that start_root_() + // gets called. + + // It is the convention throughout the code that the macro `SIMDJSON_DEVELOPMENT_CHECKS` determines whether + // we check for OUT_OF_ORDER_ITERATION. Proper on::demand code should never trigger this error. +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.at_root()) { return OUT_OF_ORDER_ITERATION; } +#endif + // assert_at_root() serves two purposes: in Debug mode, whether or not + // SIMDJSON_DEVELOPMENT_CHECKS is set or not, it checks that we are at the root of + // the document (this will typically be redundant). In release mode, it generates + // SIMDJSON_ASSUME statements to allow the compiler to make assumptions. + iter.assert_at_root(); + switch (*iter.peek()) { + case '[': { + // The following lines check that the document ends with ]. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_array(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + case '{': { + // The following lines would check that the document ends with }. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_object(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + default: + // Unfortunately, scalar documents are a special case in simdjson and they cannot + // be safely converted to value instances. + return SCALAR_DOCUMENT_AS_VALUE; + } + } + simdjson_inline simdjson_result document::get_array() & noexcept { + auto value = get_root_value_iterator(); + return array::start_root(value); + } + simdjson_inline simdjson_result document::get_object() & noexcept { + auto value = get_root_value_iterator(); + return object::start_root(value); + } + + /** + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. We want to disallow trailing + * content. + * Thus, in several implementations below, we pass a 'true' parameter value to + * a get_root_value_iterator() method: this indicates that we disallow trailing content. + */ + + simdjson_inline simdjson_result document::get_uint64() noexcept { + return get_root_value_iterator().get_root_uint64(true); + } + simdjson_inline simdjson_result document::get_uint64_in_string() noexcept { + return get_root_value_iterator().get_root_uint64_in_string(true); + } + simdjson_inline simdjson_result document::get_int64() noexcept { + return get_root_value_iterator().get_root_int64(true); + } + simdjson_inline simdjson_result document::get_int64_in_string() noexcept { + return get_root_value_iterator().get_root_int64_in_string(true); + } + simdjson_inline simdjson_result document::get_double() noexcept { + return get_root_value_iterator().get_root_double(true); + } + simdjson_inline simdjson_result document::get_double_in_string() noexcept { + return get_root_value_iterator().get_root_double_in_string(true); + } + simdjson_inline simdjson_result document::get_string(bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(true, allow_replacement); + } + template + simdjson_inline error_code document::get_string(string_type& receiver, bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(receiver, true, allow_replacement); + } + simdjson_inline simdjson_result document::get_wobbly_string() noexcept { + return get_root_value_iterator().get_root_wobbly_string(true); + } + simdjson_inline simdjson_result document::get_raw_json_string() noexcept { + return get_root_value_iterator().get_root_raw_json_string(true); + } + simdjson_inline simdjson_result document::get_bool() noexcept { + return get_root_value_iterator().get_root_bool(true); + } + simdjson_inline simdjson_result document::is_null() noexcept { + return get_root_value_iterator().is_root_null(true); + } + + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_array(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_object(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_double(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_bool(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_value(); } + + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_double(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_uint64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_int64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_bool(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_value(); } + + template simdjson_inline error_code document::get(T& out) & noexcept { + return get().get(out); + } + template simdjson_inline error_code document::get(T& out) && noexcept { + return std::forward(*this).get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document::operator array() & noexcept(false) { return get_array(); } + simdjson_inline document::operator object() & noexcept(false) { return get_object(); } + simdjson_inline document::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document::operator double() noexcept(false) { return get_double(); } + simdjson_inline document::operator std::string_view() noexcept(false) { return get_string(false); } + simdjson_inline document::operator raw_json_string() noexcept(false) { return get_raw_json_string(); } + simdjson_inline document::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document::operator value() noexcept(false) { return get_value(); } + +#endif + simdjson_inline simdjson_result document::count_elements() & noexcept { + auto a = get_array(); + simdjson_result answer = a.count_elements(); + /* If there was an array, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::count_fields() & noexcept { + auto a = get_object(); + simdjson_result answer = a.count_fields(); + /* If there was an object, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::at(size_t index) & noexcept { + auto a = get_array(); + return a.at(index); + } + simdjson_inline simdjson_result document::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result document::end() & noexcept { + return {}; + } + + simdjson_inline simdjson_result document::find_field(std::string_view key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field(const char* key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field_unordered(std::string_view key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::find_field_unordered(const char* key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::operator[](std::string_view key) & noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result document::operator[](const char* key) & noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline error_code document::consume() noexcept { + auto error = iter.skip_child(0); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result document::raw_json() noexcept { + auto _iter = get_root_value_iterator(); + const uint8_t* starting_point{ _iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter.unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result document::type() noexcept { + return get_root_value_iterator().type(); + } + + simdjson_inline simdjson_result document::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool document::is_negative() noexcept { + return get_root_value_iterator().is_root_negative(); + } + + simdjson_inline simdjson_result document::is_integer() noexcept { + return get_root_value_iterator().is_root_integer(true); + } + + simdjson_inline simdjson_result document::get_number_type() noexcept { + return get_root_value_iterator().get_root_number_type(true); + } + + simdjson_inline simdjson_result document::get_number() noexcept { + return get_root_value_iterator().get_root_number(true); + } + + + simdjson_inline simdjson_result document::raw_json_token() noexcept { + auto _iter = get_root_value_iterator(); + return std::string_view(reinterpret_cast(_iter.peek_start()), _iter.peek_start_length()); + } + + simdjson_inline simdjson_result document::at_pointer(std::string_view json_pointer) noexcept { + rewind(); // Rewind the document each time at_pointer is called + if (json_pointer.empty()) { + return this->get_value(); + } + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + ppc64::ondemand::document&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base( + error + ) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template + simdjson_inline simdjson_result simdjson_result::get() & noexcept { + if (error()) { return error(); } + return first.get(); + } + template + simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first).get(); + } + template + simdjson_inline error_code simdjson_result::get(T& out) & noexcept { + if (error()) { return error(); } + return first.get(out); + } + template + simdjson_inline error_code simdjson_result::get(T& out) && noexcept { + if (error()) { return error(); } + return std::forward(first).get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() & noexcept = delete; + template<> simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first); + } + template<> simdjson_inline error_code simdjson_result::get(ppc64::ondemand::document& out) & noexcept = delete; + template<> simdjson_inline error_code simdjson_result::get(ppc64::ondemand::document& out) && noexcept { + if (error()) { return error(); } + out = std::forward(first); + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + + + simdjson_inline bool simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } + + +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator ppc64::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline bool simdjson_result::at_end() const noexcept { + if (error()) { return error(); } + return first.at_end(); + } + + + simdjson_inline int32_t simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline document_reference::document_reference() noexcept : doc{ nullptr } {} + simdjson_inline document_reference::document_reference(document& d) noexcept : doc(&d) {} + simdjson_inline void document_reference::rewind() noexcept { doc->rewind(); } + simdjson_inline simdjson_result document_reference::get_array() & noexcept { return doc->get_array(); } + simdjson_inline simdjson_result document_reference::get_object() & noexcept { return doc->get_object(); } + /** + * The document_reference instances are used primarily/solely for streams of JSON + * documents. + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. + * + * However, for streams of JSON documents, we want to be able to start from + * "321" "321" "321" + * and parse it successfully as a stream of JSON documents, calling get_uint64_in_string() + * successfully each time. + * + * To achieve this result, we pass a 'false' to a get_root_value_iterator() method: + * this indicates that we allow trailing content. + */ + simdjson_inline simdjson_result document_reference::get_uint64() noexcept { return doc->get_root_value_iterator().get_root_uint64(false); } + simdjson_inline simdjson_result document_reference::get_uint64_in_string() noexcept { return doc->get_root_value_iterator().get_root_uint64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_int64() noexcept { return doc->get_root_value_iterator().get_root_int64(false); } + simdjson_inline simdjson_result document_reference::get_int64_in_string() noexcept { return doc->get_root_value_iterator().get_root_int64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_double() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_double_in_string() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_string(bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(false, allow_replacement); } + template + simdjson_inline error_code document_reference::get_string(string_type& receiver, bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(receiver, false, allow_replacement); } + simdjson_inline simdjson_result document_reference::get_wobbly_string() noexcept { return doc->get_root_value_iterator().get_root_wobbly_string(false); } + simdjson_inline simdjson_result document_reference::get_raw_json_string() noexcept { return doc->get_root_value_iterator().get_root_raw_json_string(false); } + simdjson_inline simdjson_result document_reference::get_bool() noexcept { return doc->get_root_value_iterator().get_root_bool(false); } + simdjson_inline simdjson_result document_reference::get_value() noexcept { return doc->get_value(); } + simdjson_inline simdjson_result document_reference::is_null() noexcept { return doc->get_root_value_iterator().is_root_null(false); } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document_reference::operator array() & noexcept(false) { return array(*doc); } + simdjson_inline document_reference::operator object() & noexcept(false) { return object(*doc); } + simdjson_inline document_reference::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document_reference::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document_reference::operator double() noexcept(false) { return get_double(); } + simdjson_inline document_reference::operator std::string_view() noexcept(false) { return std::string_view(*doc); } + simdjson_inline document_reference::operator raw_json_string() noexcept(false) { return raw_json_string(*doc); } + simdjson_inline document_reference::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document_reference::operator value() noexcept(false) { return value(*doc); } +#endif + simdjson_inline simdjson_result document_reference::count_elements() & noexcept { return doc->count_elements(); } + simdjson_inline simdjson_result document_reference::count_fields() & noexcept { return doc->count_fields(); } + simdjson_inline simdjson_result document_reference::at(size_t index) & noexcept { return doc->at(index); } + simdjson_inline simdjson_result document_reference::begin() & noexcept { return doc->begin(); } + simdjson_inline simdjson_result document_reference::end() & noexcept { return doc->end(); } + simdjson_inline simdjson_result document_reference::find_field(std::string_view key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::find_field(const char* key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::operator[](std::string_view key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::operator[](const char* key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::find_field_unordered(std::string_view key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::find_field_unordered(const char* key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::type() noexcept { return doc->type(); } + simdjson_inline simdjson_result document_reference::is_scalar() noexcept { return doc->is_scalar(); } + simdjson_inline simdjson_result document_reference::current_location() noexcept { return doc->current_location(); } + simdjson_inline int32_t document_reference::current_depth() const noexcept { return doc->current_depth(); } + simdjson_inline bool document_reference::is_negative() noexcept { return doc->is_negative(); } + simdjson_inline simdjson_result document_reference::is_integer() noexcept { return doc->get_root_value_iterator().is_root_integer(false); } + simdjson_inline simdjson_result document_reference::get_number_type() noexcept { return doc->get_root_value_iterator().get_root_number_type(false); } + simdjson_inline simdjson_result document_reference::get_number() noexcept { return doc->get_root_value_iterator().get_root_number(false); } + simdjson_inline simdjson_result document_reference::raw_json_token() noexcept { return doc->raw_json_token(); } + simdjson_inline simdjson_result document_reference::at_pointer(std::string_view json_pointer) noexcept { return doc->at_pointer(json_pointer); } + simdjson_inline simdjson_result document_reference::raw_json() noexcept { return doc->raw_json(); } + simdjson_inline document_reference::operator document& () const noexcept { return *doc; } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + + + +namespace simdjson { + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::document_reference value, error_code error) + noexcept : implementation_simdjson_result_base(std::forward(value), error) {} + + + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator ppc64::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H +/* end file simdjson/generic/ondemand/document-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/document_stream-inl.h for ppc64: #include "simdjson/generic/ondemand/document_stream-inl.h" */ +/* begin file simdjson/generic/ondemand/document_stream-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void stage1_worker::finish() { + // After calling "run" someone would call finish() to wait + // for the end of the processing. + // This function will wait until either the thread has done + // the processing or, else, the destructor has been called. + std::unique_lock lock(locking_mutex); + cond_var.wait(lock, [this] {return has_work == false; }); + } + + inline stage1_worker::~stage1_worker() { + // The thread may never outlive the stage1_worker instance + // and will always be stopped/joined before the stage1_worker + // instance is gone. + stop_thread(); + } + + inline void stage1_worker::start_thread() { + std::unique_lock lock(locking_mutex); + if (thread.joinable()) { + return; // This should never happen but we never want to create more than one thread. + } + thread = std::thread([this] { + while (true) { + std::unique_lock thread_lock(locking_mutex); + // We wait for either "run" or "stop_thread" to be called. + cond_var.wait(thread_lock, [this] {return has_work || !can_work; }); + // If, for some reason, the stop_thread() method was called (i.e., the + // destructor of stage1_worker is called, then we want to immediately destroy + // the thread (and not do any more processing). + if (!can_work) { + break; + } + this->owner->stage1_thread_error = this->owner->run_stage1(*this->stage1_thread_parser, + this->_next_batch_start); + this->has_work = false; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify "finish" + thread_lock.unlock(); + } + } + ); + } + + + inline void stage1_worker::stop_thread() { + std::unique_lock lock(locking_mutex); + // We have to make sure that all locks can be released. + can_work = false; + has_work = false; + cond_var.notify_all(); + lock.unlock(); + if (thread.joinable()) { + thread.join(); + } + } + + inline void stage1_worker::run(document_stream* ds, parser* stage1, size_t next_batch_start) { + std::unique_lock lock(locking_mutex); + owner = ds; + _next_batch_start = next_batch_start; + stage1_thread_parser = stage1; + has_work = true; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify the thread lock that we have work + lock.unlock(); + } + +#endif // SIMDJSON_THREADS_ENABLED + + simdjson_inline document_stream::document_stream( + ondemand::parser& _parser, + const uint8_t* _buf, + size_t _len, + size_t _batch_size, + bool _allow_comma_separated + ) noexcept + : parser{ &_parser }, + buf{ _buf }, + len{ _len }, + batch_size{ _batch_size <= MINIMAL_BATCH_SIZE ? MINIMAL_BATCH_SIZE : _batch_size }, + allow_comma_separated{ _allow_comma_separated }, + error{ SUCCESS } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(_parser.threaded) // we need to make a copy because _parser.threaded can change +#endif + { +#ifdef SIMDJSON_THREADS_ENABLED + if (worker.get() == nullptr) { + error = MEMALLOC; + } +#endif + } + + simdjson_inline document_stream::document_stream() noexcept + : parser{ nullptr }, + buf{ nullptr }, + len{ 0 }, + batch_size{ 0 }, + allow_comma_separated{ false }, + error{ UNINITIALIZED } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(false) +#endif + { + } + + simdjson_inline document_stream::~document_stream() noexcept + { +#ifdef SIMDJSON_THREADS_ENABLED + worker.reset(); +#endif + } + + inline size_t document_stream::size_in_bytes() const noexcept { + return len; + } + + inline size_t document_stream::truncated_bytes() const noexcept { + if (error == CAPACITY) { return len - batch_start; } + return parser->implementation->structural_indexes[parser->implementation->n_structural_indexes] - parser->implementation->structural_indexes[parser->implementation->n_structural_indexes + 1]; + } + + simdjson_inline document_stream::iterator::iterator() noexcept + : stream{ nullptr }, finished{ true } { + } + + simdjson_inline document_stream::iterator::iterator(document_stream* _stream, bool is_end) noexcept + : stream{ _stream }, finished{ is_end } { + } + + simdjson_inline simdjson_result document_stream::iterator::operator*() noexcept { + //if(stream->error) { return stream->error; } + return simdjson_result(stream->doc, stream->error); + } + + simdjson_inline document_stream::iterator& document_stream::iterator::operator++() noexcept { + // If there is an error, then we want the iterator + // to be finished, no matter what. (E.g., we do not + // keep generating documents with errors, or go beyond + // a document with errors.) + // + // Users do not have to call "operator*()" when they use operator++, + // so we need to end the stream in the operator++ function. + // + // Note that setting finished = true is essential otherwise + // we would enter an infinite loop. + if (stream->error) { finished = true; } + // Note that stream->error() is guarded against error conditions + // (it will immediately return if stream->error casts to false). + // In effect, this next function does nothing when (stream->error) + // is true (hence the risk of an infinite loop). + stream->next(); + // If that was the last document, we're finished. + // It is the only type of error we do not want to appear + // in operator*. + if (stream->error == EMPTY) { finished = true; } + // If we had any other kind of error (not EMPTY) then we want + // to pass it along to the operator* and we cannot mark the result + // as "finished" just yet. + return *this; + } + + simdjson_inline bool document_stream::iterator::operator!=(const document_stream::iterator& other) const noexcept { + return finished != other.finished; + } + + simdjson_inline document_stream::iterator document_stream::begin() noexcept { + start(); + // If there are no documents, we're finished. + return iterator(this, error == EMPTY); + } + + simdjson_inline document_stream::iterator document_stream::end() noexcept { + return iterator(this, true); + } + + inline void document_stream::start() noexcept { + if (error) { return; } + error = parser->allocate(batch_size); + if (error) { return; } + // Always run the first stage 1 parse immediately + batch_start = 0; + error = run_stage1(*parser, batch_start); + while (error == EMPTY) { + // In exceptional cases, we may start with an empty block + batch_start = next_batch_start(); + if (batch_start >= len) { return; } + error = run_stage1(*parser, batch_start); + } + if (error) { return; } + doc_index = batch_start; + doc = document(json_iterator(&buf[batch_start], parser)); + doc.iter._streaming = true; + +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread && next_batch_start() < len) { + // Kick off the first thread on next batch if needed + error = stage1_thread_parser.allocate(batch_size); + if (error) { return; } + worker->start_thread(); + start_stage1_thread(); + if (error) { return; } + } +#endif // SIMDJSON_THREADS_ENABLED + } + + inline void document_stream::next() noexcept { + // We always enter at once once in an error condition. + if (error) { return; } + next_document(); + if (error) { return; } + auto cur_struct_index = doc.iter._root - parser->implementation->structural_indexes.get(); + doc_index = batch_start + parser->implementation->structural_indexes[cur_struct_index]; + + // Check if at end of structural indexes (i.e. at end of batch) + if (cur_struct_index >= static_cast(parser->implementation->n_structural_indexes)) { + error = EMPTY; + // Load another batch (if available) + while (error == EMPTY) { + batch_start = next_batch_start(); + if (batch_start >= len) { break; } +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread) { + load_from_stage1_thread(); + } + else { + error = run_stage1(*parser, batch_start); + } +#else + error = run_stage1(*parser, batch_start); +#endif + /** + * Whenever we move to another window, we need to update all pointers to make + * it appear as if the input buffer started at the beginning of the window. + * + * Take this input: + * + * {"z":5} {"1":1,"2":2,"4":4} [7, 10, 9] [15, 11, 12, 13] [154, 110, 112, 1311] + * + * Say you process the following window... + * + * '{"z":5} {"1":1,"2":2,"4":4} [7, 10, 9]' + * + * When you do so, the json_iterator has a pointer at the beginning of the memory region + * (pointing at the beginning of '{"z"...'. + * + * When you move to the window that starts at... + * + * '[7, 10, 9] [15, 11, 12, 13] ... + * + * then it is not sufficient to just run stage 1. You also need to re-anchor the + * json_iterator so that it believes we are starting at '[7, 10, 9]...'. + * + * Under the DOM front-end, this gets done automatically because the parser owns + * the pointer the data, and when you call stage1 and then stage2 on the same + * parser, then stage2 will run on the pointer acquired by stage1. + * + * That is, stage1 calls "this->buf = _buf" so the parser remembers the buffer that + * we used. But json_iterator has no callback when stage1 is called on the parser. + * In fact, I think that the parser is unaware of json_iterator. + * + * + * So we need to re-anchor the json_iterator after each call to stage 1 so that + * all of the pointers are in sync. + */ + doc.iter = json_iterator(&buf[batch_start], parser); + doc.iter._streaming = true; + /** + * End of resync. + */ + + if (error) { continue; } // If the error was EMPTY, we may want to load another batch. + doc_index = batch_start; + } + } + } + + inline void document_stream::next_document() noexcept { + // Go to next place where depth=0 (document depth) + error = doc.iter.skip_child(0); + if (error) { return; } + // Always set depth=1 at the start of document + doc.iter._depth = 1; + // consume comma if comma separated is allowed + if (allow_comma_separated) { doc.iter.consume_character(','); } + // Resets the string buffer at the beginning, thus invalidating the strings. + doc.iter._string_buf_loc = parser->string_buf.get(); + doc.iter._root = doc.iter.position(); + } + + inline size_t document_stream::next_batch_start() const noexcept { + return batch_start + parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]; + } + + inline error_code document_stream::run_stage1(ondemand::parser& p, size_t _batch_start) noexcept { + // This code only updates the structural index in the parser, it does not update any json_iterator + // instance. + size_t remaining = len - _batch_start; + if (remaining <= batch_size) { + return p.implementation->stage1(&buf[_batch_start], remaining, stage1_mode::streaming_final); + } + else { + return p.implementation->stage1(&buf[_batch_start], batch_size, stage1_mode::streaming_partial); + } + } + + simdjson_inline size_t document_stream::iterator::current_index() const noexcept { + return stream->doc_index; + } + + simdjson_inline std::string_view document_stream::iterator::source() const noexcept { + auto depth = stream->doc.iter.depth(); + auto cur_struct_index = stream->doc.iter._root - stream->parser->implementation->structural_indexes.get(); + + // If at root, process the first token to determine if scalar value + if (stream->doc.iter.at_root()) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': // Depth=1 already at start of document + break; + case '}': case ']': + depth--; + break; + default: // Scalar value document + // TODO: Remove any trailing whitespaces + // This returns a string spanning from start of value to the beginning of the next document (excluded) + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[++cur_struct_index] - current_index() - 1); + } + cur_struct_index++; + } + + while (cur_struct_index <= static_cast(stream->parser->implementation->n_structural_indexes)) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': + depth++; + break; + case '}': case ']': + depth--; + break; + } + if (depth == 0) { break; } + cur_struct_index++; + } + + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[cur_struct_index] - current_index() + stream->batch_start + 1);; + } + + inline error_code document_stream::iterator::error() const noexcept { + return stream->error; + } + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void document_stream::load_from_stage1_thread() noexcept { + worker->finish(); + // Swap to the parser that was loaded up in the thread. Make sure the parser has + // enough memory to swap to, as well. + std::swap(stage1_thread_parser, *parser); + error = stage1_thread_error; + if (error) { return; } + + // If there's anything left, start the stage 1 thread! + if (next_batch_start() < len) { + start_stage1_thread(); + } + } + + inline void document_stream::start_stage1_thread() noexcept { + // we call the thread on a lambda that will update + // this->stage1_thread_error + // there is only one thread that may write to this value + // TODO this is NOT exception-safe. + this->stage1_thread_error = UNINITIALIZED; // In case something goes wrong, make sure it's an error + size_t _next_batch_start = this->next_batch_start(); + + worker->run(this, &this->stage1_thread_parser, _next_batch_start); + } + +#endif // SIMDJSON_THREADS_ENABLED + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result::simdjson_result( + ppc64::ondemand::document_stream&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + +} + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H +/* end file simdjson/generic/ondemand/document_stream-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/field-inl.h for ppc64: #include "simdjson/generic/ondemand/field-inl.h" */ +/* begin file simdjson/generic/ondemand/field-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + // clang 6 doesn't think the default constructor can be noexcept, so we make it explicit + simdjson_inline field::field() noexcept : std::pair() {} + + simdjson_inline field::field(raw_json_string key, ondemand::value&& value) noexcept + : std::pair(key, std::forward(value)) + { + } + + simdjson_inline simdjson_result field::start(value_iterator& parent_iter) noexcept { + raw_json_string key; + SIMDJSON_TRY(parent_iter.field_key().get(key)); + SIMDJSON_TRY(parent_iter.field_value()); + return field::start(parent_iter, key); + } + + simdjson_inline simdjson_result field::start(const value_iterator& parent_iter, raw_json_string key) noexcept { + return field(key, parent_iter.child()); + } + + simdjson_inline simdjson_warn_unused simdjson_result field::unescaped_key(bool allow_replacement) noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() but Visual Studio won't let us. + simdjson_result answer = first.unescape(second.iter.json_iter(), allow_replacement); + first.consume(); + return answer; + } + + simdjson_inline raw_json_string field::key() const noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() by Visual Studio won't let us. + return first; + } + + simdjson_inline value& field::value() & noexcept { + return second; + } + + simdjson_inline value field::value() && noexcept { + return std::forward(*this).second; + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + ppc64::ondemand::field&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::key() noexcept { + if (error()) { return error(); } + return first.key(); + } + simdjson_inline simdjson_result simdjson_result::unescaped_key(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.unescaped_key(allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::value() noexcept { + if (error()) { return error(); } + return std::move(first.value()); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H +/* end file simdjson/generic/ondemand/field-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/json_iterator-inl.h for ppc64: #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/json_iterator-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline json_iterator::json_iterator(json_iterator&& other) noexcept + : token(std::forward(other.token)), + parser{ other.parser }, + _string_buf_loc{ other._string_buf_loc }, + error{ other.error }, + _depth{ other._depth }, + _root{ other._root }, + _streaming{ other._streaming } + { + other.parser = nullptr; + } + simdjson_inline json_iterator& json_iterator::operator=(json_iterator&& other) noexcept { + token = other.token; + parser = other.parser; + _string_buf_loc = other._string_buf_loc; + error = other.error; + _depth = other._depth; + _root = other._root; + _streaming = other._streaming; + other.parser = nullptr; + return *this; + } + + simdjson_inline json_iterator::json_iterator(const uint8_t* buf, ondemand::parser* _parser) noexcept + : token(buf, &_parser->implementation->structural_indexes[0]), + parser{ _parser }, + _string_buf_loc{ parser->string_buf.get() }, + _depth{ 1 }, + _root{ parser->implementation->structural_indexes.get() }, + _streaming{ false } + + { + logger::log_headers(); +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif + } + + inline void json_iterator::rewind() noexcept { + token.set_position(root_position()); + logger::log_headers(); // We start again + _string_buf_loc = parser->string_buf.get(); + _depth = 1; + } + + inline bool json_iterator::balanced() const noexcept { + token_iterator ti(token); + int32_t count{ 0 }; + ti.set_position(root_position()); + while (ti.peek() <= peek_last()) { + switch (*ti.return_current_and_advance()) + { + case '[': case '{': + count++; + break; + case ']': case '}': + count--; + break; + default: + break; + } + } + return count == 0; + } + + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and parent_depth, which is a desired effect. The warning does not show up if the + // skip_child() function is not marked inline). + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline error_code json_iterator::skip_child(depth_t parent_depth) noexcept { + if (depth() <= parent_depth) { return SUCCESS; } + switch (*return_current_and_advance()) { + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + + // For the first open array/object in a value, we've already incremented depth, so keep it the same + // We never stop at colon, but if we did, it wouldn't affect depth + case '[': case '{': case ':': + logger::log_start_value(*this, "skip"); + break; + // If there is a comma, we have just finished a value in an array/object, and need to get back in + case ',': + logger::log_value(*this, "skip"); + break; + // ] or } means we just finished a value and need to jump out of the array/object + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } +#if SIMDJSON_CHECK_EOF + // If there are no more tokens, the parent is incomplete. + if (at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "Missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + break; + case '"': + if (*peek() == ':') { + // We are at a key!!! + // This might happen if you just started an object and you skip it immediately. + // Performance note: it would be nice to get rid of this check as it is somewhat + // expensive. + // https://github.com/simdjson/simdjson/issues/1742 + logger::log_value(*this, "key"); + return_current_and_advance(); // eat up the ':' + break; // important!!! + } + simdjson_fallthrough; + // Anything else must be a scalar value + default: + // For the first scalar, we will have incremented depth already, so we decrement it here. + logger::log_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + } + + // Now that we've considered the first value, we only increment/decrement for arrays/objects + while (position() < end_position()) { + switch (*return_current_and_advance()) { + case '[': case '{': + logger::log_start_value(*this, "skip"); + _depth++; + break; + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + default: + logger::log_value(*this, "skip", ""); + break; + } + } + + return report_error(TAPE_ERROR, "not enough close braces"); + } + + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool json_iterator::at_root() const noexcept { + return position() == root_position(); + } + + simdjson_inline bool json_iterator::is_single_token() const noexcept { + return parser->implementation->n_structural_indexes == 1; + } + + simdjson_inline bool json_iterator::streaming() const noexcept { + return _streaming; + } + + simdjson_inline token_position json_iterator::root_position() const noexcept { + return _root; + } + + simdjson_inline void json_iterator::assert_at_document_depth() const noexcept { + SIMDJSON_ASSUME(_depth == 1); + } + + simdjson_inline void json_iterator::assert_at_root() const noexcept { + SIMDJSON_ASSUME(_depth == 1); +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + // Under Visual Studio, the next SIMDJSON_ASSUME fails with: the argument + // has side effects that will be discarded. + SIMDJSON_ASSUME(token.position() == _root); +#endif + } + + simdjson_inline void json_iterator::assert_more_tokens(uint32_t required_tokens) const noexcept { + assert_valid_position(token._position + required_tokens - 1); + } + + simdjson_inline void json_iterator::assert_valid_position(token_position position) const noexcept { +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(position >= &parser->implementation->structural_indexes[0]); + SIMDJSON_ASSUME(position < &parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]); +#endif + } + + simdjson_inline bool json_iterator::at_end() const noexcept { + return position() == end_position(); + } + simdjson_inline token_position json_iterator::end_position() const noexcept { + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + return &parser->implementation->structural_indexes[n_structural_indexes]; + } + + inline std::string json_iterator::to_string() const noexcept { + if (!is_alive()) { return "dead json_iterator instance"; } + const char* current_structural = reinterpret_cast(token.peek()); + return std::string("json_iterator [ depth : ") + std::to_string(_depth) + + std::string(", structural : '") + std::string(current_structural, 1) + + std::string("', offset : ") + std::to_string(token.current_offset()) + + std::string("', error : ") + error_message(error) + + std::string(" ]"); + } + + inline simdjson_result json_iterator::current_location() const noexcept { + if (!is_alive()) { // Unrecoverable error + if (!at_root()) { + return reinterpret_cast(token.peek(-1)); + } + else { + return reinterpret_cast(token.peek()); + } + } + if (at_end()) { + return OUT_OF_BOUNDS; + } + return reinterpret_cast(token.peek()); + } + + simdjson_inline bool json_iterator::is_alive() const noexcept { + return parser; + } + + simdjson_inline void json_iterator::abandon() noexcept { + parser = nullptr; + _depth = 0; + } + + simdjson_inline const uint8_t* json_iterator::return_current_and_advance() noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif // SIMDJSON_CHECK_EOF + return token.return_current_and_advance(); + } + + simdjson_inline const uint8_t* json_iterator::unsafe_pointer() const noexcept { + // deliberately done without safety guard: + return token.peek(); + } + + simdjson_inline const uint8_t* json_iterator::peek(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // SIMDJSON_CHECK_EOF + return token.peek(delta); + } + + simdjson_inline uint32_t json_iterator::peek_length(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // #if SIMDJSON_CHECK_EOF + return token.peek_length(delta); + } + + simdjson_inline const uint8_t* json_iterator::peek(token_position position) const noexcept { + // todo: currently we require end-of-string buffering, but the following + // assert_valid_position should be turned on if/when we lift that condition. + // assert_valid_position(position); + // This is almost surely related to SIMDJSON_CHECK_EOF but given that SIMDJSON_CHECK_EOF + // is ON by default, we have no choice but to disable it for real with a comment. + return token.peek(position); + } + + simdjson_inline uint32_t json_iterator::peek_length(token_position position) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_valid_position(position); +#endif // SIMDJSON_CHECK_EOF + return token.peek_length(position); + } + + simdjson_inline token_position json_iterator::last_position() const noexcept { + // The following line fails under some compilers... + // SIMDJSON_ASSUME(parser->implementation->n_structural_indexes > 0); + // since it has side-effects. + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + SIMDJSON_ASSUME(n_structural_indexes > 0); + return &parser->implementation->structural_indexes[n_structural_indexes - 1]; + } + simdjson_inline const uint8_t* json_iterator::peek_last() const noexcept { + return token.peek(last_position()); + } + + simdjson_inline void json_iterator::ascend_to(depth_t parent_depth) noexcept { + SIMDJSON_ASSUME(parent_depth >= 0 && parent_depth < INT32_MAX - 1); + SIMDJSON_ASSUME(_depth == parent_depth + 1); + _depth = parent_depth; + } + + simdjson_inline void json_iterator::descend_to(depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); + _depth = child_depth; + } + + simdjson_inline depth_t json_iterator::depth() const noexcept { + return _depth; + } + + simdjson_inline uint8_t*& json_iterator::string_buf_loc() noexcept { + return _string_buf_loc; + } + + simdjson_inline error_code json_iterator::report_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error != SUCCESS && _error != UNINITIALIZED && _error != INCORRECT_TYPE && _error != NO_SUCH_FIELD); + logger::log_error(*this, message); + error = _error; + return error; + } + + simdjson_inline token_position json_iterator::position() const noexcept { + return token.position(); + } + + simdjson_inline simdjson_result json_iterator::unescape(raw_json_string in, bool allow_replacement) noexcept { + return parser->unescape(in, _string_buf_loc, allow_replacement); + } + + simdjson_inline simdjson_result json_iterator::unescape_wobbly(raw_json_string in) noexcept { + return parser->unescape_wobbly(in, _string_buf_loc); + } + + simdjson_inline void json_iterator::reenter_child(token_position position, depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); +#if SIMDJSON_DEVELOPMENT_CHECKS +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(size_t(child_depth) < parser->max_depth()); + SIMDJSON_ASSUME(position >= parser->start_positions[child_depth]); +#endif +#endif + token.set_position(position); + _depth = child_depth; + } + + simdjson_inline error_code json_iterator::consume_character(char c) noexcept { + if (*peek() == c) { + return_current_and_advance(); + return SUCCESS; + } + return TAPE_ERROR; + } + +#if SIMDJSON_DEVELOPMENT_CHECKS + + simdjson_inline token_position json_iterator::start_position(depth_t depth) const noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + return size_t(depth) < parser->max_depth() ? parser->start_positions[depth] : 0; + } + + simdjson_inline void json_iterator::set_start_position(depth_t depth, token_position position) noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + if (size_t(depth) < parser->max_depth()) { parser->start_positions[depth] = position; } + } + +#endif + + + simdjson_inline error_code json_iterator::optional_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error == INCORRECT_TYPE || _error == NO_SUCH_FIELD); + logger::log_error(*this, message); + return _error; + } + + + simdjson_warn_unused simdjson_inline bool json_iterator::copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept { + // This function is not expected to be called in performance-sensitive settings. + // Let us guard against silly cases: + if ((N < max_len) || (N == 0)) { return false; } + // Copy to the buffer. + std::memcpy(tmpbuf, json, max_len); + if (N > max_len) { // We pad whatever remains with ' '. + std::memset(tmpbuf + max_len, ' ', N - max_len); + } + return true; + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::json_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/json_iterator-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/json_type-inl.h for ppc64: #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* begin file simdjson/generic/ondemand/json_type-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept { + switch (type) { + case json_type::array: out << "array"; break; + case json_type::object: out << "object"; break; + case json_type::number: out << "number"; break; + case json_type::string: out << "string"; break; + case json_type::boolean: out << "boolean"; break; + case json_type::null: out << "null"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false) { + return out << type.value(); + } +#endif + + + + simdjson_inline number_type number::get_number_type() const noexcept { + return type; + } + + simdjson_inline bool number::is_uint64() const noexcept { + return get_number_type() == number_type::unsigned_integer; + } + + simdjson_inline uint64_t number::get_uint64() const noexcept { + return payload.unsigned_integer; + } + + simdjson_inline number::operator uint64_t() const noexcept { + return get_uint64(); + } + + + simdjson_inline bool number::is_int64() const noexcept { + return get_number_type() == number_type::signed_integer; + } + + simdjson_inline int64_t number::get_int64() const noexcept { + return payload.signed_integer; + } + + simdjson_inline number::operator int64_t() const noexcept { + return get_int64(); + } + + simdjson_inline bool number::is_double() const noexcept { + return get_number_type() == number_type::floating_point_number; + } + + simdjson_inline double number::get_double() const noexcept { + return payload.floating_point_number; + } + + simdjson_inline number::operator double() const noexcept { + return get_double(); + } + + simdjson_inline double number::as_double() const noexcept { + if (is_double()) { + return payload.floating_point_number; + } + if (is_int64()) { + return double(payload.signed_integer); + } + return double(payload.unsigned_integer); + } + + simdjson_inline void number::append_s64(int64_t value) noexcept { + payload.signed_integer = value; + type = number_type::signed_integer; + } + + simdjson_inline void number::append_u64(uint64_t value) noexcept { + payload.unsigned_integer = value; + type = number_type::unsigned_integer; + } + + simdjson_inline void number::append_double(double value) noexcept { + payload.floating_point_number = value; + type = number_type::floating_point_number; + } + + simdjson_inline void number::skip_double() noexcept { + type = number_type::floating_point_number; + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::json_type&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H +/* end file simdjson/generic/ondemand/json_type-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/logger-inl.h for ppc64: #include "simdjson/generic/ondemand/logger-inl.h" */ +/* begin file simdjson/generic/ondemand/logger-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static int log_depth = 0; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + template + static inline std::string string_format(const std::string& format, const Args&... args) + { + SIMDJSON_PUSH_DISABLE_ALL_WARNINGS + int size_s = std::snprintf(nullptr, 0, format.c_str(), args...) + 1; + auto size = static_cast(size_s); + if (size <= 0) return std::string(); + std::unique_ptr buf(new char[size]); + std::snprintf(buf.get(), size, format.c_str(), args...); + SIMDJSON_POP_DISABLE_WARNINGS + return std::string(buf.get(), buf.get() + size - 1); + } + + static inline log_level get_log_level_from_env() + { + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe + char* lvl = getenv("SIMDJSON_LOG_LEVEL"); + SIMDJSON_POP_DISABLE_WARNINGS + if (lvl && simdjson_strcasecmp(lvl, "ERROR") == 0) { return log_level::error; } + return log_level::info; + } + + static inline log_level log_threshold() + { + static log_level threshold = get_log_level_from_env(); + return threshold; + } + + static inline bool should_log(log_level level) + { + return level >= log_threshold(); + } + + inline void log_event(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "", type, detail, log_level::info); + } + inline void log_value(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "+", type, detail, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + inline void log_start_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_line(iter, "+", type, "", delta, depth_delta, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + + inline void log_end_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + if (LOG_ENABLED) { log_depth--; } + log_line(iter, "-", type, "", delta, depth_delta, log_level::info); + } + + inline void log_error(const json_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_line(iter, "ERROR: ", error, detail, delta, depth_delta, log_level::error); + } + inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail) noexcept { + log_line(iter, index, depth, "ERROR: ", error, detail, log_level::error); + } + + inline void log_event(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_event(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_value(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_value(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_start_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_start_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_end_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_end_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_error(const value_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_error(iter.json_iter(), error, detail, delta, depth_delta); + } + + inline void log_headers() noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(log_level::info))) { + // Technically a static variable is not thread-safe, but if you are using threads and logging... well... + static bool displayed_hint{ false }; + log_depth = 0; + printf("\n"); + if (!displayed_hint) { + // We only print this helpful header once. + printf("# Logging provides the depth and position of the iterator user-visible steps:\n"); + printf("# +array says 'this is where we were when we discovered the start array'\n"); + printf( + "# -array says 'this is where we were when we ended the array'\n"); + printf("# skip says 'this is a structural or value I am skipping'\n"); + printf("# +/-skip says 'this is a start/end array or object I am skipping'\n"); + printf("#\n"); + printf("# The indentation of the terms (array, string,...) indicates the depth,\n"); + printf("# in addition to the depth being displayed.\n"); + printf("#\n"); + printf("# Every token in the document has a single depth determined by the tokens before it,\n"); + printf("# and is not affected by what the token actually is.\n"); + printf("#\n"); + printf("# Not all structural elements are presented as tokens in the logs.\n"); + printf("#\n"); + printf("# We never give control to the user within an empty array or an empty object.\n"); + printf("#\n"); + printf("# Inside an array, having a depth greater than the array's depth means that\n"); + printf("# we are pointing inside a value.\n"); + printf("# Having a depth equal to the array means that we are pointing right before a value.\n"); + printf("# Having a depth smaller than the array means that we have moved beyond the array.\n"); + displayed_hint = true; + } + printf("\n"); + printf("| %-*s ", LOG_EVENT_LEN, "Event"); + printf("| %-*s ", LOG_BUFFER_LEN, "Buffer"); + printf("| %-*s ", LOG_SMALL_BUFFER_LEN, "Next"); + // printf("| %-*s ", 5, "Next#"); + printf("| %-*s ", 5, "Depth"); + printf("| Detail "); + printf("|\n"); + + printf("|%.*s", LOG_EVENT_LEN + 2, DASHES); + printf("|%.*s", LOG_BUFFER_LEN + 2, DASHES); + printf("|%.*s", LOG_SMALL_BUFFER_LEN + 2, DASHES); + // printf("|%.*s", 5+2, DASHES); + printf("|%.*s", 5 + 2, DASHES); + printf("|--------"); + printf("|\n"); + fflush(stdout); + } + } + } + + template + inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, log_level level, Args&&... args) noexcept { + log_line(iter, iter.position() + delta, depth_t(iter.depth() + depth_delta), title_prefix, title, detail, level, std::forward(args)...); + } + + template + inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, log_level level, Args&&... args) noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(level))) { + const int indent = depth * 2; + const auto buf = iter.token.buf; + auto msg = string_format(title, std::forward(args)...); + printf("| %*s%s%-*s ", indent, "", title_prefix, + LOG_EVENT_LEN - indent - int(strlen(title_prefix)), msg.c_str()); + { + // Print the current structural. + printf("| "); + // Before we begin, the index might point right before the document. + // This could be unsafe, see https://github.com/simdjson/simdjson/discussions/1938 + if (index < iter._root) { + printf("%*s", LOG_BUFFER_LEN, ""); + } + else { + auto current_structural = &buf[*index]; + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current_structural[i])); + } + } + printf(" "); + } + { + // Print the next structural. + printf("| "); + auto next_structural = &buf[*(index + 1)]; + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next_structural[i])); + } + printf(" "); + } + // printf("| %5u ", *(index+1)); + printf("| %5i ", depth); + printf("| %6.*s ", int(detail.size()), detail.data()); + printf("|\n"); + fflush(stdout); + } + } + } + + } // namespace logger + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H +/* end file simdjson/generic/ondemand/logger-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/object-inl.h for ppc64: #include "simdjson/generic/ondemand/object-inl.h" */ +/* begin file simdjson/generic/ondemand/object-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) & noexcept { + return find_field_unordered(key); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) && noexcept { + return std::forward(*this).find_field_unordered(key); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + + simdjson_inline simdjson_result object::start(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_object().error()); + return object(iter); + } + simdjson_inline simdjson_result object::start_root(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_root_object().error()); + return object(iter); + } + simdjson_inline error_code object::consume() noexcept { + if (iter.is_at_key()) { + /** + * whenever you are pointing at a key, calling skip_child() is + * unsafe because you will hit a string and you will assume that + * it is string value, and this mistake will lead you to make bad + * depth computation. + */ + /** + * We want to 'consume' the key. We could really + * just do _json_iter->return_current_and_advance(); at this + * point, but, for clarity, we will use the high-level API to + * eat the key. We assume that the compiler optimizes away + * most of the work. + */ + simdjson_unused raw_json_string actual_key; + auto error = iter.field_key().get(actual_key); + if (error) { iter.abandon(); return error; }; + // Let us move to the value while we are at it. + if ((error = iter.field_value())) { iter.abandon(); return error; } + } + auto error_skip = iter.json_iter().skip_child(iter.depth() - 1); + if (error_skip) { iter.abandon(); } + return error_skip; + } + + simdjson_inline simdjson_result object::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + const uint8_t* final_point{ iter._json_iter->peek() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result object::started(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.started_object().error()); + return object(iter); + } + + simdjson_inline object object::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline object::object(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result object::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return object_iterator(iter); + } + simdjson_inline simdjson_result object::end() noexcept { + return object_iterator(iter); + } + + inline simdjson_result object::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + size_t slash = json_pointer.find('/'); + std::string_view key = json_pointer.substr(0, slash); + // Grab the child with the given key + simdjson_result child; + + // If there is an escape character in the key, unescape it and then get the child. + size_t escape = key.find('~'); + if (escape != std::string_view::npos) { + // Unescape the key + std::string unescaped(key); + do { + switch (unescaped[escape + 1]) { + case '0': + unescaped.replace(escape, 2, "~"); + break; + case '1': + unescaped.replace(escape, 2, "/"); + break; + default: + return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); + } + escape = unescaped.find('~', escape + 1); + } while (escape != std::string::npos); + child = find_field(unescaped); // Take note find_field does not unescape keys when matching + } + else { + child = find_field(key); + } + if (child.error()) { + return child; // we do not continue if there was an error + } + // If there is a /, we have to recurse and look up more of the path + if (slash != std::string_view::npos) { + child = child.at_pointer(json_pointer.substr(slash)); + } + return child; + } + + simdjson_inline simdjson_result object::count_fields() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the object after counting the number of elements. + iter.reset_object(); + return count; + } + + simdjson_inline simdjson_result object::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_object().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + simdjson_inline simdjson_result object::reset() & noexcept { + return iter.reset_object(); + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::object&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first)[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + inline simdjson_result simdjson_result::reset() noexcept { + if (error()) { return error(); } + return first.reset(); + } + + inline simdjson_result simdjson_result::is_empty() noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H +/* end file simdjson/generic/ondemand/object-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/object_iterator-inl.h for ppc64: #include "simdjson/generic/ondemand/object_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/object_iterator-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + // + // object_iterator + // + + simdjson_inline object_iterator::object_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result object_iterator::operator*() noexcept { + error_code error = iter.error(); + if (error) { iter.abandon(); return error; } + auto result = field::start(iter); + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (result.error()) { iter.abandon(); } + return result; + } + simdjson_inline bool object_iterator::operator==(const object_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool object_iterator::operator!=(const object_iterator&) const noexcept { + return iter.is_open(); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline object_iterator& object_iterator::operator++() noexcept { + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (!iter.is_open()) { return *this; } // Iterator will be released if there is an error + + simdjson_unused error_code error; + if ((error = iter.skip_child())) { return *this; } + + simdjson_unused bool has_value; + if ((error = iter.has_next_field().get(has_value))) { return *this; }; + return *this; + } + SIMDJSON_POP_DISABLE_WARNINGS + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter.depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the object is first found and the iterator is just past the {. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the , or } before the next value. In this state, + // depth == iter.depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter.depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter.depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the object iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet field may be missing or not be an + // object--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter.depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between fields, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter.depth == depth, and at_start == false. + // + // Errors that occur while reading a field to give to the user (such as when the key is not a + // string or the field is missing a colon) are yielded immediately. Depth is then decremented, + // moving to the Finished state without transitioning through an Error state at all. + // + // ## Terminal State + // + // The terminal state has iter.depth < depth. at_start is always false. + // + // - Finished: When we have reached a }, we are finished. We signal this by decrementing depth. + // In this state, iter.depth < depth, at_start == false, and error == SUCCESS. + // + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + ppc64::ondemand::object_iterator&& value + ) noexcept + : implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + // Checks for ']' and ',' + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++first; + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/object_iterator-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/parser-inl.h for ppc64: #include "simdjson/generic/ondemand/parser-inl.h" */ +/* begin file simdjson/generic/ondemand/parser-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string_view.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/dom/base.h" // for MINIMAL_DOCUMENT_CAPACITY */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline parser::parser(size_t max_capacity) noexcept + : _max_capacity{ max_capacity } { + } + + simdjson_warn_unused simdjson_inline error_code parser::allocate(size_t new_capacity, size_t new_max_depth) noexcept { + if (new_capacity > max_capacity()) { return CAPACITY; } + if (string_buf && new_capacity == capacity() && new_max_depth == max_depth()) { return SUCCESS; } + + // string_capacity copied from document::allocate + _capacity = 0; + size_t string_capacity = SIMDJSON_ROUNDUP_N(5 * new_capacity / 3 + SIMDJSON_PADDING, 64); + string_buf.reset(new (std::nothrow) uint8_t[string_capacity]); +#if SIMDJSON_DEVELOPMENT_CHECKS + start_positions.reset(new (std::nothrow) token_position[new_max_depth]); +#endif + if (implementation) { + SIMDJSON_TRY(implementation->set_capacity(new_capacity)); + SIMDJSON_TRY(implementation->set_max_depth(new_max_depth)); + } + else { + SIMDJSON_TRY(simdjson::get_active_implementation()->create_dom_parser_implementation(new_capacity, new_max_depth, implementation)); + } + _capacity = new_capacity; + _max_depth = new_max_depth; + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length() || !string_buf) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return document::start({ reinterpret_cast(json.data()), this }); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const char* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const uint8_t* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string_view json, size_t allocated) & noexcept { + return iterate(padded_string_view(json, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string& json) & noexcept { + if (json.capacity() - json.size() < SIMDJSON_PADDING) { + json.reserve(json.size() + SIMDJSON_PADDING); + } + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const std::string& json) & noexcept { + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + padded_string_view json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + const padded_string& json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate_raw(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length()) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return json_iterator(reinterpret_cast(json.data()), this); + } + + inline simdjson_result parser::iterate_many(const uint8_t* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + if (allow_comma_separated && batch_size < len) { batch_size = len; } + return document_stream(*this, buf, len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const char* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(reinterpret_cast(buf), len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const std::string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const padded_string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + + simdjson_inline size_t parser::capacity() const noexcept { + return _capacity; + } + simdjson_inline size_t parser::max_capacity() const noexcept { + return _max_capacity; + } + simdjson_inline size_t parser::max_depth() const noexcept { + return _max_depth; + } + + simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { + if (max_capacity < dom::MINIMAL_DOCUMENT_CAPACITY) { + _max_capacity = max_capacity; + } + else { + _max_capacity = dom::MINIMAL_DOCUMENT_CAPACITY; + } + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement) const noexcept { + uint8_t* end = implementation->parse_string(in.buf, dst, allow_replacement); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept { + uint8_t* end = implementation->parse_wobbly_string(in.buf, dst); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::parser&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H +/* end file simdjson/generic/ondemand/parser-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/raw_json_string-inl.h for ppc64: #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + namespace ppc64 { + namespace ondemand { + + simdjson_inline raw_json_string::raw_json_string(const uint8_t* _buf) noexcept : buf{ _buf } {} + + simdjson_inline const char* raw_json_string::raw() const noexcept { return reinterpret_cast(buf); } + + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(std::string_view target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; pos < target.size() && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(const char* target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; target[pos] && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; target[pos]; pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(size_t length, std::string_view target) const noexcept { + // If we are going to call memcmp, then we must know something about the length of the raw_json_string. + return (length >= target.size()) && (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + + simdjson_inline bool raw_json_string::unsafe_is_equal(std::string_view target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + if (target.size() <= SIMDJSON_PADDING) { + return (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + const char* r{ raw() }; + size_t pos{ 0 }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(std::string_view target) const noexcept { + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(const char* target) const noexcept { + // Assumptions: 'target' does not contain unescaped quote characters, is null terminated and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(const char* target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept { + return a.unsafe_is_equal(c); + } + + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept { + return a == c; + } + + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept { + return !(a == c); + } + + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept { + return !(a == c); + } + + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape(json_iterator& iter, bool allow_replacement) const noexcept { + return iter.unescape(*this, allow_replacement); + } + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape_wobbly(json_iterator& iter) const noexcept { + return iter.unescape_wobbly(*this); + } + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream& out, const raw_json_string& str) noexcept { + bool in_escape = false; + const char* s = str.raw(); + while (true) { + switch (*s) { + case '\\': in_escape = !in_escape; break; + case '"': if (in_escape) { in_escape = false; } + else { return out; } break; + default: if (in_escape) { in_escape = false; } + } + out << *s; + s++; + } + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::raw_json_string&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::raw() const noexcept { + if (error()) { return error(); } + return first.raw(); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape(ppc64::ondemand::json_iterator& iter, bool allow_replacement) const noexcept { + if (error()) { return error(); } + return first.unescape(iter, allow_replacement); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape_wobbly(ppc64::ondemand::json_iterator& iter) const noexcept { + if (error()) { return error(); } + return first.unescape_wobbly(iter); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H +/* end file simdjson/generic/ondemand/raw_json_string-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/serialization-inl.h for ppc64: #include "simdjson/generic/ondemand/serialization-inl.h" */ +/* begin file simdjson/generic/ondemand/serialization-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/serialization.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + inline std::string_view trim(const std::string_view str) noexcept { + // We can almost surely do better by rolling our own find_first_not_of function. + size_t first = str.find_first_not_of(" \t\n\r"); + // If we have the empty string (just white space), then no trimming is possible, and + // we return the empty string_view. + if (std::string_view::npos == first) { return std::string_view(); } + size_t last = str.find_last_not_of(" \t\n\r"); + return str.substr(first, (last - first + 1)); + } + + + inline simdjson_result to_json_string(ppc64::ondemand::document& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(ppc64::ondemand::document_reference& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(ppc64::ondemand::value& x) noexcept { + /** + * If we somehow receive a value that has already been consumed, + * then the following code could be in trouble. E.g., we create + * an array as needed, but if an array was already created, then + * it could be bad. + */ + using namespace ppc64::ondemand; + ppc64::ondemand::json_type t; + auto error = x.type().get(t); + if (error != SUCCESS) { return error; } + switch (t) + { + case json_type::array: + { + ppc64::ondemand::array array; + error = x.get_array().get(array); + if (error) { return error; } + return to_json_string(array); + } + case json_type::object: + { + ppc64::ondemand::object object; + error = x.get_object().get(object); + if (error) { return error; } + return to_json_string(object); + } + default: + return trim(x.raw_json_token()); + } + } + + inline simdjson_result to_json_string(ppc64::ondemand::object& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(ppc64::ondemand::array& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } +} // namespace simdjson + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::document_reference& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::ppc64::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + } + } +} // namespace simdjson::ppc64::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H +/* end file simdjson/generic/ondemand/serialization-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/token_iterator-inl.h for ppc64: #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/token_iterator-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline token_iterator::token_iterator( + const uint8_t* _buf, + token_position position + ) noexcept : buf{ _buf }, _position{ position } + { + } + + simdjson_inline uint32_t token_iterator::current_offset() const noexcept { + return *(_position); + } + + + simdjson_inline const uint8_t* token_iterator::return_current_and_advance() noexcept { + return &buf[*(_position++)]; + } + + simdjson_inline const uint8_t* token_iterator::peek(token_position position) const noexcept { + return &buf[*position]; + } + simdjson_inline uint32_t token_iterator::peek_index(token_position position) const noexcept { + return *position; + } + simdjson_inline uint32_t token_iterator::peek_length(token_position position) const noexcept { + return *(position + 1) - *position; + } + + simdjson_inline const uint8_t* token_iterator::peek(int32_t delta) const noexcept { + return &buf[*(_position + delta)]; + } + simdjson_inline uint32_t token_iterator::peek_index(int32_t delta) const noexcept { + return *(_position + delta); + } + simdjson_inline uint32_t token_iterator::peek_length(int32_t delta) const noexcept { + return *(_position + delta + 1) - *(_position + delta); + } + + simdjson_inline token_position token_iterator::position() const noexcept { + return _position; + } + simdjson_inline void token_iterator::set_position(token_position target_position) noexcept { + _position = target_position; + } + + simdjson_inline bool token_iterator::operator==(const token_iterator& other) const noexcept { + return _position == other._position; + } + simdjson_inline bool token_iterator::operator!=(const token_iterator& other) const noexcept { + return _position != other._position; + } + simdjson_inline bool token_iterator::operator>(const token_iterator& other) const noexcept { + return _position > other._position; + } + simdjson_inline bool token_iterator::operator>=(const token_iterator& other) const noexcept { + return _position >= other._position; + } + simdjson_inline bool token_iterator::operator<(const token_iterator& other) const noexcept { + return _position < other._position; + } + simdjson_inline bool token_iterator::operator<=(const token_iterator& other) const noexcept { + return _position <= other._position; + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::token_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/token_iterator-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/value-inl.h for ppc64: #include "simdjson/generic/ondemand/value-inl.h" */ +/* begin file simdjson/generic/ondemand/value-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline value::value(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + simdjson_inline value value::start(const value_iterator& iter) noexcept { + return iter; + } + simdjson_inline value value::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline simdjson_result value::get_array() noexcept { + return array::start(iter); + } + simdjson_inline simdjson_result value::get_object() noexcept { + return object::start(iter); + } + simdjson_inline simdjson_result value::start_or_resume_object() noexcept { + if (iter.at_start()) { + return get_object(); + } + else { + return object::resume(iter); + } + } + + simdjson_inline simdjson_result value::get_raw_json_string() noexcept { + return iter.get_raw_json_string(); + } + simdjson_inline simdjson_result value::get_string(bool allow_replacement) noexcept { + return iter.get_string(allow_replacement); + } + template + simdjson_inline error_code value::get_string(string_type& receiver, bool allow_replacement) noexcept { + return iter.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result value::get_wobbly_string() noexcept { + return iter.get_wobbly_string(); + } + simdjson_inline simdjson_result value::get_double() noexcept { + return iter.get_double(); + } + simdjson_inline simdjson_result value::get_double_in_string() noexcept { + return iter.get_double_in_string(); + } + simdjson_inline simdjson_result value::get_uint64() noexcept { + return iter.get_uint64(); + } + simdjson_inline simdjson_result value::get_uint64_in_string() noexcept { + return iter.get_uint64_in_string(); + } + simdjson_inline simdjson_result value::get_int64() noexcept { + return iter.get_int64(); + } + simdjson_inline simdjson_result value::get_int64_in_string() noexcept { + return iter.get_int64_in_string(); + } + simdjson_inline simdjson_result value::get_bool() noexcept { + return iter.get_bool(); + } + simdjson_inline simdjson_result value::is_null() noexcept { + return iter.is_null(); + } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_array(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_object(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_number(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_double(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_bool(); } + + template simdjson_inline error_code value::get(T& out) noexcept { + return get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline value::operator array() noexcept(false) { + return get_array(); + } + simdjson_inline value::operator object() noexcept(false) { + return get_object(); + } + simdjson_inline value::operator uint64_t() noexcept(false) { + return get_uint64(); + } + simdjson_inline value::operator int64_t() noexcept(false) { + return get_int64(); + } + simdjson_inline value::operator double() noexcept(false) { + return get_double(); + } + simdjson_inline value::operator std::string_view() noexcept(false) { + return get_string(false); + } + simdjson_inline value::operator raw_json_string() noexcept(false) { + return get_raw_json_string(); + } + simdjson_inline value::operator bool() noexcept(false) { + return get_bool(); + } +#endif + + simdjson_inline simdjson_result value::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result value::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result value::count_elements() & noexcept { + simdjson_result answer; + auto a = get_array(); + answer = a.count_elements(); + // count_elements leaves you pointing inside the array, at the first element. + // We need to move back so that the user can create a new array (which requires that + // we point at '['). + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::count_fields() & noexcept { + simdjson_result answer; + auto a = get_object(); + answer = a.count_fields(); + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::at(size_t index) noexcept { + auto a = get_array(); + return a.at(index); + } + + simdjson_inline simdjson_result value::find_field(std::string_view key) noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result value::find_field(const char* key) noexcept { + return start_or_resume_object().find_field(key); + } + + simdjson_inline simdjson_result value::find_field_unordered(std::string_view key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result value::find_field_unordered(const char* key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + + simdjson_inline simdjson_result value::operator[](std::string_view key) noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result value::operator[](const char* key) noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline simdjson_result value::type() noexcept { + return iter.type(); + } + + simdjson_inline simdjson_result value::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool value::is_negative() noexcept { + return iter.is_negative(); + } + + simdjson_inline simdjson_result value::is_integer() noexcept { + return iter.is_integer(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number_type() noexcept { + return iter.get_number_type(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number() noexcept { + return iter.get_number(); + } + + simdjson_inline std::string_view value::raw_json_token() noexcept { + return std::string_view(reinterpret_cast(iter.peek_start()), iter.peek_start_length()); + } + + simdjson_inline simdjson_result value::raw_json() noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: { + ondemand::array array; + SIMDJSON_TRY(get_array().get(array)); + return array.raw_json(); + } + case json_type::object: { + ondemand::object object; + SIMDJSON_TRY(get_object().get(object)); + return object.raw_json(); + } + default: + return raw_json_token(); + } + } + + simdjson_inline simdjson_result value::current_location() noexcept { + return iter.json_iter().current_location(); + } + + simdjson_inline int32_t value::current_depth() const noexcept { + return iter.json_iter().depth(); + } + + simdjson_inline simdjson_result value::at_pointer(std::string_view json_pointer) noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + ppc64::ondemand::value&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + if (error()) { return error(); } + return {}; + } + + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) noexcept { + if (error()) { return error(); } + return first[key]; + } + + simdjson_inline simdjson_result simdjson_result::get_array() noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return first.get(); + } + template simdjson_inline error_code simdjson_result::get(T& out) noexcept { + if (error()) { return error(); } + return first.get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return std::move(first); + } + template<> simdjson_inline error_code simdjson_result::get(ppc64::ondemand::value& out) noexcept { + if (error()) { return error(); } + out = first; + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator ppc64::ondemand::array() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::object() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator ppc64::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H +/* end file simdjson/generic/ondemand/value-inl.h for ppc64 */ +/* including simdjson/generic/ondemand/value_iterator-inl.h for ppc64: #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/value_iterator-inl.h for ppc64 */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/atomparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace ppc64 { + namespace ondemand { + + simdjson_inline value_iterator::value_iterator( + json_iterator* json_iter, + depth_t depth, + token_position start_position + ) noexcept : _json_iter{ json_iter }, _depth{ depth }, _start_position{ start_position } + { + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_root_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_object() noexcept { + assert_at_container_start(); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + if (*_json_iter->peek() == '}') { + logger::log_value(*_json_iter, "empty object"); + _json_iter->return_current_and_advance(); + end_container(); + return false; + } + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_object() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // object: e.g., `{"a":2} foo }`. Users concerned with garbage content should + // call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != '}') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing } at end"); + } + // If the last character is } *and* the first gibberish character is also '}' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == '}') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed object. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_object() noexcept { + auto error = check_root_object(); + if (error) { return error; } + return started_object(); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::end_container() noexcept { +#if SIMDJSON_CHECK_EOF + if (depth() > 1 && at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing parent ] or }"); } + // if (depth() <= 1 && !at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + _json_iter->ascend_to(depth() - 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_field() noexcept { + assert_at_next(); + + // It's illegal to call this unless there are more tokens: anything that ends in } or ] is + // obligated to verify there are more tokens if they are not the top level. + switch (*_json_iter->return_current_and_advance()) { + case '}': + logger::log_end_value(*_json_iter, "object"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between object fields"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_raw(const std::string_view key) noexcept { + error_code error; + bool has_value; + // + // Initially, the object can be in one of a few different places: + // + // 1. The start of the object, at the first field: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + if (at_first_field()) { + has_value = true; + + // + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + return false; + + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + if ((error = skip_child())) { abandon(); return error; } + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + while (has_value) { + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + //if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); // Skip the value entirely + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + + // If the loop ended, we're out of fields to look at. + return false; + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_unordered_raw(const std::string_view key) noexcept { + /** + * When find_field_unordered_raw is called, we can either be pointing at the + * first key, pointing outside (at the closing brace) or if a key was matched + * we can be either pointing right afterthe ':' right before the value (that we need skip), + * or we may have consumed the value and we might be at a comma or at the + * final brace (ready for a call to has_next_field()). + */ + error_code error; + bool has_value; + + // First, we scan from that point to the end. + // If we don't find a match, we may loop back around, and scan from the beginning to that point. + token_position search_start = _json_iter->position(); + + // We want to know whether we need to go back to the beginning. + bool at_first = at_first_field(); + /////////////// + // Initially, the object can be in one of a few different places: + // + // 1. At the first key: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + // + if (at_first) { + has_value = true; + + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { + +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + SIMDJSON_TRY(reset_object().get(has_value)); + at_first = true; + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + // If someone queried a key but they not did access the value, then we are left pointing + // at the ':' and we need to move forward through the value... If the value was + // processed then skip_child() does not move the iterator (but may adjust the depth). + if ((error = skip_child())) { abandon(); return error; } + search_start = _json_iter->position(); + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + + // After initial processing, we will be in one of two states: + // + // ``` + // // At the beginning of a field + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // At the end of the object + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // ``` + // + // Next, we find a match starting from the current position. + while (has_value) { + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + // Performance note: it maybe wasteful to rewind to the beginning when there might be + // no other query following. Indeed, it would require reskipping the whole object. + // Instead, you can just stay where you are. If there is a new query, there is always time + // to rewind. + if (at_first) { return false; } + + // If we reach the end without finding a match, search the rest of the fields starting at the + // beginning of the object. + // (We have already run through the object before, so we've already validated its structure. We + // don't check errors in this bit.) + SIMDJSON_TRY(reset_object().get(has_value)); + while (true) { + SIMDJSON_ASSUME(has_value); // we should reach search_start before ever reaching the end of the object + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + error = field_key().get(actual_key); SIMDJSON_ASSUME(!error); + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + error = field_value(); SIMDJSON_ASSUME(!error); + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // If we reached the end of the key-value pair we started from, then we know + // that the key is not there so we return false. We are either right before + // the next comma or the final brace. + if (_json_iter->position() == search_start) { return false; } + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + error = has_next_field().get(has_value); SIMDJSON_ASSUME(!error); + // If we make the mistake of exiting here, then we could be left pointing at a key + // in the middle of an object. That's not an allowable state. + } + // If the loop ended, we're out of fields to look at. The program should + // never reach this point. + return false; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::field_key() noexcept { + assert_at_next(); + + const uint8_t* key = _json_iter->return_current_and_advance(); + if (*(key++) != '"') { return report_error(TAPE_ERROR, "Object key is not a string"); } + return raw_json_string(key); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::field_value() noexcept { + assert_at_next(); + + if (*_json_iter->return_current_and_advance() != ':') { return report_error(TAPE_ERROR, "Missing colon in object field"); } + _json_iter->descend_to(depth() + 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_root_array(); + } + + inline std::string value_iterator::to_string() const noexcept { + auto answer = std::string("value_iterator [ depth : ") + std::to_string(_depth) + std::string(", "); + if (_json_iter != nullptr) { answer += _json_iter->to_string(); } + answer += std::string(" ]"); + return answer; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_array() noexcept { + assert_at_container_start(); + if (*_json_iter->peek() == ']') { + logger::log_value(*_json_iter, "empty array"); + _json_iter->return_current_and_advance(); + SIMDJSON_TRY(end_container()); + return false; + } + _json_iter->descend_to(depth() + 1); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_array() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // array: e.g., `[1, 2] foo]`. Users concerned with garbage content should + // also call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != ']') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing ] at end"); + } + // If the last character is ] *and* the first gibberish character is also ']' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == ']') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed array. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_array() noexcept { + auto error = check_root_array(); + if (error) { return error; } + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_element() noexcept { + assert_at_next(); + + logger::log_event(*this, "has_next_element"); + switch (*_json_iter->return_current_and_advance()) { + case ']': + logger::log_end_value(*_json_iter, "array"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + _json_iter->descend_to(depth() + 1); + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between array elements"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_bool(const uint8_t* json) const noexcept { + auto not_true = atomparsing::str4ncmp(json, "true"); + auto not_false = atomparsing::str4ncmp(json, "fals") | (json[4] ^ 'e'); + bool error = (not_true && not_false) || jsoncharutils::is_not_structural_or_whitespace(json[not_true ? 5 : 4]); + if (error) { return incorrect_type_error("Not a boolean"); } + return simdjson_result(!not_true); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_null(const uint8_t* json) const noexcept { + bool is_null_string = !atomparsing::str4ncmp(json, "null") && jsoncharutils::is_structural_or_whitespace(json[4]); + // if we start with 'n', we must be a null + if (!is_null_string && json[0] == 'n') { return incorrect_type_error("Not a null but starts with n"); } + return is_null_string; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_string(bool allow_replacement) noexcept { + return get_raw_json_string().unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_string(string_type& receiver, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_string(allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_wobbly_string() noexcept { + return get_raw_json_string().unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_raw_json_string() noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64() noexcept { + auto result = numberparsing::parse_unsigned(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64_in_string() noexcept { + auto result = numberparsing::parse_unsigned_in_string(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64() noexcept { + auto result = numberparsing::parse_integer(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64_in_string() noexcept { + auto result = numberparsing::parse_integer_in_string(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double() noexcept { + auto result = numberparsing::parse_double(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double_in_string() noexcept { + auto result = numberparsing::parse_double_in_string(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_bool() noexcept { + auto result = parse_bool(peek_non_root_scalar("bool")); + if (result.error() == SUCCESS) { advance_non_root_scalar("bool"); } + return result; + } + simdjson_inline simdjson_result value_iterator::is_null() noexcept { + bool is_null_value; + SIMDJSON_TRY(parse_null(peek_non_root_scalar("null")).get(is_null_value)); + if (is_null_value) { advance_non_root_scalar("null"); } + return is_null_value; + } + simdjson_inline bool value_iterator::is_negative() noexcept { + return numberparsing::is_negative(peek_non_root_scalar("numbersign")); + } + simdjson_inline bool value_iterator::is_root_negative() noexcept { + return numberparsing::is_negative(peek_root_scalar("numbersign")); + } + simdjson_inline simdjson_result value_iterator::is_integer() noexcept { + return numberparsing::is_integer(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number_type() noexcept { + return numberparsing::get_number_type(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number() noexcept { + number num; + error_code error = numberparsing::parse_number(peek_non_root_scalar("number"), num); + if (error) { return error; } + return num; + } + + simdjson_inline simdjson_result value_iterator::is_root_integer(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("is_root_integer"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + return false; // if there are more than 20 characters, it cannot be represented as an integer. + } + auto answer = numberparsing::is_integer(tmpbuf); + // If the parsing was a success, we must still check that it is + // a single scalar. Note that we parse first because of cases like '[]' where + // getting TRAILING_CONTENT is wrong. + if (check_trailing && (answer.error() == SUCCESS) && (!_json_iter->is_single_token())) { return TRAILING_CONTENT; } + return answer; + } + + simdjson_inline simdjson_result value_iterator::get_root_number_type(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto answer = numberparsing::get_number_type(tmpbuf); + if (check_trailing && (answer.error() == SUCCESS) && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + return answer; + } + simdjson_inline simdjson_result value_iterator::get_root_number(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + number num; + error_code error = numberparsing::parse_number(tmpbuf, num); + if (error) { return error; } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("number"); + return num; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_string(bool check_trailing, bool allow_replacement) noexcept { + return get_root_raw_json_string(check_trailing).unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_root_string(check_trailing, allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_wobbly_string(bool check_trailing) noexcept { + return get_root_raw_json_string(check_trailing).unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_raw_json_string(bool check_trailing) noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_bool(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("bool"); + uint8_t tmpbuf[5 + 1 + 1]; // +1 for null termination + tmpbuf[5 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 5 + 1)) { return incorrect_type_error("Not a boolean"); } + auto result = parse_bool(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("bool"); + } + return result; + } + simdjson_inline simdjson_result value_iterator::is_root_null(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("null"); + bool result = (max_len >= 4 && !atomparsing::str4ncmp(json, "null") && + (max_len == 4 || jsoncharutils::is_structural_or_whitespace(json[4]))); + if (result) { // we have something that looks like a null. + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("null"); + } + return result; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::skip_child() noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth >= _depth); + + return _json_iter->skip_child(depth()); + } + + simdjson_inline value_iterator value_iterator::child() const noexcept { + assert_at_child(); + return { _json_iter, depth() + 1, _json_iter->token.position() }; + } + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and iterator depth, which is a desired effect. It does not happen if is_open is + // marked non-inline. + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline bool value_iterator::is_open() const noexcept { + return _json_iter->depth() >= depth(); + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool value_iterator::at_end() const noexcept { + return _json_iter->at_end(); + } + + simdjson_inline bool value_iterator::at_start() const noexcept { + return _json_iter->token.position() == start_position(); + } + + simdjson_inline bool value_iterator::at_first_field() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + return _json_iter->token.position() == start_position() + 1; + } + + simdjson_inline void value_iterator::abandon() noexcept { + _json_iter->abandon(); + } + + simdjson_warn_unused simdjson_inline depth_t value_iterator::depth() const noexcept { + return _depth; + } + simdjson_warn_unused simdjson_inline error_code value_iterator::error() const noexcept { + return _json_iter->error; + } + simdjson_warn_unused simdjson_inline uint8_t*& value_iterator::string_buf_loc() noexcept { + return _json_iter->string_buf_loc(); + } + simdjson_warn_unused simdjson_inline const json_iterator& value_iterator::json_iter() const noexcept { + return *_json_iter; + } + simdjson_warn_unused simdjson_inline json_iterator& value_iterator::json_iter() noexcept { + return *_json_iter; + } + + simdjson_inline const uint8_t* value_iterator::peek_start() const noexcept { + return _json_iter->peek(start_position()); + } + simdjson_inline uint32_t value_iterator::peek_start_length() const noexcept { + return _json_iter->peek_length(start_position()); + } + + simdjson_inline const uint8_t* value_iterator::peek_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return peek_start(); } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return; } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept { + logger::log_start_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + const uint8_t* json; + if (!is_at_start()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + json = peek_start(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + } + else { + assert_at_start(); + /** + * We should be prudent. Let us peek. If it is not the right type, we + * return an error. Only once we have determined that we have the right + * type are we allowed to advance! + */ + json = _json_iter->peek(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + _json_iter->return_current_and_advance(); + } + + + return SUCCESS; + } + + + simdjson_inline const uint8_t* value_iterator::peek_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_root(); + return _json_iter->peek(); + } + simdjson_inline const uint8_t* value_iterator::peek_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_non_root_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_root(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + simdjson_inline void value_iterator::advance_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_non_root_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::incorrect_type_error(const char* message) const noexcept { + logger::log_error(*_json_iter, start_position(), depth(), message); + return INCORRECT_TYPE; + } + + simdjson_inline bool value_iterator::is_at_start() const noexcept { + return position() == start_position(); + } + + simdjson_inline bool value_iterator::is_at_key() const noexcept { + // Keys are at the same depth as the object. + // Note here that we could be safer and check that we are within an object, + // but we do not. + return _depth == _json_iter->_depth && *_json_iter->peek() == '"'; + } + + simdjson_inline bool value_iterator::is_at_iterator_start() const noexcept { + // We can legitimately be either at the first value ([1]), or after the array if it's empty ([]). + auto delta = position() - start_position(); + return delta == 1 || delta == 2; + } + + inline void value_iterator::assert_at_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_container_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position + 1); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_next() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + simdjson_inline void value_iterator::move_at_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position); + } + + simdjson_inline void value_iterator::move_at_container_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position + 1); + } + + simdjson_inline simdjson_result value_iterator::reset_array() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_array(); + } + + simdjson_inline simdjson_result value_iterator::reset_object() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_object(); + } + + inline void value_iterator::assert_at_child() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth + 1); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_root() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth == 1); + } + + inline void value_iterator::assert_at_non_root_start() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth > 1); + } + + inline void value_iterator::assert_is_valid() const noexcept { + SIMDJSON_ASSUME(_json_iter != nullptr); + } + + simdjson_inline bool value_iterator::is_valid() const noexcept { + return _json_iter != nullptr; + } + + simdjson_inline simdjson_result value_iterator::type() const noexcept { + switch (*peek_start()) { + case '{': + return json_type::object; + case '[': + return json_type::array; + case '"': + return json_type::string; + case 'n': + return json_type::null; + case 't': case 'f': + return json_type::boolean; + case '-': + case '0': case '1': case '2': case '3': case '4': + case '5': case '6': case '7': case '8': case '9': + return json_type::number; + default: + return TAPE_ERROR; + } + } + + simdjson_inline token_position value_iterator::start_position() const noexcept { + return _start_position; + } + + simdjson_inline token_position value_iterator::position() const noexcept { + return _json_iter->position(); + } + + simdjson_inline token_position value_iterator::end_position() const noexcept { + return _json_iter->end_position(); + } + + simdjson_inline token_position value_iterator::last_position() const noexcept { + return _json_iter->last_position(); + } + + simdjson_inline error_code value_iterator::report_error(error_code error, const char* message) noexcept { + return _json_iter->report_error(error, message); + } + + } // namespace ondemand + } // namespace ppc64 +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(ppc64::ondemand::value_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/value_iterator-inl.h for ppc64 */ +/* end file simdjson/generic/ondemand/amalgamated.h for ppc64 */ +/* including simdjson/ppc64/end.h: #include "simdjson/ppc64/end.h" */ +/* begin file simdjson/ppc64/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/ppc64/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#undef SIMDJSON_SKIP_BACKSLASH_SHORT_CIRCUIT +/* undefining SIMDJSON_IMPLEMENTATION from "ppc64" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/ppc64/end.h */ + +#endif // SIMDJSON_PPC64_ONDEMAND_H +/* end file simdjson/ppc64/ondemand.h */ +#elif SIMDJSON_BUILTIN_IMPLEMENTATION_IS(westmere) +/* including simdjson/westmere/ondemand.h: #include "simdjson/westmere/ondemand.h" */ +/* begin file simdjson/westmere/ondemand.h */ +#ifndef SIMDJSON_WESTMERE_ONDEMAND_H +#define SIMDJSON_WESTMERE_ONDEMAND_H + +/* including simdjson/westmere/begin.h: #include "simdjson/westmere/begin.h" */ +/* begin file simdjson/westmere/begin.h */ +/* defining SIMDJSON_IMPLEMENTATION to "westmere" */ +#define SIMDJSON_IMPLEMENTATION westmere +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + /** + * Implementation for Westmere (Intel SSE4.2). + */ + namespace westmere { + + class implementation; + + namespace { + namespace simd { + + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ +#ifndef SIMDJSON_WESTMERE_INTRINSICS_H +#define SIMDJSON_WESTMERE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + */ +#include // for _mm_alignr_epi8 +#include // for _mm_clmulepi64_si128 +#endif + +static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); + +#endif // SIMDJSON_WESTMERE_INTRINSICS_H +/* end file simdjson/westmere/intrinsics.h */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_TARGET_REGION("sse4.2,pclmul,popcnt") +#endif + +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ +#ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H +#define SIMDJSON_WESTMERE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMANIPULATION_H +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/bitmask.h: #include "simdjson/westmere/bitmask.h" */ +/* begin file simdjson/westmere/bitmask.h */ +#ifndef SIMDJSON_WESTMERE_BITMASK_H +#define SIMDJSON_WESTMERE_BITMASK_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // + // Perform a "cumulative bitwise xor," flipping bits each time a 1 is encountered. + // + // For example, prefix_xor(00100100) == 00011100 + // + simdjson_inline uint64_t prefix_xor(const uint64_t bitmask) { + // There should be no such thing with a processing supporting avx2 + // but not clmul. + __m128i all_ones = _mm_set1_epi8('\xFF'); + __m128i result = _mm_clmulepi64_si128(_mm_set_epi64x(0ULL, bitmask), all_ones, 0); + return _mm_cvtsi128_si64(result); + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMASK_H +/* end file simdjson/westmere/bitmask.h */ +/* including simdjson/westmere/numberparsing_defs.h: #include "simdjson/westmere/numberparsing_defs.h" */ +/* begin file simdjson/westmere/numberparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +#define SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H + +/* including simdjson/westmere/base.h: #include "simdjson/westmere/base.h" */ +/* begin file simdjson/westmere/base.h */ +#ifndef SIMDJSON_WESTMERE_BASE_H +#define SIMDJSON_WESTMERE_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +// The constructor may be executed on any host, so we take care not to use SIMDJSON_TARGET_WESTMERE +namespace simdjson { + /** + * Implementation for Westmere (Intel SSE4.2). + */ + namespace westmere { + + class implementation; + + namespace { + namespace simd { + + template struct simd8; + template struct simd8x64; + + } // namespace simd + } // unnamed namespace + + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BASE_H +/* end file simdjson/westmere/base.h */ +/* including simdjson/westmere/intrinsics.h: #include "simdjson/westmere/intrinsics.h" */ +/* begin file simdjson/westmere/intrinsics.h */ +#ifndef SIMDJSON_WESTMERE_INTRINSICS_H +#define SIMDJSON_WESTMERE_INTRINSICS_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if SIMDJSON_VISUAL_STUDIO +// under clang within visual studio, this will include +#include // visual studio or clang +#else +#include // elsewhere +#endif // SIMDJSON_VISUAL_STUDIO + + +#if SIMDJSON_CLANG_VISUAL_STUDIO +/** + * You are not supposed, normally, to include these + * headers directly. Instead you should either include intrin.h + * or x86intrin.h. However, when compiling with clang + * under Windows (i.e., when _MSC_VER is set), these headers + * only get included *if* the corresponding features are detected + * from macros: + */ +#include // for _mm_alignr_epi8 +#include // for _mm_clmulepi64_si128 +#endif + +static_assert(sizeof(__m128i) <= simdjson::SIMDJSON_PADDING, "insufficient padding for westmere"); + +#endif // SIMDJSON_WESTMERE_INTRINSICS_H +/* end file simdjson/westmere/intrinsics.h */ + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/numberparsing_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace numberparsing { + + /** @private */ + static simdjson_inline uint32_t parse_eight_digits_unrolled(const uint8_t* chars) { + // this actually computes *16* values so we are being wasteful. + const __m128i ascii0 = _mm_set1_epi8('0'); + const __m128i mul_1_10 = + _mm_setr_epi8(10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1, 10, 1); + const __m128i mul_1_100 = _mm_setr_epi16(100, 1, 100, 1, 100, 1, 100, 1); + const __m128i mul_1_10000 = + _mm_setr_epi16(10000, 1, 10000, 1, 10000, 1, 10000, 1); + const __m128i input = _mm_sub_epi8( + _mm_loadu_si128(reinterpret_cast(chars)), ascii0); + const __m128i t1 = _mm_maddubs_epi16(input, mul_1_10); + const __m128i t2 = _mm_madd_epi16(t1, mul_1_100); + const __m128i t3 = _mm_packus_epi32(t2, t2); + const __m128i t4 = _mm_madd_epi16(t3, mul_1_10000); + return _mm_cvtsi128_si32( + t4); // only captures the sum of the first 8 digits, drop the rest + } + + /** @private */ + simdjson_inline internal::value128 full_multiplication(uint64_t value1, uint64_t value2) { + internal::value128 answer; +#if SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS +#ifdef _M_ARM64 + // ARM64 has native support for 64-bit multiplications, no need to emultate + answer.high = __umulh(value1, value2); + answer.low = value1 * value2; +#else + answer.low = _umul128(value1, value2, &answer.high); // _umul128 not available on ARM64 +#endif // _M_ARM64 +#else // SIMDJSON_REGULAR_VISUAL_STUDIO || SIMDJSON_IS_32BITS + __uint128_t r = (static_cast<__uint128_t>(value1)) * value2; + answer.low = uint64_t(r); + answer.high = uint64_t(r >> 64); +#endif + return answer; + } + + } // namespace numberparsing + } // namespace westmere +} // namespace simdjson + +#define SIMDJSON_SWAR_NUMBER_PARSING 1 + +#endif // SIMDJSON_WESTMERE_NUMBERPARSING_DEFS_H +/* end file simdjson/westmere/numberparsing_defs.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ +#ifndef SIMDJSON_WESTMERE_SIMD_H +#define SIMDJSON_WESTMERE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace simd { + + template + struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { return this->value; } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm_or_si128(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm_and_si128(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm_xor_si128(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm_andnot_si128(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + template> + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm_alignr_epi8(*this, prev_chunk, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm_testz_si128(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm_setzero_si128(); } + static simdjson_inline simd8 load(const T values[16]) { + return _mm_loadu_si128(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { return _mm_storeu_si128(reinterpret_cast<__m128i*>(dst), *this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m128i shufmask = _mm_set_epi64x(thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask + shufmask = + _mm_add_epi8(shufmask, _mm_set_epi32(0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m128i pruned = _mm_shuffle_epi8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = _mm_shuffle_epi8(pruned, compactmask); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), answer); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epu8(*this, other); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm_testz_si128(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm_testz_si128(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm_movemask_epi8(_mm_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "Westmere kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_SIMD_INPUT_H +/* end file simdjson/westmere/simd.h */ +/* including simdjson/westmere/stringparsing_defs.h: #include "simdjson/westmere/stringparsing_defs.h" */ +/* begin file simdjson/westmere/stringparsing_defs.h */ +#ifndef SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +#define SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H + +/* including simdjson/westmere/bitmanipulation.h: #include "simdjson/westmere/bitmanipulation.h" */ +/* begin file simdjson/westmere/bitmanipulation.h */ +#ifndef SIMDJSON_WESTMERE_BITMANIPULATION_H +#define SIMDJSON_WESTMERE_BITMANIPULATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/intrinsics.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + + // We sometimes call trailing_zero on inputs that are zero, + // but the algorithms do not end up using the returned value. + // Sadly, sanitizers are not smart enough to figure it out. + SIMDJSON_NO_SANITIZE_UNDEFINED + // This function can be used safely even if not all bytes have been + // initialized. + // See issue https://github.com/simdjson/simdjson/issues/1965 + SIMDJSON_NO_SANITIZE_MEMORY + simdjson_inline int trailing_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long ret; + // Search the mask data from least significant bit (LSB) + // to the most significant bit (MSB) for a set bit (1). + _BitScanForward64(&ret, input_num); + return (int)ret; +#else // SIMDJSON_REGULAR_VISUAL_STUDIO + return __builtin_ctzll(input_num); +#endif // SIMDJSON_REGULAR_VISUAL_STUDIO + } + + /* result might be undefined when input_num is zero */ + simdjson_inline uint64_t clear_lowest_bit(uint64_t input_num) { + return input_num & (input_num - 1); + } + + /* result might be undefined when input_num is zero */ + simdjson_inline int leading_zeroes(uint64_t input_num) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + unsigned long leading_zero = 0; + // Search the mask data from most significant bit (MSB) + // to least significant bit (LSB) for a set bit (1). + if (_BitScanReverse64(&leading_zero, input_num)) + return (int)(63 - leading_zero); + else + return 64; +#else + return __builtin_clzll(input_num); +#endif// SIMDJSON_REGULAR_VISUAL_STUDIO + } + +#if SIMDJSON_REGULAR_VISUAL_STUDIO + simdjson_inline unsigned __int64 count_ones(uint64_t input_num) { + // note: we do not support legacy 32-bit Windows in this kernel + return __popcnt64(input_num);// Visual Studio wants two underscores + } +#else + simdjson_inline long long int count_ones(uint64_t input_num) { + return _popcnt64(input_num); + } +#endif + + simdjson_inline bool add_overflow(uint64_t value1, uint64_t value2, + uint64_t* result) { +#if SIMDJSON_REGULAR_VISUAL_STUDIO + return _addcarry_u64(0, value1, value2, + reinterpret_cast(result)); +#else + return __builtin_uaddll_overflow(value1, value2, + reinterpret_cast(result)); +#endif + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_BITMANIPULATION_H +/* end file simdjson/westmere/bitmanipulation.h */ +/* including simdjson/westmere/simd.h: #include "simdjson/westmere/simd.h" */ +/* begin file simdjson/westmere/simd.h */ +#ifndef SIMDJSON_WESTMERE_SIMD_H +#define SIMDJSON_WESTMERE_SIMD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/bitmanipulation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/simdprune_tables.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace { + namespace simd { + + template + struct base { + __m128i value; + + // Zero constructor + simdjson_inline base() : value{ __m128i() } {} + + // Conversion from SIMD register + simdjson_inline base(const __m128i _value) : value(_value) {} + + // Conversion to SIMD register + simdjson_inline operator const __m128i& () const { return this->value; } + simdjson_inline operator __m128i& () { return this->value; } + + // Bit operations + simdjson_inline Child operator|(const Child other) const { return _mm_or_si128(*this, other); } + simdjson_inline Child operator&(const Child other) const { return _mm_and_si128(*this, other); } + simdjson_inline Child operator^(const Child other) const { return _mm_xor_si128(*this, other); } + simdjson_inline Child bit_andnot(const Child other) const { return _mm_andnot_si128(other, *this); } + simdjson_inline Child& operator|=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast | other; return *this_cast; } + simdjson_inline Child& operator&=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast & other; return *this_cast; } + simdjson_inline Child& operator^=(const Child other) { auto this_cast = static_cast(this); *this_cast = *this_cast ^ other; return *this_cast; } + }; + + template> + struct base8 : base> { + typedef uint16_t bitmask_t; + typedef uint32_t bitmask2_t; + + simdjson_inline base8() : base>() {} + simdjson_inline base8(const __m128i _value) : base>(_value) {} + + friend simdjson_inline Mask operator==(const simd8 lhs, const simd8 rhs) { return _mm_cmpeq_epi8(lhs, rhs); } + + static const int SIZE = sizeof(base>::value); + + template + simdjson_inline simd8 prev(const simd8 prev_chunk) const { + return _mm_alignr_epi8(*this, prev_chunk, 16 - N); + } + }; + + // SIMD byte mask type (returned by things like eq and gt) + template<> + struct simd8 : base8 { + static simdjson_inline simd8 splat(bool _value) { return _mm_set1_epi8(uint8_t(-(!!_value))); } + + simdjson_inline simd8() : base8() {} + simdjson_inline simd8(const __m128i _value) : base8(_value) {} + // Splat constructor + simdjson_inline simd8(bool _value) : base8(splat(_value)) {} + + simdjson_inline int to_bitmask() const { return _mm_movemask_epi8(*this); } + simdjson_inline bool any() const { return !_mm_testz_si128(*this, *this); } + simdjson_inline simd8 operator~() const { return *this ^ true; } + }; + + template + struct base8_numeric : base8 { + static simdjson_inline simd8 splat(T _value) { return _mm_set1_epi8(_value); } + static simdjson_inline simd8 zero() { return _mm_setzero_si128(); } + static simdjson_inline simd8 load(const T values[16]) { + return _mm_loadu_si128(reinterpret_cast(values)); + } + // Repeat 16 values as many times as necessary (usually for lookup tables) + static simdjson_inline simd8 repeat_16( + T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7, + T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + simdjson_inline base8_numeric() : base8() {} + simdjson_inline base8_numeric(const __m128i _value) : base8(_value) {} + + // Store to array + simdjson_inline void store(T dst[16]) const { return _mm_storeu_si128(reinterpret_cast<__m128i*>(dst), *this); } + + // Override to distinguish from bool version + simdjson_inline simd8 operator~() const { return *this ^ 0xFFu; } + + // Addition/subtraction are the same for signed and unsigned + simdjson_inline simd8 operator+(const simd8 other) const { return _mm_add_epi8(*this, other); } + simdjson_inline simd8 operator-(const simd8 other) const { return _mm_sub_epi8(*this, other); } + simdjson_inline simd8& operator+=(const simd8 other) { *this = *this + other; return *static_cast*>(this); } + simdjson_inline simd8& operator-=(const simd8 other) { *this = *this - other; return *static_cast*>(this); } + + // Perform a lookup assuming the value is between 0 and 16 (undefined behavior for out of range values) + template + simdjson_inline simd8 lookup_16(simd8 lookup_table) const { + return _mm_shuffle_epi8(lookup_table, *this); + } + + // Copies to 'output" all bytes corresponding to a 0 in the mask (interpreted as a bitset). + // Passing a 0 value for mask would be equivalent to writing out every byte to output. + // Only the first 16 - count_ones(mask) bytes of the result are significant but 16 bytes + // get written. + // Design consideration: it seems like a function with the + // signature simd8 compress(uint32_t mask) would be + // sensible, but the AVX ISA makes this kind of approach difficult. + template + simdjson_inline void compress(uint16_t mask, L* output) const { + using internal::thintable_epi8; + using internal::BitsSetTable256mul2; + using internal::pshufb_combine_table; + // this particular implementation was inspired by work done by @animetosho + // we do it in two steps, first 8 bytes and then second 8 bytes + uint8_t mask1 = uint8_t(mask); // least significant 8 bits + uint8_t mask2 = uint8_t(mask >> 8); // most significant 8 bits + // next line just loads the 64-bit values thintable_epi8[mask1] and + // thintable_epi8[mask2] into a 128-bit register, using only + // two instructions on most compilers. + __m128i shufmask = _mm_set_epi64x(thintable_epi8[mask2], thintable_epi8[mask1]); + // we increment by 0x08 the second half of the mask + shufmask = + _mm_add_epi8(shufmask, _mm_set_epi32(0x08080808, 0x08080808, 0, 0)); + // this is the version "nearly pruned" + __m128i pruned = _mm_shuffle_epi8(*this, shufmask); + // we still need to put the two halves together. + // we compute the popcount of the first half: + int pop1 = BitsSetTable256mul2[mask1]; + // then load the corresponding mask, what it does is to write + // only the first pop1 bytes from the first 8 bytes, and then + // it fills in with the bytes from the second 8 bytes + some filling + // at the end. + __m128i compactmask = + _mm_loadu_si128(reinterpret_cast(pshufb_combine_table + pop1 * 8)); + __m128i answer = _mm_shuffle_epi8(pruned, compactmask); + _mm_storeu_si128(reinterpret_cast<__m128i*>(output), answer); + } + + template + simdjson_inline simd8 lookup_16( + L replace0, L replace1, L replace2, L replace3, + L replace4, L replace5, L replace6, L replace7, + L replace8, L replace9, L replace10, L replace11, + L replace12, L replace13, L replace14, L replace15) const { + return lookup_16(simd8::repeat_16( + replace0, replace1, replace2, replace3, + replace4, replace5, replace6, replace7, + replace8, replace9, replace10, replace11, + replace12, replace13, replace14, replace15 + )); + } + }; + + // Signed bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(int8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const int8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + int8_t v0, int8_t v1, int8_t v2, int8_t v3, int8_t v4, int8_t v5, int8_t v6, int8_t v7, + int8_t v8, int8_t v9, int8_t v10, int8_t v11, int8_t v12, int8_t v13, int8_t v14, int8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Order-sensitive comparisons + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epi8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epi8(*this, other); } + simdjson_inline simd8 operator>(const simd8 other) const { return _mm_cmpgt_epi8(*this, other); } + simdjson_inline simd8 operator<(const simd8 other) const { return _mm_cmpgt_epi8(other, *this); } + }; + + // Unsigned bytes + template<> + struct simd8 : base8_numeric { + simdjson_inline simd8() : base8_numeric() {} + simdjson_inline simd8(const __m128i _value) : base8_numeric(_value) {} + // Splat constructor + simdjson_inline simd8(uint8_t _value) : simd8(splat(_value)) {} + // Array constructor + simdjson_inline simd8(const uint8_t* values) : simd8(load(values)) {} + // Member-by-member initialization + simdjson_inline simd8( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) : simd8(_mm_setr_epi8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + )) {} + // Repeat 16 values as many times as necessary (usually for lookup tables) + simdjson_inline static simd8 repeat_16( + uint8_t v0, uint8_t v1, uint8_t v2, uint8_t v3, uint8_t v4, uint8_t v5, uint8_t v6, uint8_t v7, + uint8_t v8, uint8_t v9, uint8_t v10, uint8_t v11, uint8_t v12, uint8_t v13, uint8_t v14, uint8_t v15 + ) { + return simd8( + v0, v1, v2, v3, v4, v5, v6, v7, + v8, v9, v10, v11, v12, v13, v14, v15 + ); + } + + // Saturated math + simdjson_inline simd8 saturating_add(const simd8 other) const { return _mm_adds_epu8(*this, other); } + simdjson_inline simd8 saturating_sub(const simd8 other) const { return _mm_subs_epu8(*this, other); } + + // Order-specific operations + simdjson_inline simd8 max_val(const simd8 other) const { return _mm_max_epu8(*this, other); } + simdjson_inline simd8 min_val(const simd8 other) const { return _mm_min_epu8(*this, other); } + // Same as >, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 gt_bits(const simd8 other) const { return this->saturating_sub(other); } + // Same as <, but only guarantees true is nonzero (< guarantees true = -1) + simdjson_inline simd8 lt_bits(const simd8 other) const { return other.saturating_sub(*this); } + simdjson_inline simd8 operator<=(const simd8 other) const { return other.max_val(*this) == other; } + simdjson_inline simd8 operator>=(const simd8 other) const { return other.min_val(*this) == other; } + simdjson_inline simd8 operator>(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + simdjson_inline simd8 operator<(const simd8 other) const { return this->gt_bits(other).any_bits_set(); } + + // Bit-specific operations + simdjson_inline simd8 bits_not_set() const { return *this == uint8_t(0); } + simdjson_inline simd8 bits_not_set(simd8 bits) const { return (*this & bits).bits_not_set(); } + simdjson_inline simd8 any_bits_set() const { return ~this->bits_not_set(); } + simdjson_inline simd8 any_bits_set(simd8 bits) const { return ~this->bits_not_set(bits); } + simdjson_inline bool is_ascii() const { return _mm_movemask_epi8(*this) == 0; } + simdjson_inline bool bits_not_set_anywhere() const { return _mm_testz_si128(*this, *this); } + simdjson_inline bool any_bits_set_anywhere() const { return !bits_not_set_anywhere(); } + simdjson_inline bool bits_not_set_anywhere(simd8 bits) const { return _mm_testz_si128(*this, bits); } + simdjson_inline bool any_bits_set_anywhere(simd8 bits) const { return !bits_not_set_anywhere(bits); } + template + simdjson_inline simd8 shr() const { return simd8(_mm_srli_epi16(*this, N)) & uint8_t(0xFFu >> N); } + template + simdjson_inline simd8 shl() const { return simd8(_mm_slli_epi16(*this, N)) & uint8_t(0xFFu << N); } + // Get one of the bits and make a bitmask out of it. + // e.g. value.get_bit<7>() gets the high bit + template + simdjson_inline int get_bit() const { return _mm_movemask_epi8(_mm_slli_epi16(*this, 7 - N)); } + }; + + template + struct simd8x64 { + static constexpr int NUM_CHUNKS = 64 / sizeof(simd8); + static_assert(NUM_CHUNKS == 4, "Westmere kernel should use four registers per 64-byte block."); + const simd8 chunks[NUM_CHUNKS]; + + simd8x64(const simd8x64& o) = delete; // no copy allowed + simd8x64& operator=(const simd8& other) = delete; // no assignment allowed + simd8x64() = delete; // no default constructor allowed + + simdjson_inline simd8x64(const simd8 chunk0, const simd8 chunk1, const simd8 chunk2, const simd8 chunk3) : chunks{ chunk0, chunk1, chunk2, chunk3 } {} + simdjson_inline simd8x64(const T ptr[64]) : chunks{ simd8::load(ptr), simd8::load(ptr + 16), simd8::load(ptr + 32), simd8::load(ptr + 48) } {} + + simdjson_inline void store(T ptr[64]) const { + this->chunks[0].store(ptr + sizeof(simd8) * 0); + this->chunks[1].store(ptr + sizeof(simd8) * 1); + this->chunks[2].store(ptr + sizeof(simd8) * 2); + this->chunks[3].store(ptr + sizeof(simd8) * 3); + } + + simdjson_inline simd8 reduce_or() const { + return (this->chunks[0] | this->chunks[1]) | (this->chunks[2] | this->chunks[3]); + } + + simdjson_inline uint64_t compress(uint64_t mask, T* output) const { + this->chunks[0].compress(uint16_t(mask), output); + this->chunks[1].compress(uint16_t(mask >> 16), output + 16 - count_ones(mask & 0xFFFF)); + this->chunks[2].compress(uint16_t(mask >> 32), output + 32 - count_ones(mask & 0xFFFFFFFF)); + this->chunks[3].compress(uint16_t(mask >> 48), output + 48 - count_ones(mask & 0xFFFFFFFFFFFF)); + return 64 - count_ones(mask); + } + + simdjson_inline uint64_t to_bitmask() const { + uint64_t r0 = uint32_t(this->chunks[0].to_bitmask()); + uint64_t r1 = this->chunks[1].to_bitmask(); + uint64_t r2 = this->chunks[2].to_bitmask(); + uint64_t r3 = this->chunks[3].to_bitmask(); + return r0 | (r1 << 16) | (r2 << 32) | (r3 << 48); + } + + simdjson_inline uint64_t eq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] == mask, + this->chunks[1] == mask, + this->chunks[2] == mask, + this->chunks[3] == mask + ).to_bitmask(); + } + + simdjson_inline uint64_t eq(const simd8x64& other) const { + return simd8x64( + this->chunks[0] == other.chunks[0], + this->chunks[1] == other.chunks[1], + this->chunks[2] == other.chunks[2], + this->chunks[3] == other.chunks[3] + ).to_bitmask(); + } + + simdjson_inline uint64_t lteq(const T m) const { + const simd8 mask = simd8::splat(m); + return simd8x64( + this->chunks[0] <= mask, + this->chunks[1] <= mask, + this->chunks[2] <= mask, + this->chunks[3] <= mask + ).to_bitmask(); + } + }; // struct simd8x64 + + } // namespace simd + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_SIMD_INPUT_H +/* end file simdjson/westmere/simd.h */ + +namespace simdjson { + namespace westmere { + namespace { + + using namespace simd; + + // Holds backslashes and quotes locations. + struct backslash_and_quote { + public: + static constexpr uint32_t BYTES_PROCESSED = 32; + simdjson_inline static backslash_and_quote copy_and_find(const uint8_t* src, uint8_t* dst); + + simdjson_inline bool has_quote_first() { return ((bs_bits - 1) & quote_bits) != 0; } + simdjson_inline bool has_backslash() { return bs_bits != 0; } + simdjson_inline int quote_index() { return trailing_zeroes(quote_bits); } + simdjson_inline int backslash_index() { return trailing_zeroes(bs_bits); } + + uint32_t bs_bits; + uint32_t quote_bits; + }; // struct backslash_and_quote + + simdjson_inline backslash_and_quote backslash_and_quote::copy_and_find(const uint8_t* src, uint8_t* dst) { + // this can read up to 31 bytes beyond the buffer size, but we require + // SIMDJSON_PADDING of padding + static_assert(SIMDJSON_PADDING >= (BYTES_PROCESSED - 1), "backslash and quote finder must process fewer than SIMDJSON_PADDING bytes"); + simd8 v0(src); + simd8 v1(src + 16); + v0.store(dst); + v1.store(dst + 16); + uint64_t bs_and_quote = simd8x64(v0 == '\\', v1 == '\\', v0 == '"', v1 == '"').to_bitmask(); + return { + uint32_t(bs_and_quote), // bs_bits + uint32_t(bs_and_quote >> 32) // quote_bits + }; + } + + } // unnamed namespace + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_WESTMERE_STRINGPARSING_DEFS_H +/* end file simdjson/westmere/stringparsing_defs.h */ +/* end file simdjson/westmere/begin.h */ +/* including simdjson/generic/ondemand/amalgamated.h for westmere: #include "simdjson/generic/ondemand/amalgamated.h" */ +/* begin file simdjson/generic/ondemand/amalgamated.h for westmere */ +#if defined(SIMDJSON_CONDITIONAL_INCLUDE) && !defined(SIMDJSON_GENERIC_ONDEMAND_DEPENDENCIES_H) +#error simdjson/generic/ondemand/dependencies.h must be included before simdjson/generic/ondemand/amalgamated.h! +#endif + +// Stuff other things depend on +/* including simdjson/generic/ondemand/base.h for westmere: #include "simdjson/generic/ondemand/base.h" */ +/* begin file simdjson/generic/ondemand/base.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_BASE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_BASE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + /** + * A fast, simple, DOM-like interface that parses JSON as you use it. + * + * Designed for maximum speed and a lower memory profile. + */ + namespace ondemand { + + /** Represents the depth of a JSON value (number of nested arrays/objects). */ + using depth_t = int32_t; + + /** @copydoc simdjson::westmere::number_type */ + using number_type = simdjson::westmere::number_type; + + /** @private Position in the JSON buffer indexes */ + using token_position = const uint32_t*; + + class array; + class array_iterator; + class document; + class document_reference; + class document_stream; + class field; + class json_iterator; + enum class json_type; + struct number; + class object; + class object_iterator; + class parser; + class raw_json_string; + class token_iterator; + class value; + class value_iterator; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_BASE_H +/* end file simdjson/generic/ondemand/base.h for westmere */ +/* including simdjson/generic/ondemand/value_iterator.h for westmere: #include "simdjson/generic/ondemand/value_iterator.h" */ +/* begin file simdjson/generic/ondemand/value_iterator.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * Iterates through a single JSON value at a particular depth. + * + * Does not keep track of the type of value: provides methods for objects, arrays and scalars and expects + * the caller to call the right ones. + * + * @private This is not intended for external use. + */ + class value_iterator { + protected: + /** The underlying JSON iterator */ + json_iterator* _json_iter{}; + /** The depth of this value */ + depth_t _depth{}; + /** + * The starting token index for this value + */ + token_position _start_position{}; + + public: + simdjson_inline value_iterator() noexcept = default; + + /** + * Denote that we're starting a document. + */ + simdjson_inline void start_document() noexcept; + + /** + * Skips a non-iterated or partially-iterated JSON value, whether it is a scalar, array or object. + * + * Optimized for scalars. + */ + simdjson_warn_unused simdjson_inline error_code skip_child() noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is at the start of the value + */ + simdjson_inline bool at_start() const noexcept; + + /** + * Tell whether the value is open--if the value has not been used, or the array/object is still open. + */ + simdjson_inline bool is_open() const noexcept; + + /** + * Tell whether the value is at an object's first field (just after the {). + */ + simdjson_inline bool at_first_field() const noexcept; + + /** + * Abandon all iteration. + */ + simdjson_inline void abandon() noexcept; + + /** + * Get the child value as a value_iterator. + */ + simdjson_inline value_iterator child_value() const noexcept; + + /** + * Get the depth of this value. + */ + simdjson_inline int32_t depth() const noexcept; + + /** + * Get the JSON type of this value. + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() const noexcept; + + /** + * @addtogroup object Object iteration + * + * Methods to iterate and find object fields. These methods generally *assume* the value is + * actually an object; the caller is responsible for keeping track of that fact. + * + * @{ + */ + + /** + * Start an object iteration. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + */ + simdjson_warn_unused simdjson_inline simdjson_result start_object() noexcept; + /** + * Start an object iteration from the root. + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_object() noexcept; + /** + * Checks whether an object could be started from the root. May be called by start_root_object. + * + * @returns SUCCESS if it is possible to safely start an object from the root (document level). + * @error INCORRECT_TYPE if there is no opening { + * @error TAPE_ERROR if there is no matching } at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_object() noexcept; + /** + * Start an object iteration after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_object() noexcept; + /** + * Start an object iteration from the root, after the user has already checked and moved past the {. + * + * Does not move the iterator unless the object is empty ({}). + * + * @returns Whether the object had any fields (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_object() noexcept; + + /** + * Moves to the next field in an object. + * + * Looks for , and }. If } is found, the object is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return whether there is another field in the object. + * @error TAPE_ERROR If there is a comma missing between fields. + * @error TAPE_ERROR If there is a comma, but not enough tokens remaining to have a key, :, and value. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_field() noexcept; + + /** + * Get the current field's key. + */ + simdjson_warn_unused simdjson_inline simdjson_result field_key() noexcept; + + /** + * Pass the : in the field and move to its value. + */ + simdjson_warn_unused simdjson_inline error_code field_value() noexcept; + + /** + * Find the next field with the given key. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline error_code find_field(const std::string_view key) noexcept; + + /** + * Find the next field with the given key, *without* unescaping. This assumes object order: it + * will not find the field if it was already passed when looking for some *other* field. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_raw(const std::string_view key) noexcept; + + /** + * Find the field with the given key without regard to order, and *without* unescaping. + * + * This is an unordered object lookup: if the field is not found initially, it will cycle around and scan from the beginning. + * + * Assumes you have called next_field() or otherwise matched the previous value. + * + * This means the iterator must be sitting at the next key: + * + * ``` + * { "a": 1, "b": 2 } + * ^ + * ``` + * + * Key is *raw JSON,* meaning it will be matched against the verbatim JSON without attempting to + * unescape it. This works well for typical ASCII and UTF-8 keys (almost all of them), but may + * fail to match some keys with escapes (\u, \n, etc.). + */ + simdjson_warn_unused simdjson_inline simdjson_result find_field_unordered_raw(const std::string_view key) noexcept; + + /** @} */ + + /** + * @addtogroup array Array iteration + * Methods to iterate over array elements. These methods generally *assume* the value is actually + * an object; the caller is responsible for keeping track of that fact. + * @{ + */ + + /** + * Check for an opening [ and start an array iteration. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + */ + simdjson_warn_unused simdjson_inline simdjson_result start_array() noexcept; + /** + * Check for an opening [ and start an array iteration while at the root. + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline simdjson_result start_root_array() noexcept; + /** + * Checks whether an array could be started from the root. May be called by start_root_array. + * + * @returns SUCCESS if it is possible to safely start an array from the root (document level). + * @error INCORRECT_TYPE If there is no [. + * @error TAPE_ERROR if there is no matching ] at end of document + */ + simdjson_warn_unused simdjson_inline error_code check_root_array() noexcept; + /** + * Start an array iteration, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_array() noexcept; + /** + * Start an array iteration from the root, after the user has already checked and moved past the [. + * + * Does not move the iterator unless the array is empty ([]). + * + * @returns Whether the array had any elements (returns false for empty). + * @error INCOMPLETE_ARRAY_OR_OBJECT If there are no more tokens (implying the *parent* + * array or object is incomplete). + */ + simdjson_warn_unused simdjson_inline simdjson_result started_root_array() noexcept; + + /** + * Moves to the next element in an array. + * + * Looks for , and ]. If ] is found, the array is finished and the iterator advances past it. + * Otherwise, it advances to the next value. + * + * @return Whether there is another element in the array. + * @error TAPE_ERROR If there is a comma missing between elements. + */ + simdjson_warn_unused simdjson_inline simdjson_result has_next_element() noexcept; + + /** + * Get a child value iterator. + */ + simdjson_warn_unused simdjson_inline value_iterator child() const noexcept; + + /** @} */ + + /** + * @defgroup scalar Scalar values + * @addtogroup scalar + * @{ + */ + + simdjson_warn_unused simdjson_inline simdjson_result get_string(bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_bool() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_null() noexcept; + simdjson_warn_unused simdjson_inline bool is_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_integer() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + simdjson_warn_unused simdjson_inline simdjson_result get_root_string(bool check_trailing, bool allow_replacement) noexcept; + template + simdjson_warn_unused simdjson_inline error_code get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_wobbly_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_raw_json_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_uint64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_int64_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_double_in_string(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_bool(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline bool is_root_negative() noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_integer(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number_type(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result get_root_number(bool check_trailing) noexcept; + simdjson_warn_unused simdjson_inline simdjson_result is_root_null(bool check_trailing) noexcept; + + simdjson_inline error_code error() const noexcept; + simdjson_inline uint8_t*& string_buf_loc() noexcept; + simdjson_inline const json_iterator& json_iter() const noexcept; + simdjson_inline json_iterator& json_iter() noexcept; + + simdjson_inline void assert_is_valid() const noexcept; + simdjson_inline bool is_valid() const noexcept; + + /** @} */ + protected: + /** + * Restarts an array iteration. + * @returns Whether the array has any elements (returns false for empty). + */ + simdjson_inline simdjson_result reset_array() noexcept; + /** + * Restarts an object iteration. + * @returns Whether the object has any fields (returns false for empty). + */ + simdjson_inline simdjson_result reset_object() noexcept; + /** + * move_at_start(): moves us so that we are pointing at the beginning of + * the container. It updates the index so that at_start() is true and it + * syncs the depth. The user can then create a new container instance. + * + * Usage: used with value::count_elements(). + **/ + simdjson_inline void move_at_start() noexcept; + + /** + * move_at_container_start(): moves us so that we are pointing at the beginning of + * the container so that assert_at_container_start() passes. + * + * Usage: used with reset_array() and reset_object(). + **/ + simdjson_inline void move_at_container_start() noexcept; + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + simdjson_inline value_iterator(json_iterator* json_iter, depth_t depth, token_position start_index) noexcept; + + simdjson_inline simdjson_result parse_null(const uint8_t* json) const noexcept; + simdjson_inline simdjson_result parse_bool(const uint8_t* json) const noexcept; + simdjson_inline const uint8_t* peek_start() const noexcept; + simdjson_inline uint32_t peek_start_length() const noexcept; + + /** + * The general idea of the advance_... methods and the peek_* methods + * is that you first peek and check that you have desired type. If you do, + * and only if you do, then you advance. + * + * We used to unconditionally advance. But this made reasoning about our + * current state difficult. + * Suppose you always advance. Look at the 'value' matching the key + * "shadowable" in the following example... + * + * ({"globals":{"a":{"shadowable":[}}}}) + * + * If the user thinks it is a Boolean and asks for it, then we check the '[', + * decide it is not a Boolean, but still move into the next character ('}'). Now + * we are left pointing at '}' right after a '['. And we have not yet reported + * an error, only that we do not have a Boolean. + * + * If, instead, you just stand your ground until it is content that you know, then + * you will only even move beyond the '[' if the user tells you that you have an + * array. So you will be at the '}' character inside the array and, hopefully, you + * will then catch the error because an array cannot start with '}', but the code + * processing Boolean values does not know this. + * + * So the contract is: first call 'peek_...' and then call 'advance_...' only + * if you have determined that it is a type you can handle. + * + * Unfortunately, it makes the code more verbose, longer and maybe more error prone. + */ + + simdjson_inline void advance_scalar(const char* type) noexcept; + simdjson_inline void advance_root_scalar(const char* type) noexcept; + simdjson_inline void advance_non_root_scalar(const char* type) noexcept; + + simdjson_inline const uint8_t* peek_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_root_scalar(const char* type) noexcept; + simdjson_inline const uint8_t* peek_non_root_scalar(const char* type) noexcept; + + + simdjson_inline error_code start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept; + simdjson_inline error_code end_container() noexcept; + + /** + * Advance to a place expecting a value (increasing depth). + * + * @return The current token (the one left behind). + * @error TAPE_ERROR If the document ended early. + */ + simdjson_inline simdjson_result advance_to_value() noexcept; + + simdjson_inline error_code incorrect_type_error(const char* message) const noexcept; + simdjson_inline error_code error_unless_more_tokens(uint32_t tokens = 1) const noexcept; + + simdjson_inline bool is_at_start() const noexcept; + /** + * is_at_iterator_start() returns true on an array or object after it has just been + * created, whether the instance is empty or not. + * + * Usage: used by array::begin() in debug mode (SIMDJSON_DEVELOPMENT_CHECKS) + */ + simdjson_inline bool is_at_iterator_start() const noexcept; + + /** + * Assuming that we are within an object, this returns true if we + * are pointing at a key. + * + * Usage: the skip_child() method should never be used while we are pointing + * at a key inside an object. + */ + simdjson_inline bool is_at_key() const noexcept; + + inline void assert_at_start() const noexcept; + inline void assert_at_container_start() const noexcept; + inline void assert_at_root() const noexcept; + inline void assert_at_child() const noexcept; + inline void assert_at_next() const noexcept; + inline void assert_at_non_root_start() const noexcept; + + /** Get the starting position of this value */ + simdjson_inline token_position start_position() const noexcept; + + /** @copydoc error_code json_iterator::position() const noexcept; */ + simdjson_inline token_position position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position last_position() const noexcept; + /** @copydoc error_code json_iterator::end_position() const noexcept; */ + simdjson_inline token_position end_position() const noexcept; + /** @copydoc error_code json_iterator::report_error(error_code error, const char *message) noexcept; */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + friend class document; + friend class object; + friend class array; + friend class value; + }; // value_iterator + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::value_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_H +/* end file simdjson/generic/ondemand/value_iterator.h for westmere */ +/* including simdjson/generic/ondemand/value.h for westmere: #include "simdjson/generic/ondemand/value.h" */ +/* begin file simdjson/generic/ondemand/value.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * An ephemeral JSON value returned during iteration. It is only valid for as long as you do + * not access more data in the JSON document. + */ + class value { + public: + /** + * Create a new invalid value. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline value() noexcept = default; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) noexcept; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() noexcept; + + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() noexcept; + + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + + /** + * Cast this JSON value (inside string) to a unsigned integer. + * + * @returns A unsigned 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + + /** + * Cast this JSON value to a "wobbly" string. + * + * The string is may not be a valid UTF-8 string. + * See https://simonsapin.github.io/wtf-8/ + * + * Important: a value should be consumed once. Calling get_wobbly_string() twice on the same value + * is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Equivalent to get(). + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); +#endif + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + * + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * Performance hint: You should only call count_elements() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method on the object instance. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @return The type of JSON value (json_type::array, json_type::object, json_type::string, + * json_type::number, json_type::boolean, or json_type::null). + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the value is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the value is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the value is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * Performance note: if you call this function systematically + * before parsing a number, you may have fallen for a performance + * anti-pattern. + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + * + * Performance note: this is designed with performance in mind. When + * calling 'get_number()', you scan the number string only once, determining + * efficiently the type and storing it in an efficient manner. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. However, if this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view is guaranteed to be + * a non-space token. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + * + * See also value::raw_json(). + */ + simdjson_inline std::string_view raw_json_token() noexcept; + + /** + * Get a string_view pointing at this value in the JSON document. + * If this element is an array or an object, it consumes the array or the object + * and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + * If this element is a scalar (string, number, Boolean, null), it returns what + * raw_json_token() would return. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + simdjson_inline simdjson_result current_location() noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. + * + * Calling at_pointer() on non-document instances (e.g., arrays and objects) is not + * standardized (by RFC 6901). We provide some experimental support for JSON pointers + * on non-document instances. Yet it is not the case when calling at_pointer on an array + * or an object instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + protected: + /** + * Create a value. + */ + simdjson_inline value(const value_iterator& iter) noexcept; + + /** + * Skip this value, allowing iteration to continue. + */ + simdjson_inline void skip() noexcept; + + /** + * Start a value at the current position. + * + * (It should already be started; this is just a self-documentation method.) + */ + static simdjson_inline value start(const value_iterator& iter) noexcept; + + /** + * Resume a value. + */ + static simdjson_inline value resume(const value_iterator& iter) noexcept; + + /** + * Get the object, starting or resuming it as necessary + */ + simdjson_inline simdjson_result start_or_resume_object() noexcept; + + // simdjson_inline void log_value(const char *type) const noexcept; + // simdjson_inline void log_error(const char *message) const noexcept; + + value_iterator iter{}; + + friend class document; + friend class array_iterator; + friend class field; + friend class object; + friend struct simdjson_result; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::value&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result get_array() noexcept; + simdjson_inline simdjson_result get_object() noexcept; + + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() noexcept; + + template simdjson_inline error_code get(T& out) noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator westmere::ondemand::array() noexcept(false); + simdjson_inline operator westmere::ondemand::object() noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator westmere::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) noexcept; + + /** + * Get the type of this JSON value. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + */ + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + + /** @copydoc simdjson_inline std::string_view value::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + /** @copydoc simdjson_inline simdjson_result current_location() noexcept */ + simdjson_inline simdjson_result current_location() noexcept; + /** @copydoc simdjson_inline int32_t current_depth() const noexcept */ + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_H +/* end file simdjson/generic/ondemand/value.h for westmere */ +/* including simdjson/generic/ondemand/logger.h for westmere: #include "simdjson/generic/ondemand/logger.h" */ +/* begin file simdjson/generic/ondemand/logger.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + // Logging should be free unless SIMDJSON_VERBOSE_LOGGING is set. Importantly, it is critical + // that the call to the log functions be side-effect free. Thus, for example, you should not + // create temporary std::string instances. + namespace logger { + + enum class log_level : int32_t { + info = 0, + error = 1 + }; + +#if SIMDJSON_VERBOSE_LOGGING + static constexpr const bool LOG_ENABLED = true; +#else + static constexpr const bool LOG_ENABLED = false; +#endif + + // We do not want these functions to be 'really inlined' since real inlining is + // for performance purposes and if you are using the loggers, you do not care about + // performance (or should not). + static inline void log_headers() noexcept; + // If args are provided, title will be treated as format string + template + static inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + template + static inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + static inline void log_event(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_value(const json_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail = "") noexcept; + static inline void log_start_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const json_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail = "") noexcept; + static inline void log_error(const json_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + static inline void log_event(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = 0, int depth_delta = 0) noexcept; + static inline void log_value(const value_iterator& iter, const char* type, std::string_view detail = "", int delta = -1, int depth_delta = 0) noexcept; + static inline void log_start_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_end_value(const value_iterator& iter, const char* type, int delta = -1, int depth_delta = 0) noexcept; + static inline void log_error(const value_iterator& iter, const char* error, const char* detail = "", int delta = -1, int depth_delta = 0) noexcept; + + } // namespace logger + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_H +/* end file simdjson/generic/ondemand/logger.h for westmere */ +/* including simdjson/generic/ondemand/token_iterator.h for westmere: #include "simdjson/generic/ondemand/token_iterator.h" */ +/* begin file simdjson/generic/ondemand/token_iterator.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * Iterates through JSON tokens (`{` `}` `[` `]` `,` `:` `""` `123` `true` `false` `null`) + * detected by stage 1. + * + * @private This is not intended for external use. + */ + class token_iterator { + public: + /** + * Create a new invalid token_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline token_iterator() noexcept = default; + simdjson_inline token_iterator(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator& operator=(token_iterator&& other) noexcept = default; + simdjson_inline token_iterator(const token_iterator& other) noexcept = default; + simdjson_inline token_iterator& operator=(const token_iterator& other) noexcept = default; + + /** + * Advance to the next token (returning the current one). + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + /** + * Reports the current offset in bytes from the start of the underlying buffer. + */ + simdjson_inline uint32_t current_offset() const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for a given token. + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + + /** + * Return the current index. + */ + simdjson_inline token_position position() const noexcept; + /** + * Reset to a previously saved index. + */ + simdjson_inline void set_position(token_position target_position) noexcept; + + // NOTE: we don't support a full C++ iterator interface, because we expect people to make + // different calls to advance the iterator based on *their own* state. + + simdjson_inline bool operator==(const token_iterator& other) const noexcept; + simdjson_inline bool operator!=(const token_iterator& other) const noexcept; + simdjson_inline bool operator>(const token_iterator& other) const noexcept; + simdjson_inline bool operator>=(const token_iterator& other) const noexcept; + simdjson_inline bool operator<(const token_iterator& other) const noexcept; + simdjson_inline bool operator<=(const token_iterator& other) const noexcept; + + protected: + simdjson_inline token_iterator(const uint8_t* buf, token_position position) noexcept; + + /** + * Get the index of the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = current token, + * 1 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_index(int32_t delta = 0) const noexcept; + /** + * Get the index of the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token. + * + */ + simdjson_inline uint32_t peek_index(token_position position) const noexcept; + + const uint8_t* buf{}; + token_position _position{}; + + friend class json_iterator; + friend class value_iterator; + friend class object; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::token_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_H +/* end file simdjson/generic/ondemand/token_iterator.h for westmere */ +/* including simdjson/generic/ondemand/json_iterator.h for westmere: #include "simdjson/generic/ondemand/json_iterator.h" */ +/* begin file simdjson/generic/ondemand/json_iterator.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * Iterates through JSON tokens, keeping track of depth and string buffer. + * + * @private This is not intended for external use. + */ + class json_iterator { + protected: + token_iterator token{}; + ondemand::parser* parser{}; + /** + * Next free location in the string buffer. + * + * Used by raw_json_string::unescape() to have a place to unescape strings to. + */ + uint8_t* _string_buf_loc{}; + /** + * JSON error, if there is one. + * + * INCORRECT_TYPE and NO_SUCH_FIELD are *not* stored here, ever. + * + * PERF NOTE: we *hope* this will be elided into control flow, as it is only used (a) in the first + * iteration of the loop, or (b) for the final iteration after a missing comma is found in ++. If + * this is not elided, we should make sure it's at least not using up a register. Failing that, + * we should store it in document so there's only one of them. + */ + error_code error{ SUCCESS }; + /** + * Depth of the current token in the JSON. + * + * - 0 = finished with document + * - 1 = document root value (could be [ or {, not yet known) + * - 2 = , or } inside root array/object + * - 3 = key or value inside root array/object. + */ + depth_t _depth{}; + /** + * Beginning of the document indexes. + * Normally we have root == parser->implementation->structural_indexes.get() + * but this may differ, especially in streaming mode (where we have several + * documents); + */ + token_position _root{}; + /** + * Normally, a json_iterator operates over a single document, but in + * some cases, we may have a stream of documents. This attribute is meant + * as meta-data: the json_iterator works the same irrespective of the + * value of this attribute. + */ + bool _streaming{ false }; + + public: + simdjson_inline json_iterator() noexcept = default; + simdjson_inline json_iterator(json_iterator&& other) noexcept; + simdjson_inline json_iterator& operator=(json_iterator&& other) noexcept; + simdjson_inline explicit json_iterator(const json_iterator& other) noexcept = default; + simdjson_inline json_iterator& operator=(const json_iterator& other) noexcept = default; + /** + * Skips a JSON value, whether it is a scalar, array or object. + */ + simdjson_warn_unused simdjson_inline error_code skip_child(depth_t parent_depth) noexcept; + + /** + * Tell whether the iterator is still at the start + */ + simdjson_inline bool at_root() const noexcept; + + /** + * Tell whether we should be expected to run in streaming + * mode (iterating over many documents). It is pure metadata + * that does not affect how the iterator works. It is used by + * start_root_array() and start_root_object(). + */ + simdjson_inline bool streaming() const noexcept; + + /** + * Get the root value iterator + */ + simdjson_inline token_position root_position() const noexcept; + /** + * Assert that we are at the document depth (== 1) + */ + simdjson_inline void assert_at_document_depth() const noexcept; + /** + * Assert that we are at the root of the document + */ + simdjson_inline void assert_at_root() const noexcept; + + /** + * Tell whether the iterator is at the EOF mark + */ + simdjson_inline bool at_end() const noexcept; + + /** + * Tell whether the iterator is live (has not been moved). + */ + simdjson_inline bool is_alive() const noexcept; + + /** + * Abandon this iterator, setting depth to 0 (as if the document is finished). + */ + simdjson_inline void abandon() noexcept; + + /** + * Advance the current token without modifying depth. + */ + simdjson_inline const uint8_t* return_current_and_advance() noexcept; + + /** + * Returns true if there is a single token in the index (i.e., it is + * a JSON with a scalar value such as a single number). + * + * @return whether there is a single token + */ + simdjson_inline bool is_single_token() const noexcept; + + /** + * Assert that there are at least the given number of tokens left. + * + * Has no effect in release builds. + */ + simdjson_inline void assert_more_tokens(uint32_t required_tokens = 1) const noexcept; + /** + * Assert that the given position addresses an actual token (is within bounds). + * + * Has no effect in release builds. + */ + simdjson_inline void assert_valid_position(token_position position) const noexcept; + /** + * Get the JSON text for a given token (relative). + * + * This is not null-terminated; it is a view into the JSON. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(int32_t delta = 0) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param delta The relative position of the token to retrieve. e.g. 0 = next token, -1 = prev token. + */ + simdjson_inline uint32_t peek_length(int32_t delta = 0) const noexcept; + /** + * Get a pointer to the current location in the input buffer. + * + * This is not null-terminated; it is a view into the JSON. + * + * You may be pointing outside of the input buffer: it is not generally + * safe to dereference this pointer. + */ + simdjson_inline const uint8_t* unsafe_pointer() const noexcept; + /** + * Get the JSON text for a given token. + * + * This is not null-terminated; it is a view into the JSON. + * + * @param position The position of the token to retrieve. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek(token_position position) const noexcept; + /** + * Get the maximum length of the JSON text for the current token (or relative). + * + * The length will include any whitespace at the end of the token. + * + * @param position The position of the token to retrieve. + */ + simdjson_inline uint32_t peek_length(token_position position) const noexcept; + /** + * Get the JSON text for the last token in the document. + * + * This is not null-terminated; it is a view into the JSON. + * + * TODO consider a string_view, assuming the length will get stripped out by the optimizer when + * it isn't used ... + */ + simdjson_inline const uint8_t* peek_last() const noexcept; + + /** + * Ascend one level. + * + * Validates that the depth - 1 == parent_depth. + * + * @param parent_depth the expected parent depth. + */ + simdjson_inline void ascend_to(depth_t parent_depth) noexcept; + + /** + * Descend one level. + * + * Validates that the new depth == child_depth. + * + * @param child_depth the expected child depth. + */ + simdjson_inline void descend_to(depth_t child_depth) noexcept; + simdjson_inline void descend_to(depth_t child_depth, int32_t delta) noexcept; + + /** + * Get current depth. + */ + simdjson_inline depth_t depth() const noexcept; + + /** + * Get current (writeable) location in the string buffer. + */ + simdjson_inline uint8_t*& string_buf_loc() noexcept; + + /** + * Report an unrecoverable error, preventing further iteration. + * + * @param error The error to report. Must not be SUCCESS, UNINITIALIZED, INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code report_error(error_code error, const char* message) noexcept; + + /** + * Log error, but don't stop iteration. + * @param error The error to report. Must be INCORRECT_TYPE, or NO_SUCH_FIELD. + * @param message An error message to report with the error. + */ + simdjson_inline error_code optional_error(error_code error, const char* message) noexcept; + + /** + * Take an input in json containing max_len characters and attempt to copy it over to tmpbuf, a buffer with + * N bytes of capacity. It will return false if N is too small (smaller than max_len) of if it is zero. + * The buffer (tmpbuf) is padded with space characters. + */ + simdjson_warn_unused simdjson_inline bool copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept; + + simdjson_inline token_position position() const noexcept; + /** + * Write the raw_json_string to the string buffer and return a string_view. + * Each raw_json_string should be unescaped once, or else the string buffer might + * overflow. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, bool allow_replacement) noexcept; + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in) noexcept; + + simdjson_inline void reenter_child(token_position position, depth_t child_depth) noexcept; + + simdjson_inline error_code consume_character(char c) noexcept; +#if SIMDJSON_DEVELOPMENT_CHECKS + simdjson_inline token_position start_position(depth_t depth) const noexcept; + simdjson_inline void set_start_position(depth_t depth, token_position position) noexcept; +#endif + + /* Useful for debugging and logging purposes. */ + inline std::string to_string() const noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Updates this json iterator so that it is back at the beginning of the document, + * as if it had just been created. + */ + inline void rewind() noexcept; + /** + * This checks whether the {,},[,] are balanced so that the document + * ends with proper zero depth. This requires scanning the whole document + * and it may be expensive. It is expected that it will be rarely called. + * It does not attempt to match { with } and [ with ]. + */ + inline bool balanced() const noexcept; + protected: + simdjson_inline json_iterator(const uint8_t* buf, ondemand::parser* parser) noexcept; + /// The last token before the end + simdjson_inline token_position last_position() const noexcept; + /// The token *at* the end. This points at gibberish and should only be used for comparison. + simdjson_inline token_position end_position() const noexcept; + /// The end of the buffer. + simdjson_inline token_position end() const noexcept; + + friend class document; + friend class document_stream; + friend class object; + friend class array; + friend class value; + friend class raw_json_string; + friend class parser; + friend class value_iterator; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, logger::log_level level, Args&&... args) noexcept; + template + friend simdjson_inline void logger::log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, logger::log_level level, Args&&... args) noexcept; + }; // json_iterator + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::json_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_H +/* end file simdjson/generic/ondemand/json_iterator.h for westmere */ +/* including simdjson/generic/ondemand/json_type.h for westmere: #include "simdjson/generic/ondemand/json_type.h" */ +/* begin file simdjson/generic/ondemand/json_type.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * The type of a JSON value. + */ + enum class json_type { + // Start at 1 to catch uninitialized / default values more easily + array = 1, ///< A JSON array ( [ 1, 2, 3 ... ] ) + object, ///< A JSON object ( { "a": 1, "b" 2, ... } ) + number, ///< A JSON number ( 1 or -2.3 or 4.5e6 ...) + string, ///< A JSON string ( "a" or "hello world\n" ...) + boolean, ///< A JSON boolean (true or false) + null ///< A JSON null (null) + }; + + /** + * A type representing a JSON number. + * The design of the struct is deliberately straight-forward. All + * functions return standard values with no error check. + */ + struct number { + + /** + * return the automatically determined type of + * the number: number_type::floating_point_number, + * number_type::signed_integer or number_type::unsigned_integer. + * + * enum class number_type { + * floating_point_number=1, /// a binary64 number + * signed_integer, /// a signed integer that fits in a 64-bit word using two's complement + * unsigned_integer /// a positive integer larger or equal to 1<<63 + * }; + */ + simdjson_inline ondemand::number_type get_number_type() const noexcept; + /** + * return true if the automatically determined type of + * the number is number_type::unsigned_integer. + */ + simdjson_inline bool is_uint64() const noexcept; + /** + * return the value as a uint64_t, only valid if is_uint64() is true. + */ + simdjson_inline uint64_t get_uint64() const noexcept; + simdjson_inline operator uint64_t() const noexcept; + + /** + * return true if the automatically determined type of + * the number is number_type::signed_integer. + */ + simdjson_inline bool is_int64() const noexcept; + /** + * return the value as a int64_t, only valid if is_int64() is true. + */ + simdjson_inline int64_t get_int64() const noexcept; + simdjson_inline operator int64_t() const noexcept; + + + /** + * return true if the automatically determined type of + * the number is number_type::floating_point_number. + */ + simdjson_inline bool is_double() const noexcept; + /** + * return the value as a double, only valid if is_double() is true. + */ + simdjson_inline double get_double() const noexcept; + simdjson_inline operator double() const noexcept; + + /** + * Convert the number to a double. Though it always succeed, the conversion + * may be lossy if the number cannot be represented exactly. + */ + simdjson_inline double as_double() const noexcept; + + + protected: + /** + * The next block of declaration is designed so that we can call the number parsing + * functions on a number type. They are protected and should never be used outside + * of the core simdjson library. + */ + friend class value_iterator; + template + friend error_code numberparsing::slow_float_parsing(simdjson_unused const uint8_t* src, W writer); + template + friend error_code numberparsing::write_float(const uint8_t* const src, bool negative, uint64_t i, const uint8_t* start_digits, size_t digit_count, int64_t exponent, W& writer); + template + friend error_code numberparsing::parse_number(const uint8_t* const src, W& writer); + /** Store a signed 64-bit value to the number. */ + simdjson_inline void append_s64(int64_t value) noexcept; + /** Store an unsigned 64-bit value to the number. */ + simdjson_inline void append_u64(uint64_t value) noexcept; + /** Store a double value to the number. */ + simdjson_inline void append_double(double value) noexcept; + /** Specifies that the value is a double, but leave it undefined. */ + simdjson_inline void skip_double() noexcept; + /** + * End of friend declarations. + */ + + /** + * Our attributes are a union type (size = 64 bits) + * followed by a type indicator. + */ + union { + double floating_point_number; + int64_t signed_integer; + uint64_t unsigned_integer; + } payload{ 0 }; + number_type type{ number_type::signed_integer }; + }; + + /** + * Write the JSON type to the output stream + * + * @param out The output stream. + * @param type The json_type. + */ + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Send JSON type to an output stream. + * + * @param out The output stream. + * @param type The json_type. + * @throw simdjson_error if the result being printed has an error. If there is an error with the + * underlying output stream, that error will be propagated (simdjson_error will not be + * thrown). + */ + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false); +#endif + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::json_type&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_H +/* end file simdjson/generic/ondemand/json_type.h for westmere */ +/* including simdjson/generic/ondemand/raw_json_string.h for westmere: #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * A string escaped per JSON rules, terminated with quote ("). They are used to represent + * unescaped keys inside JSON documents. + * + * (In other words, a pointer to the beginning of a string, just after the start quote, inside a + * JSON file.) + * + * This class is deliberately simplistic and has little functionality. You can + * compare a raw_json_string instance with an unescaped C string, but + * that is nearly all you can do. + * + * The raw_json_string is unescaped. If you wish to write an unescaped version of it to your own + * buffer, you may do so using the parser.unescape(string, buff) method, using an ondemand::parser + * instance. Doing so requires you to have a sufficiently large buffer. + * + * The raw_json_string instances originate typically from field instance which in turn represent + * key-value pairs from object instances. From a field instance, you get the raw_json_string + * instance by calling key(). You can, if you want a more usable string_view instance, call + * the unescaped_key() method on the field instance. You may also create a raw_json_string from + * any other string value, with the value.get_raw_json_string() method. Again, you can get + * a more usable string_view instance by calling get_string(). + * + */ + class raw_json_string { + public: + /** + * Create a new invalid raw_json_string. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline raw_json_string() noexcept = default; + + /** + * Create a new invalid raw_json_string pointed at the given location in the JSON. + * + * The given location must be just *after* the beginning quote (") in the JSON file. + * + * It *must* be terminated by a ", and be a valid JSON string. + */ + simdjson_inline raw_json_string(const uint8_t* _buf) noexcept; + /** + * Get the raw pointer to the beginning of the string in the JSON (just after the "). + * + * It is possible for this function to return a null pointer if the instance + * has outlived its existence. + */ + simdjson_inline const char* raw() const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done) on target.size() characters, + * and if the raw_json_string instance has a quote character at byte index target.size(). + * We never read more than length + 1 bytes in the raw_json_string instance. + * If length is smaller than target.size(), this will return false. + * + * The std::string_view instance may contain any characters. However, the caller + * is responsible for setting length so that length bytes may be read in the + * raw_json_string. + * + * Performance: the comparison may be done using memcmp which may be efficient + * for long strings. + */ + simdjson_inline bool unsafe_is_equal(size_t length, std::string_view target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The std::string_view instance should not contain unescaped quote characters: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * Performance: the comparison is done byte-by-byte which might be inefficient for + * long strings. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + * The provided C string should not contain an unescaped quote character: + * the caller is responsible for this check. See is_free_from_unescaped_quote. + * + * If target is a compile-time constant, and your compiler likes you, + * you should be able to do the following without performance penalty... + * + * static_assert(raw_json_string::is_free_from_unescaped_quote(target), ""); + * s.unsafe_is_equal(target); + */ + simdjson_inline bool unsafe_is_equal(const char* target) const noexcept; + + /** + * This compares the current instance to the std::string_view target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(std::string_view target) const noexcept; + + /** + * This compares the current instance to the C string target: returns true if + * they are byte-by-byte equal (no escaping is done). + */ + simdjson_inline bool is_equal(const char* target) const noexcept; + + /** + * Returns true if target is free from unescaped quote. If target is known at + * compile-time, we might expect the computation to happen at compile time with + * many compilers (not all!). + */ + static simdjson_inline bool is_free_from_unescaped_quote(std::string_view target) noexcept; + static simdjson_inline bool is_free_from_unescaped_quote(const char* target) noexcept; + + private: + + + /** + * This will set the inner pointer to zero, effectively making + * this instance unusable. + */ + simdjson_inline void consume() noexcept { buf = nullptr; } + + /** + * Checks whether the inner pointer is non-null and thus usable. + */ + simdjson_inline simdjson_warn_unused bool alive() const noexcept { return buf != nullptr; } + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result will be a valid UTF-8. + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + * @param allow_replacement Whether we allow replacement of invalid surrogate pairs. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape(json_iterator& iter, bool allow_replacement) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. + * The result may not be a valid UTF-8. https://simonsapin.github.io/wtf-8/ + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid until the next parse() call on the parser. + * + * @param iter A json_iterator, which contains a buffer where the string will be written. + */ + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(json_iterator& iter) const noexcept; + const uint8_t* buf{}; + friend class object; + friend class field; + friend class parser; + friend struct simdjson_result; + }; + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream&, const raw_json_string&) noexcept; + + /** + * Comparisons between raw_json_string and std::string_view instances are potentially unsafe: the user is responsible + * for providing a string with no unescaped quote. Note that unescaped quotes cannot be present in valid JSON strings. + */ + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept; + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept; + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept; + + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::raw_json_string&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline ~simdjson_result() noexcept = default; ///< @private + + simdjson_inline simdjson_result raw() const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape(westmere::ondemand::json_iterator& iter, bool allow_replacement) const noexcept; + simdjson_inline simdjson_warn_unused simdjson_result unescape_wobbly(westmere::ondemand::json_iterator& iter) const noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_H +/* end file simdjson/generic/ondemand/raw_json_string.h for westmere */ +/* including simdjson/generic/ondemand/parser.h for westmere: #include "simdjson/generic/ondemand/parser.h" */ +/* begin file simdjson/generic/ondemand/parser.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * The default batch size for document_stream instances for this On Demand kernel. + * Note that different On Demand kernel may use a different DEFAULT_BATCH_SIZE value + * in the future. + */ + static constexpr size_t DEFAULT_BATCH_SIZE = 1000000; + /** + * Some adversary might try to set the batch size to 0 or 1, which might cause problems. + * We set a minimum of 32B since anything else is highly likely to be an error. In practice, + * most users will want a much larger batch size. + * + * All non-negative MINIMAL_BATCH_SIZE values should be 'safe' except that, obviously, no JSON + * document can ever span 0 or 1 byte and that very large values would create memory allocation issues. + */ + static constexpr size_t MINIMAL_BATCH_SIZE = 32; + + /** + * A JSON fragment iterator. + * + * This holds the actual iterator as well as the buffer for writing strings. + */ + class parser { + public: + /** + * Create a JSON parser. + * + * The new parser will have zero capacity. + */ + inline explicit parser(size_t max_capacity = SIMDJSON_MAXSIZE_BYTES) noexcept; + + inline parser(parser&& other) noexcept = default; + simdjson_inline parser(const parser& other) = delete; + simdjson_inline parser& operator=(const parser& other) = delete; + simdjson_inline parser& operator=(parser&& other) noexcept = default; + + /** Deallocate the JSON parser. */ + inline ~parser() noexcept = default; + + /** + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * document doc = parser.iterate(json); + * + * It is expected that the content is a valid UTF-8 file, containing a valid JSON document. + * Otherwise the iterate method may return an error. In particular, the whole input should be + * valid: we do not attempt to tolerate incorrect content either before or after a JSON + * document. If there is a UTF-8 BOM, the parser skips it. + * + * ### IMPORTANT: Validate what you use + * + * Calling iterate on an invalid JSON document may not immediately trigger an error. The call to + * iterate does not parse and validate the whole document. + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * @param len The length of the JSON. + * @param capacity The number of bytes allocated in the JSON (must be at least len+SIMDJSON_PADDING). + * + * @return The document, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate(padded_string_view json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const char* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const uint8_t* json, size_t len, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string_view json, size_t capacity) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(std::string& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(const simdjson_result& json) & noexcept; + /** @overload simdjson_result iterate(padded_string_view json) & noexcept */ + simdjson_warn_unused simdjson_result iterate(padded_string&& json) & noexcept = delete; + + /** + * @private + * + * Start iterating an on-demand JSON document. + * + * ondemand::parser parser; + * json_iterator doc = parser.iterate(json); + * + * ### IMPORTANT: Buffer Lifetime + * + * Because parsing is done while you iterate, you *must* keep the JSON buffer around at least as + * long as the document iteration. + * + * ### IMPORTANT: Document Lifetime + * + * Only one iteration at a time can happen per parser, and the parser *must* be kept alive during + * iteration to ensure intermediate buffers can be accessed. Any document must be destroyed before + * you call parse() again or destroy the parser. + * + * The ondemand::document instance holds the iterator. The document must remain in scope + * while you are accessing instances of ondemand::value, ondemand::object, ondemand::array. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * @param json The JSON to parse. + * + * @return The iterator, or an error: + * - INSUFFICIENT_PADDING if the input has less than SIMDJSON_PADDING extra bytes. + * - MEMALLOC if realloc_if_needed the parser does not have enough capacity, and memory + * allocation fails. + * - EMPTY if the document is all whitespace. + * - UTF8_ERROR if the document is not valid UTF-8. + * - UNESCAPED_CHARS if a string contains control characters that must be escaped + * - UNCLOSED_STRING if there is an unclosed string in the document. + */ + simdjson_warn_unused simdjson_result iterate_raw(padded_string_view json) & noexcept; + + + /** + * Parse a buffer containing many JSON documents. + * + * auto json = R"({ "foo": 1 } { "foo": 2 } { "foo": 3 } )"_padded; + * ondemand::parser parser; + * ondemand::document_stream docs = parser.iterate_many(json); + * for (auto & doc : docs) { + * std::cout << doc["foo"] << std::endl; + * } + * // Prints 1 2 3 + * + * No copy of the input buffer is made. + * + * The function is lazy: it may be that no more than one JSON document at a time is parsed. + * + * The caller is responsabile to ensure that the input string data remains unchanged and is + * not deleted during the loop. + * + * ### Format + * + * The buffer must contain a series of one or more JSON documents, concatenated into a single + * buffer, separated by ASCII whitespace. It effectively parses until it has a fully valid document, + * then starts parsing the next document at that point. (It does this with more parallelism and + * lookahead than you might think, though.) + * + * documents that consist of an object or array may omit the whitespace between them, concatenating + * with no separator. Documents that consist of a single primitive (i.e. documents that are not + * arrays or objects) MUST be separated with ASCII whitespace. + * + * The characters inside a JSON document, and between JSON documents, must be valid Unicode (UTF-8). + * If there is a UTF-8 BOM, the parser skips it. + * + * The documents must not exceed batch_size bytes (by default 1MB) or they will fail to parse. + * Setting batch_size to excessively large or excessively small values may impact negatively the + * performance. + * + * ### REQUIRED: Buffer Padding + * + * The buffer must have at least SIMDJSON_PADDING extra allocated bytes. It does not matter what + * those bytes are initialized to, as long as they are allocated. These bytes will be read: if you + * using a sanitizer that verifies that no uninitialized byte is read, then you should initialize the + * SIMDJSON_PADDING bytes to avoid runtime warnings. + * + * ### Threads + * + * When compiled with SIMDJSON_THREADS_ENABLED, this method will use a single thread under the + * hood to do some lookahead. + * + * ### Parser Capacity + * + * If the parser's current capacity is less than batch_size, it will allocate enough capacity + * to handle it (up to max_capacity). + * + * @param buf The concatenated JSON to parse. + * @param len The length of the concatenated JSON. + * @param batch_size The batch size to use. MUST be larger than the largest document. The sweet + * spot is cache-related: small enough to fit in cache, yet big enough to + * parse as many documents as possible in one tight loop. + * Defaults to 10MB, which has been a reasonable sweet spot in our tests. + * @param allow_comma_separated (defaults on false) This allows a mode where the documents are + * separated by commas instead of whitespace. It comes with a performance + * penalty because the entire document is indexed at once (and the document must be + * less than 4 GB), and there is no multithreading. In this mode, the batch_size parameter + * is effectively ignored, as it is set to at least the document size. + * @return The stream, or an error. An empty input will yield 0 documents rather than an EMPTY error. Errors: + * - MEMALLOC if the parser does not have enough capacity and memory allocation fails + * - CAPACITY if the parser does not have enough capacity and batch_size > max_capacity. + * - other json errors if parsing fails. You should not rely on these errors to always the same for the + * same document: they may vary under runtime dispatch (so they may vary depending on your system and hardware). + */ + inline simdjson_result iterate_many(const uint8_t* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const char* buf, size_t len, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const std::string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const std::string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + /** @overload parse_many(const uint8_t *buf, size_t len, size_t batch_size) */ + inline simdjson_result iterate_many(const padded_string& s, size_t batch_size = DEFAULT_BATCH_SIZE, bool allow_comma_separated = false) noexcept; + inline simdjson_result iterate_many(const padded_string&& s, size_t batch_size, bool allow_comma_separated = false) = delete;// unsafe + + /** @private We do not want to allow implicit conversion from C string to std::string. */ + simdjson_result iterate_many(const char* buf, size_t batch_size = DEFAULT_BATCH_SIZE) noexcept = delete; + + /** The capacity of this parser (the largest document it can process). */ + simdjson_inline size_t capacity() const noexcept; + /** The maximum capacity of this parser (the largest document it is allowed to process). */ + simdjson_inline size_t max_capacity() const noexcept; + simdjson_inline void set_max_capacity(size_t max_capacity) noexcept; + /** + * The maximum depth of this parser (the most deeply nested objects and arrays it can process). + * This parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + */ + simdjson_inline size_t max_depth() const noexcept; + + /** + * Ensure this parser has enough memory to process JSON documents up to `capacity` bytes in length + * and `max_depth` depth. + * + * The max_depth parameter is only relevant when the macro SIMDJSON_DEVELOPMENT_CHECKS is set to true. + * The document's instance current_depth() method should be used to monitor the parsing + * depth and limit it if desired. + * + * @param capacity The new capacity. + * @param max_depth The new max_depth. Defaults to DEFAULT_MAX_DEPTH. + * @return The error, if there is one. + */ + simdjson_warn_unused error_code allocate(size_t capacity, size_t max_depth = DEFAULT_MAX_DEPTH) noexcept; + +#ifdef SIMDJSON_THREADS_ENABLED + /** + * The parser instance can use threads when they are available to speed up some + * operations. It is enabled by default. Changing this attribute will change the + * behavior of the parser for future operations. + */ + bool threaded{ true }; +#endif + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result must be valid UTF-8. + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @param allow_replacement Whether we allow a replacement if the input string contains unmatched surrogate pairs. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement = false) const noexcept; + + /** + * Unescape this JSON string, replacing \\ with \, \n with newline, etc. to a user-provided buffer. + * The result may not be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * The provided pointer is advanced to the end of the string by reference, and a string_view instance + * is returned. You can ensure that your buffer is large enough by allocating a block of memory at least + * as large as the input JSON plus SIMDJSON_PADDING and then unescape all strings to this one buffer. + * + * This unescape function is a low-level function. If you want a more user-friendly approach, you should + * avoid raw_json_string instances (e.g., by calling unescaped_key() instead of key() or get_string() + * instead of get_raw_json_string()). + * + * ## IMPORTANT: string_view lifetime + * + * The string_view is only valid as long as the bytes in dst. + * + * @param raw_json_string input + * @param dst A pointer to a buffer at least large enough to write this string as well as + * an additional SIMDJSON_PADDING bytes. + * @return A string_view pointing at the unescaped string in dst + * @error STRING_ERROR if escapes are incorrect. + */ + simdjson_inline simdjson_result unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept; + + private: + /** @private [for benchmarking access] The implementation to use */ + std::unique_ptr implementation{}; + size_t _capacity{ 0 }; + size_t _max_capacity; + size_t _max_depth{ DEFAULT_MAX_DEPTH }; + std::unique_ptr string_buf{}; +#if SIMDJSON_DEVELOPMENT_CHECKS + std::unique_ptr start_positions{}; +#endif + + friend class json_iterator; + friend class document_stream; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::parser&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_H +/* end file simdjson/generic/ondemand/parser.h for westmere */ + +// All other declarations +/* including simdjson/generic/ondemand/array.h for westmere: #include "simdjson/generic/ondemand/array.h" */ +/* begin file simdjson/generic/ondemand/array.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * A forward-only JSON array. + */ + class array { + public: + /** + * Create a new invalid array. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline array() noexcept = default; + + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() noexcept; + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an array is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the beginning of the array and checks whether the + * array is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result is_empty() & noexcept; + /** + * Reset the iterator so that we are pointing back at the + * beginning of the array. You should still consume values only once even if you + * can iterate through the array more than once. If you unescape a string + * within the array more than once, you have unsafe code. Note that rewinding + * an array means that you may need to reparse it anew: it is not a free + * operation. + * + * @returns true if the array contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"([ { "foo": { "a": [ 10, 20, 30 ] }} ])"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/0/foo/a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an array + * instance: there is no rewind and no invalidation. + * + * You may only call at_pointer on an array after it has been created, but before it has + * been first accessed. When calling at_pointer on an array, the pointer is advanced to + * the location indicated by the JSON pointer (in case of success). It is no longer possible + * to call at_pointer on the same array. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the array and returns a string_view instance corresponding to the + * array as represented in JSON. It points inside the original document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + /** + * Get the value at the given index. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) noexcept; + protected: + /** + * Go to the end of the array, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + + /** + * Begin array iteration. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + */ + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + /** + * Begin array iteration from the root. + * + * @param iter The iterator. Must be where the initial [ is expected. Will be *moved* into the + * resulting array. + * @error INCORRECT_TYPE if the iterator is not at [. + * @error TAPE_ERROR if there is no closing ] at the end of the document. + */ + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + /** + * Begin array iteration. + * + * This version of the method should be called after the initial [ has been verified, and is + * intended for use by switch statements that check the type of a value. + * + * @param iter The iterator. Must be after the initial [. Will be *moved* into the resulting array. + */ + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + + /** + * Create an array at the given Internal array creation. Call array::start() or array::started() instead of this. + * + * @param iter The iterator. Must either be at the start of the first element with iter.is_alive() + * == true, or past the [] with is_alive() == false if the array is empty. Will be *moved* + * into the resulting array. + */ + simdjson_inline array(const value_iterator& iter) noexcept; + + /** + * Iterator marking current position. + * + * iter.is_alive() == false indicates iteration is complete. + */ + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + friend struct simdjson_result; + friend class array_iterator; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::array&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + inline simdjson_result count_elements() & noexcept; + inline simdjson_result is_empty() & noexcept; + inline simdjson_result reset() & noexcept; + simdjson_inline simdjson_result at(size_t index) noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_H +/* end file simdjson/generic/ondemand/array.h for westmere */ +/* including simdjson/generic/ondemand/array_iterator.h for westmere: #include "simdjson/generic/ondemand/array_iterator.h" */ +/* begin file simdjson/generic/ondemand/array_iterator.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * A forward-only JSON array. + * + * This is an input_iterator, meaning: + * - It is forward-only + * - * must be called exactly once per element. + * - ++ must be called exactly once in between each * (*, ++, *, ++, * ...) + */ + class array_iterator { + public: + /** Create a new, invalid array iterator. */ + simdjson_inline array_iterator() noexcept = default; + + // + // Iterator interface + // + + /** + * Get the current element. + * + * Part of the std::iterator interface. + */ + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + /** + * Check if we are at the end of the JSON. + * + * Part of the std::iterator interface. + * + * @return true if there are no more elements in the JSON array. + */ + simdjson_inline bool operator==(const array_iterator&) const noexcept; + /** + * Check if there are more elements in the JSON array. + * + * Part of the std::iterator interface. + * + * @return true if there are more elements in the JSON array. + */ + simdjson_inline bool operator!=(const array_iterator&) const noexcept; + /** + * Move to the next element. + * + * Part of the std::iterator interface. + */ + simdjson_inline array_iterator& operator++() noexcept; + + private: + value_iterator iter{}; + + simdjson_inline array_iterator(const value_iterator& iter) noexcept; + + friend class array; + friend class value; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::array_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_H +/* end file simdjson/generic/ondemand/array_iterator.h for westmere */ +/* including simdjson/generic/ondemand/document.h for westmere: #include "simdjson/generic/ondemand/document.h" */ +/* begin file simdjson/generic/ondemand/document.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * A JSON document. It holds a json_iterator instance. + * + * Used by tokens to get text, and string buffer location. + * + * You must keep the document around during iteration. + */ + class document { + public: + /** + * Create a new invalid document. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline document() noexcept = default; + simdjson_inline document(const document& other) noexcept = delete; // pass your documents by reference, not by copy + simdjson_inline document(document&& other) noexcept = default; + simdjson_inline document& operator=(const document& other) noexcept = delete; + simdjson_inline document& operator=(document&& other) noexcept = default; + + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @returns INCORRECT_TYPE If the JSON value is not an array. + */ + simdjson_inline simdjson_result get_array() & noexcept; + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @returns INCORRECT_TYPE If the JSON value is not an object. + */ + simdjson_inline simdjson_result get_object() & noexcept; + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64() noexcept; + /** + * Cast this JSON value (inside string) to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64() noexcept; + /** + * Cast this JSON value (inside string) to a signed integer. + * + * @returns A signed 64-bit integer. + * @returns INCORRECT_TYPE If the JSON value is not a 64-bit integer. + */ + simdjson_inline simdjson_result get_int64_in_string() noexcept; + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double() noexcept; + + /** + * Cast this JSON value (inside string) to a double. + * + * @returns A double. + * @returns INCORRECT_TYPE If the JSON value is not a valid floating-point number. + */ + simdjson_inline simdjson_result get_double_in_string() noexcept; + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: Calling get_string() twice on the same document is an error. + * + * @param Whether to allow a replacement character for unmatched surrogate pairs. + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + /** + * Attempts to fill the provided std::string reference with the parsed value of the current string. + * + * The string is guaranteed to be valid UTF-8. + * + * Important: a value should be consumed once. Calling get_string() twice on the same value + * is an error. + * + * Performance: This method may be slower than get_string() or get_string(bool) because it may need to allocate memory. + * We recommend you avoid allocating an std::string unless you need to. + * + * @returns INCORRECT_TYPE if the JSON value is not a string. Otherwise, we return SUCCESS. + */ + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + /** + * Cast this JSON value to a string. + * + * The string is not guaranteed to be valid UTF-8. See https://simonsapin.github.io/wtf-8/ + * + * Important: Calling get_wobbly_string() twice on the same document is an error. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_wobbly_string() noexcept; + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @returns INCORRECT_TYPE if the JSON value is not a string. + */ + simdjson_inline simdjson_result get_raw_json_string() noexcept; + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @returns INCORRECT_TYPE if the JSON value is not true or false. + */ + simdjson_inline simdjson_result get_bool() noexcept; + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is set to 1 (which is the case when building in Debug mode + * by default), and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value if a JSON array or object cannot be found. + * @returns SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result get_value() noexcept; + + /** + * Checks if this JSON value is null. If and only if the value is + * null, then it is consumed (we advance). If we find a token that + * begins with 'n' but is not 'null', then an error is returned. + * + * @returns Whether the value is null. + * @returns INCORRECT_TYPE If the JSON value begins with 'n' and is not 'null'. + */ + simdjson_inline simdjson_result is_null() noexcept; + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool + * + * You may use get_double(), get_bool(), get_uint64(), get_int64(), + * get_object(), get_array(), get_raw_json_string(), or get_string() instead. + * + * @returns A value of the given type, parsed from the JSON. + * @returns INCORRECT_TYPE If the JSON value is not the given type. + */ + template simdjson_inline simdjson_result get() & noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + /** @overload template simdjson_result get() & noexcept */ + template simdjson_inline simdjson_result get() && noexcept { + // Unless the simdjson library provides an inline implementation, calling this method should + // immediately fail. + static_assert(!sizeof(T), "The get method with given type is not implemented by the simdjson library. " + "The supported types are ondemand::object, ondemand::array, raw_json_string, std::string_view, uint64_t, " + "int64_t, double, and bool. We recommend you use get_double(), get_bool(), get_uint64(), get_int64(), " + " get_object(), get_array(), get_raw_json_string(), or get_string() instead of the get template."); + } + + /** + * Get this value as the given type. + * + * Supported types: object, array, raw_json_string, string_view, uint64_t, int64_t, double, bool, value + * + * Be mindful that the document instance must remain in scope while you are accessing object, array and value instances. + * + * @param out This is set to a value of the given type, parsed from the JSON. If there is an error, this may not be initialized. + * @returns INCORRECT_TYPE If the JSON value is not an object. + * @returns SUCCESS If the parse succeeded and the out parameter was set to the value. + */ + template simdjson_inline error_code get(T& out) & noexcept; + /** @overload template error_code get(T &out) & noexcept */ + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + /** + * Cast this JSON value to an array. + * + * @returns An object that can be used to iterate the array. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an array. + */ + simdjson_inline operator array() & noexcept(false); + /** + * Cast this JSON value to an object. + * + * @returns An object that can be used to look up or iterate fields. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not an object. + */ + simdjson_inline operator object() & noexcept(false); + /** + * Cast this JSON value to an unsigned integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit unsigned integer. + */ + simdjson_inline operator uint64_t() noexcept(false); + /** + * Cast this JSON value to a signed integer. + * + * @returns A signed 64-bit integer. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a 64-bit integer. + */ + simdjson_inline operator int64_t() noexcept(false); + /** + * Cast this JSON value to a double. + * + * @returns A double. + * @exception simdjson_error(INCORRECT_TYPE) If the JSON value is not a valid floating-point number. + */ + simdjson_inline operator double() noexcept(false); + /** + * Cast this JSON value to a string. + * + * The string is guaranteed to be valid UTF-8. + * + * @returns An UTF-8 string. The string is stored in the parser and will be invalidated the next + * time it parses a document or when it is destroyed. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator std::string_view() noexcept(false); + /** + * Cast this JSON value to a raw_json_string. + * + * The string is guaranteed to be valid UTF-8, and may have escapes in it (e.g. \\ or \n). + * + * @returns A pointer to the raw JSON for the given string. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not a string. + */ + simdjson_inline operator raw_json_string() noexcept(false); + /** + * Cast this JSON value to a bool. + * + * @returns A bool value. + * @exception simdjson_error(INCORRECT_TYPE) if the JSON value is not true or false. + */ + simdjson_inline operator bool() noexcept(false); + /** + * Cast this JSON value to a value when the document is an object or an array. + * + * You must not have begun iterating through the object or array. When + * SIMDJSON_DEVELOPMENT_CHECKS is defined, and you have already begun iterating, + * you will get an OUT_OF_ORDER_ITERATION error. If you have begun iterating, you can use + * rewind() to reset the document to its initial state before calling this method. + * + * @returns A value value if a JSON array or object cannot be found. + * @exception SCALAR_DOCUMENT_AS_VALUE error is the document is a scalar (see is_scalar() function). + */ + simdjson_inline operator value() noexcept(false); +#endif + /** + * This method scans the array and counts the number of elements. + * The count_elements method should always be called before you have begun + * iterating through the array: it is expected that you are pointing at + * the beginning of the array. + * The runtime complexity is linear in the size of the array. After + * calling this function, if successful, the array is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + simdjson_inline simdjson_result count_elements() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Get the value at the given index in the array. This function has linear-time complexity. + * This function should only be called once on an array instance since the array iterator is not reset between each call. + * + * @return The value at the given index, or: + * - INDEX_OUT_OF_BOUNDS if the array index is larger than an array length + */ + simdjson_inline simdjson_result at(size_t index) & noexcept; + /** + * Begin array iteration. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result begin() & noexcept; + /** + * Sentinel representing the end of the array. + * + * Part of the std::iterable interface. + */ + simdjson_inline simdjson_result end() & noexcept; + + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to + * a key a single time. Doing object["mykey"].to_string()and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. E.g., the array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + + /** + * Get the type of this JSON value. It does not validate or consume the value. + * E.g., you must still call "is_null()" to check that a value is null even if + * "type()" returns json_type::null. + * + * NOTE: If you're only expecting a value to be one type (a typical case), it's generally + * better to just call .get_double, .get_string, etc. and check for INCORRECT_TYPE (or just + * let it throw an exception). + * + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result type() noexcept; + + /** + * Checks whether the document is a scalar (string, number, null, Boolean). + * Returns false when there it is an array or object. + * + * @returns true if the type is string, number, null, Boolean + * @error TAPE_ERROR when the JSON value is a bad token like "}" "," or "alse". + */ + simdjson_inline simdjson_result is_scalar() noexcept; + + /** + * Checks whether the document is a negative number. + * + * @returns true if the number if negative. + */ + simdjson_inline bool is_negative() noexcept; + /** + * Checks whether the document is an integer number. Note that + * this requires to partially parse the number string. If + * the value is determined to be an integer, it may still + * not parse properly as an integer in subsequent steps + * (e.g., it might overflow). + * + * @returns true if the number if negative. + */ + simdjson_inline simdjson_result is_integer() noexcept; + /** + * Determine the number type (integer or floating-point number) as quickly + * as possible. This function does not fully validate the input. It is + * useful when you only need to classify the numbers, without parsing them. + * + * If you are planning to retrieve the value or you need full validation, + * consider using the get_number() method instead: it will fully parse + * and validate the input, and give you access to the type: + * get_number().get_number_type(). + * + * get_number_type() is number_type::unsigned_integer if we have + * an integer greater or equal to 9223372036854775808 + * get_number_type() is number_type::signed_integer if we have an + * integer that is less than 9223372036854775808 + * Otherwise, get_number_type() has value number_type::floating_point_number + * + * This function requires processing the number string, but it is expected + * to be faster than get_number().get_number_type() because it is does not + * parse the number value. + * + * @returns the type of the number + */ + simdjson_inline simdjson_result get_number_type() noexcept; + + /** + * Attempt to parse an ondemand::number. An ondemand::number may + * contain an integer value or a floating-point value, the simdjson + * library will autodetect the type. Thus it is a dynamically typed + * number. Before accessing the value, you must determine the detected + * type. + * + * number.get_number_type() is number_type::signed_integer if we have + * an integer in [-9223372036854775808,9223372036854775808) + * You can recover the value by calling number.get_int64() and you + * have that number.is_int64() is true. + * + * number.get_number_type() is number_type::unsigned_integer if we have + * an integer in [9223372036854775808,18446744073709551616) + * You can recover the value by calling number.get_uint64() and you + * have that number.is_uint64() is true. + * + * Otherwise, number.get_number_type() has value number_type::floating_point_number + * and we have a binary64 number. + * You can recover the value by calling number.get_double() and you + * have that number.is_double() is true. + * + * You must check the type before accessing the value: it is an error + * to call "get_int64()" when number.get_number_type() is not + * number_type::signed_integer and when number.is_int64() is false. + */ + simdjson_warn_unused simdjson_inline simdjson_result get_number() noexcept; + + /** + * Get the raw JSON for this token. + * + * The string_view will always point into the input buffer. + * + * The string_view will start at the beginning of the token, and include the entire token + * *as well as all spaces until the next token (or EOF).* This means, for example, that a + * string token always begins with a " and is always terminated by the final ", possibly + * followed by a number of spaces. + * + * The string_view is *not* null-terminated. If this is a scalar (string, number, + * boolean, or null), the character after the end of the string_view may be the padded buffer. + * + * Tokens include: + * - { + * - [ + * - "a string (possibly with UTF-8 or backslashed characters like \\\")". + * - -1.2e-100 + * - true + * - false + * - null + */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + /** + * Reset the iterator inside the document instance so we are pointing back at the + * beginning of the document, as if it had just been created. It invalidates all + * values, objects and arrays that you have created so far (including unescaped strings). + */ + inline void rewind() noexcept; + /** + * Returns debugging information. + */ + inline std::string to_debug_string() noexcept; + /** + * Some unrecoverable error conditions may render the document instance unusable. + * The is_alive() method returns true when the document is still suitable. + */ + inline bool is_alive() noexcept; + + /** + * Returns the current location in the document if in bounds. + */ + inline simdjson_result current_location() const noexcept; + + /** + * Returns true if this document has been fully parsed. + * If you have consumed the whole document and at_end() returns + * false, then there may be trailing content. + */ + inline bool at_end() const noexcept; + + /** + * Returns the current depth in the document if in bounds. + * + * E.g., + * 0 = finished with document + * 1 = document root value (could be [ or {, not yet known) + * 2 = , or } inside root array/object + * 3 = key or value inside root array/object. + */ + simdjson_inline int32_t current_depth() const noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() automatically calls rewind between each call. Thus + * all values, objects and arrays that you have created so far (including unescaped strings) + * are invalidated. After calling at_pointer, you need to consume the result: string values + * should be stored in your own variables, arrays should be decoded and stored in your own array-like + * structures and so forth. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + * - SCALAR_DOCUMENT_AS_VALUE if the json_pointer is empty and the document is not a scalar (see is_scalar() function). + */ + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + /** + * Consumes the document and returns a string_view instance corresponding to the + * document as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + protected: + /** + * Consumes the document. + */ + simdjson_inline error_code consume() noexcept; + + simdjson_inline document(ondemand::json_iterator&& iter) noexcept; + simdjson_inline const uint8_t* text(uint32_t idx) const noexcept; + + simdjson_inline value_iterator resume_value_iterator() noexcept; + simdjson_inline value_iterator get_root_value_iterator() noexcept; + simdjson_inline simdjson_result start_or_resume_object() noexcept; + static simdjson_inline document start(ondemand::json_iterator&& iter) noexcept; + + // + // Fields + // + json_iterator iter{}; ///< Current position in the document + static constexpr depth_t DOCUMENT_DEPTH = 0; ///< document depth is always 0 + + friend class array_iterator; + friend class value; + friend class ondemand::parser; + friend class object; + friend class array; + friend class field; + friend class token; + friend class document_stream; + friend class document_reference; + }; + + + /** + * A document_reference is a thin wrapper around a document reference instance. + */ + class document_reference { + public: + simdjson_inline document_reference() noexcept; + simdjson_inline document_reference(document& d) noexcept; + simdjson_inline document_reference(const document_reference& other) noexcept = default; + simdjson_inline document_reference& operator=(const document_reference& other) noexcept = default; + simdjson_inline void rewind() noexcept; + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + + simdjson_inline simdjson_result is_null() noexcept; + simdjson_inline simdjson_result raw_json() noexcept; + simdjson_inline operator document& () const noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator array() & noexcept(false); + simdjson_inline operator object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + simdjson_inline simdjson_result raw_json_token() noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + private: + document* doc{ nullptr }; + }; + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::document&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + + template simdjson_inline simdjson_result get() & noexcept; + template simdjson_inline simdjson_result get() && noexcept; + + template simdjson_inline error_code get(T& out) & noexcept; + template simdjson_inline error_code get(T& out) && noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator westmere::ondemand::array() & noexcept(false); + simdjson_inline operator westmere::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator westmere::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator westmere::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline int32_t current_depth() const noexcept; + simdjson_inline bool at_end() const noexcept; + simdjson_inline bool is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + + + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::document_reference value, error_code error) noexcept; + simdjson_inline simdjson_result() noexcept = default; + simdjson_inline error_code rewind() noexcept; + + simdjson_inline simdjson_result get_array() & noexcept; + simdjson_inline simdjson_result get_object() & noexcept; + simdjson_inline simdjson_result get_uint64() noexcept; + simdjson_inline simdjson_result get_uint64_in_string() noexcept; + simdjson_inline simdjson_result get_int64() noexcept; + simdjson_inline simdjson_result get_int64_in_string() noexcept; + simdjson_inline simdjson_result get_double() noexcept; + simdjson_inline simdjson_result get_double_in_string() noexcept; + simdjson_inline simdjson_result get_string(bool allow_replacement = false) noexcept; + template + simdjson_inline error_code get_string(string_type& receiver, bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result get_wobbly_string() noexcept; + simdjson_inline simdjson_result get_raw_json_string() noexcept; + simdjson_inline simdjson_result get_bool() noexcept; + simdjson_inline simdjson_result get_value() noexcept; + simdjson_inline simdjson_result is_null() noexcept; + +#if SIMDJSON_EXCEPTIONS + simdjson_inline operator westmere::ondemand::array() & noexcept(false); + simdjson_inline operator westmere::ondemand::object() & noexcept(false); + simdjson_inline operator uint64_t() noexcept(false); + simdjson_inline operator int64_t() noexcept(false); + simdjson_inline operator double() noexcept(false); + simdjson_inline operator std::string_view() noexcept(false); + simdjson_inline operator westmere::ondemand::raw_json_string() noexcept(false); + simdjson_inline operator bool() noexcept(false); + simdjson_inline operator westmere::ondemand::value() noexcept(false); +#endif + simdjson_inline simdjson_result count_elements() & noexcept; + simdjson_inline simdjson_result count_fields() & noexcept; + simdjson_inline simdjson_result at(size_t index) & noexcept; + simdjson_inline simdjson_result begin() & noexcept; + simdjson_inline simdjson_result end() & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(const char* key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](const char* key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(const char* key) & noexcept; + simdjson_inline simdjson_result type() noexcept; + simdjson_inline simdjson_result is_scalar() noexcept; + simdjson_inline simdjson_result current_location() noexcept; + simdjson_inline simdjson_result current_depth() const noexcept; + simdjson_inline simdjson_result is_negative() noexcept; + simdjson_inline simdjson_result is_integer() noexcept; + simdjson_inline simdjson_result get_number_type() noexcept; + simdjson_inline simdjson_result get_number() noexcept; + /** @copydoc simdjson_inline std::string_view document_reference::raw_json_token() const noexcept */ + simdjson_inline simdjson_result raw_json_token() noexcept; + + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + }; + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_H +/* end file simdjson/generic/ondemand/document.h for westmere */ +/* including simdjson/generic/ondemand/document_stream.h for westmere: #include "simdjson/generic/ondemand/document_stream.h" */ +/* begin file simdjson/generic/ondemand/document_stream.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#ifdef SIMDJSON_THREADS_ENABLED +#include +#include +#include +#endif + +namespace simdjson { + namespace westmere { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + /** @private Custom worker class **/ + struct stage1_worker { + stage1_worker() noexcept = default; + stage1_worker(const stage1_worker&) = delete; + stage1_worker(stage1_worker&&) = delete; + stage1_worker operator=(const stage1_worker&) = delete; + ~stage1_worker(); + /** + * We only start the thread when it is needed, not at object construction, this may throw. + * You should only call this once. + **/ + void start_thread(); + /** + * Start a stage 1 job. You should first call 'run', then 'finish'. + * You must call start_thread once before. + */ + void run(document_stream* ds, parser* stage1, size_t next_batch_start); + /** Wait for the run to finish (blocking). You should first call 'run', then 'finish'. **/ + void finish(); + + private: + + /** + * Normally, we would never stop the thread. But we do in the destructor. + * This function is only safe assuming that you are not waiting for results. You + * should have called run, then finish, and be done. + **/ + void stop_thread(); + + std::thread thread{}; + /** These three variables define the work done by the thread. **/ + ondemand::parser* stage1_thread_parser{}; + size_t _next_batch_start{}; + document_stream* owner{}; + /** + * We have two state variables. This could be streamlined to one variable in the future but + * we use two for clarity. + */ + bool has_work{ false }; + bool can_work{ true }; + + /** + * We lock using a mutex. + */ + std::mutex locking_mutex{}; + std::condition_variable cond_var{}; + + friend class document_stream; + }; +#endif // SIMDJSON_THREADS_ENABLED + + /** + * A forward-only stream of documents. + * + * Produced by parser::iterate_many. + * + */ + class document_stream { + public: + /** + * Construct an uninitialized document_stream. + * + * ```c++ + * document_stream docs; + * auto error = parser.iterate_many(json).get(docs); + * ``` + */ + simdjson_inline document_stream() noexcept; + /** Move one document_stream to another. */ + simdjson_inline document_stream(document_stream&& other) noexcept = default; + /** Move one document_stream to another. */ + simdjson_inline document_stream& operator=(document_stream&& other) noexcept = default; + + simdjson_inline ~document_stream() noexcept; + + /** + * Returns the input size in bytes. + */ + inline size_t size_in_bytes() const noexcept; + + /** + * After iterating through the stream, this method + * returns the number of bytes that were not parsed at the end + * of the stream. If truncated_bytes() differs from zero, + * then the input was truncated maybe because incomplete JSON + * documents were found at the end of the stream. You + * may need to process the bytes in the interval [size_in_bytes()-truncated_bytes(), size_in_bytes()). + * + * You should only call truncated_bytes() after streaming through all + * documents, like so: + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto & doc : stream) { + * // do something with doc + * } + * size_t truncated = stream.truncated_bytes(); + * + */ + inline size_t truncated_bytes() const noexcept; + + class iterator { + public: + using value_type = simdjson_result; + using reference = value_type; + + using difference_type = std::ptrdiff_t; + + using iterator_category = std::input_iterator_tag; + + /** + * Default constructor. + */ + simdjson_inline iterator() noexcept; + /** + * Get the current document (or error). + */ + simdjson_inline simdjson_result operator*() noexcept; + /** + * Advance to the next document (prefix). + */ + inline iterator& operator++() noexcept; + /** + * Check if we're at the end yet. + * @param other the end iterator to compare to. + */ + simdjson_inline bool operator!=(const iterator& other) const noexcept; + /** + * @private + * + * Gives the current index in the input document in bytes. + * + * document_stream stream = parser.parse_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * auto doc = *i; + * size_t index = i.current_index(); + * } + * + * This function (current_index()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + */ + simdjson_inline size_t current_index() const noexcept; + + /** + * @private + * + * Gives a view of the current document at the current position. + * + * document_stream stream = parser.iterate_many(json,window); + * for(auto i = stream.begin(); i != stream.end(); ++i) { + * std::string_view v = i.source(); + * } + * + * The returned string_view instance is simply a map to the (unparsed) + * source string: it may thus include white-space characters and all manner + * of padding. + * + * This function (source()) is experimental and the usage + * may change in future versions of simdjson: we find the API somewhat + * awkward and we would like to offer something friendlier. + * + */ + simdjson_inline std::string_view source() const noexcept; + + /** + * Returns error of the stream (if any). + */ + inline error_code error() const noexcept; + + private: + simdjson_inline iterator(document_stream* s, bool finished) noexcept; + /** The document_stream we're iterating through. */ + document_stream* stream; + /** Whether we're finished or not. */ + bool finished; + + friend class document; + friend class document_stream; + friend class json_iterator; + }; + + /** + * Start iterating the documents in the stream. + */ + simdjson_inline iterator begin() noexcept; + /** + * The end of the stream, for iterator comparison purposes. + */ + simdjson_inline iterator end() noexcept; + + private: + + document_stream& operator=(const document_stream&) = delete; // Disallow copying + document_stream(const document_stream& other) = delete; // Disallow copying + + /** + * Construct a document_stream. Does not allocate or parse anything until the iterator is + * used. + * + * @param parser is a reference to the parser instance used to generate this document_stream + * @param buf is the raw byte buffer we need to process + * @param len is the length of the raw byte buffer in bytes + * @param batch_size is the size of the windows (must be strictly greater or equal to the largest JSON document) + */ + simdjson_inline document_stream( + ondemand::parser& parser, + const uint8_t* buf, + size_t len, + size_t batch_size, + bool allow_comma_separated + ) noexcept; + + /** + * Parse the first document in the buffer. Used by begin(), to handle allocation and + * initialization. + */ + inline void start() noexcept; + + /** + * Parse the next document found in the buffer previously given to document_stream. + * + * The content should be a valid JSON document encoded as UTF-8. If there is a + * UTF-8 BOM, the parser skips it. + * + * You do NOT need to pre-allocate a parser. This function takes care of + * pre-allocating a capacity defined by the batch_size defined when creating the + * document_stream object. + * + * The function returns simdjson::EMPTY if there is no more data to be parsed. + * + * The function returns simdjson::SUCCESS (as integer = 0) in case of success + * and indicates that the buffer has successfully been parsed to the end. + * Every document it contained has been parsed without error. + * + * The function returns an error code from simdjson/simdjson.h in case of failure + * such as simdjson::CAPACITY, simdjson::MEMALLOC, simdjson::DEPTH_ERROR and so forth; + * the simdjson::error_message function converts these error codes into a string). + * + * You can also check validity by calling parser.is_valid(). The same parser can + * and should be reused for the other documents in the buffer. + */ + inline void next() noexcept; + + /** Move the json_iterator of the document to the location of the next document in the stream. */ + inline void next_document() noexcept; + + /** Get the next document index. */ + inline size_t next_batch_start() const noexcept; + + /** Pass the next batch through stage 1 with the given parser. */ + inline error_code run_stage1(ondemand::parser& p, size_t batch_start) noexcept; + + // Fields + ondemand::parser* parser; + const uint8_t* buf; + size_t len; + size_t batch_size; + bool allow_comma_separated; + /** + * We are going to use just one document instance. The document owns + * the json_iterator. It implies that we only ever pass a reference + * to the document to the users. + */ + document doc{}; + /** The error (or lack thereof) from the current document. */ + error_code error; + size_t batch_start{ 0 }; + size_t doc_index{}; + +#ifdef SIMDJSON_THREADS_ENABLED + /** Indicates whether we use threads. Note that this needs to be a constant during the execution of the parsing. */ + bool use_thread; + + inline void load_from_stage1_thread() noexcept; + + /** Start a thread to run stage 1 on the next batch. */ + inline void start_stage1_thread() noexcept; + + /** Wait for the stage 1 thread to finish and capture the results. */ + inline void finish_stage1_thread() noexcept; + + /** The error returned from the stage 1 thread. */ + error_code stage1_thread_error{ UNINITIALIZED }; + /** The thread used to run stage 1 against the next batch in the background. */ + std::unique_ptr worker{ new(std::nothrow) stage1_worker() }; + /** + * The parser used to run stage 1 in the background. Will be swapped + * with the regular parser when finished. + */ + ondemand::parser stage1_thread_parser{}; + + friend struct stage1_worker; +#endif // SIMDJSON_THREADS_ENABLED + + friend class parser; + friend class document; + friend class json_iterator; + friend struct simdjson_result; + friend struct internal::simdjson_result_base; + }; // document_stream + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::document_stream&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_H +/* end file simdjson/generic/ondemand/document_stream.h for westmere */ +/* including simdjson/generic/ondemand/field.h for westmere: #include "simdjson/generic/ondemand/field.h" */ +/* begin file simdjson/generic/ondemand/field.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * A JSON field (key/value pair) in an object. + * + * Returned from object iteration. + * + * Extends from std::pair so you can use C++ algorithms that rely on pairs. + */ + class field : public std::pair { + public: + /** + * Create a new invalid field. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline field() noexcept; + + /** + * Get the key as a string_view (for higher speed, consider raw_key). + * We deliberately use a more cumbersome name (unescaped_key) to force users + * to think twice about using it. + * + * This consumes the key: once you have called unescaped_key(), you cannot + * call it again nor can you call key(). + */ + simdjson_inline simdjson_warn_unused simdjson_result unescaped_key(bool allow_replacement) noexcept; + /** + * Get the key as a raw_json_string. Can be used for direct comparison with + * an unescaped C string: e.g., key() == "test". + */ + simdjson_inline raw_json_string key() const noexcept; + /** + * Get the field value. + */ + simdjson_inline ondemand::value& value() & noexcept; + /** + * @overload ondemand::value &ondemand::value() & noexcept + */ + simdjson_inline ondemand::value value() && noexcept; + + protected: + simdjson_inline field(raw_json_string key, ondemand::value&& value) noexcept; + static simdjson_inline simdjson_result start(value_iterator& parent_iter) noexcept; + static simdjson_inline simdjson_result start(const value_iterator& parent_iter, raw_json_string key) noexcept; + friend struct simdjson_result; + friend class object_iterator; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::field&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result unescaped_key(bool allow_replacement = false) noexcept; + simdjson_inline simdjson_result key() noexcept; + simdjson_inline simdjson_result value() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_H +/* end file simdjson/generic/ondemand/field.h for westmere */ +/* including simdjson/generic/ondemand/object.h for westmere: #include "simdjson/generic/ondemand/object.h" */ +/* begin file simdjson/generic/ondemand/object.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * A forward-only JSON object field iterator. + */ + class object { + public: + /** + * Create a new invalid object. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + /** + * Look up a field by name on an object (order-sensitive). + * + * The following code reads z, then y, then x, and thus will not retrieve x or y if fed the + * JSON `{ "x": 1, "y": 2, "z": 3 }`: + * + * ```c++ + * simdjson::ondemand::parser parser; + * auto obj = parser.parse(R"( { "x": 1, "y": 2, "z": 3 } )"_padded); + * double z = obj.find_field("z"); + * double y = obj.find_field("y"); + * double x = obj.find_field("x"); + * ``` + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * **Raw Keys:** The lookup will be done against the *raw* key, and will not unescape keys. + * e.g. `object["a"]` will match `{ "a": 1 }`, but will *not* match `{ "\u0061": 1 }`. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a + * key a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() + * is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + + /** + * Look up a field by name on an object, without regard to key order. + * + * **Performance Notes:** This is a bit less performant than find_field(), though its effect varies + * and often appears negligible. It starts out normally, starting out at the last field; but if + * the field is not found, it scans from the beginning of the object to see if it missed it. That + * missing case has a non-cache-friendly bump and lots of extra scanning, especially if the object + * in question is large. The fact that the extra code is there also bumps the executable size. + * + * It is the default, however, because it would be highly surprising (and hard to debug) if the + * default behavior failed to look up a field just because it was in the wrong order--and many + * APIs assume this. Therefore, you must be explicit if you want to treat objects as out of order. + * + * Use find_field() if you are sure fields will be in order (or are willing to treat it as if the + * field wasn't there when they aren't). + * + * If you have multiple fields with a matching key ({"x": 1, "x": 1}) be mindful + * that only one field is returned. + * + * You must consume the fields on an object one at a time. A request for a new key + * invalidates previous field values: it makes them unsafe. The value instance you get + * from `content["bids"]` becomes invalid when you call `content["asks"]`. The array + * given by content["bids"].get_array() should not be accessed after you have called + * content["asks"].get_array(). You can detect such mistakes by first compiling and running + * the code in Debug mode (or with the macro `SIMDJSON_DEVELOPMENT_CHECKS` set to 1): an + * OUT_OF_ORDER_ITERATION error is generated. + * + * You are expected to access keys only once. You should access the value corresponding to a key + * a single time. Doing object["mykey"].to_string() and then again object["mykey"].to_string() is an error. + * + * @param key The key to look up. + * @returns The value of the field, or NO_SUCH_FIELD if the field is not in the object. + */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + /** @overload simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; */ + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + + /** + * Get the value associated with the given JSON pointer. We use the RFC 6901 + * https://tools.ietf.org/html/rfc6901 standard, interpreting the current node + * as the root of its own JSON document. + * + * ondemand::parser parser; + * auto json = R"({ "foo": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("/foo/a/1") == 20 + * + * It is allowed for a key to be the empty string: + * + * ondemand::parser parser; + * auto json = R"({ "": { "a": [ 10, 20, 30 ] }})"_padded; + * auto doc = parser.iterate(json); + * doc.at_pointer("//a/1") == 20 + * + * Note that at_pointer() called on the document automatically calls the document's rewind + * method between each call. It invalidates all previously accessed arrays, objects and values + * that have not been consumed. Yet it is not the case when calling at_pointer on an object + * instance: there is no rewind and no invalidation. + * + * You may call at_pointer more than once on an object, but each time the pointer is advanced + * to be within the value matched by the key indicated by the JSON pointer query. Thus any preceding + * key (as well as the current key) can no longer be used with following JSON pointer calls. + * + * Also note that at_pointer() relies on find_field() which implies that we do not unescape keys when matching. + * + * @return The value associated with the given JSON pointer, or: + * - NO_SUCH_FIELD if a field does not exist in an object + * - INDEX_OUT_OF_BOUNDS if an array index is larger than an array length + * - INCORRECT_TYPE if a non-integer is used to access an array + * - INVALID_JSON_POINTER if the JSON pointer is invalid and cannot be parsed + */ + inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + + /** + * Reset the iterator so that we are pointing back at the + * beginning of the object. You should still consume values only once even if you + * can iterate through the object more than once. If you unescape a string within + * the object more than once, you have unsafe code. Note that rewinding an object + * means that you may need to reparse it anew: it is not a free operation. + * + * @returns true if the object contains some elements (not empty) + */ + inline simdjson_result reset() & noexcept; + /** + * This method scans the beginning of the object and checks whether the + * object is empty. + * The runtime complexity is constant time. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + */ + inline simdjson_result is_empty() & noexcept; + /** + * This method scans the object and counts the number of key-value pairs. + * The count_fields method should always be called before you have begun + * iterating through the object: it is expected that you are pointing at + * the beginning of the object. + * The runtime complexity is linear in the size of the object. After + * calling this function, if successful, the object is 'rewinded' at its + * beginning as if it had never been accessed. If the JSON is malformed (e.g., + * there is a missing comma), then an error is returned and it is no longer + * safe to continue. + * + * To check that an object is empty, it is more performant to use + * the is_empty() method. + * + * Performance hint: You should only call count_fields() as a last + * resort as it may require scanning the document twice or more. + */ + simdjson_inline simdjson_result count_fields() & noexcept; + /** + * Consumes the object and returns a string_view instance corresponding to the + * object as represented in JSON. It points inside the original byte array containing + * the JSON document. + */ + simdjson_inline simdjson_result raw_json() noexcept; + + protected: + /** + * Go to the end of the object, no matter where you are right now. + */ + simdjson_inline error_code consume() noexcept; + static simdjson_inline simdjson_result start(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result start_root(value_iterator& iter) noexcept; + static simdjson_inline simdjson_result started(value_iterator& iter) noexcept; + static simdjson_inline object resume(const value_iterator& iter) noexcept; + simdjson_inline object(const value_iterator& iter) noexcept; + + simdjson_warn_unused simdjson_inline error_code find_field_raw(const std::string_view key) noexcept; + + value_iterator iter{}; + + friend class value; + friend class document; + friend struct simdjson_result; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::object&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + simdjson_inline simdjson_result begin() noexcept; + simdjson_inline simdjson_result end() noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field(std::string_view key) && noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) & noexcept; + simdjson_inline simdjson_result find_field_unordered(std::string_view key) && noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) & noexcept; + simdjson_inline simdjson_result operator[](std::string_view key) && noexcept; + simdjson_inline simdjson_result at_pointer(std::string_view json_pointer) noexcept; + inline simdjson_result reset() noexcept; + inline simdjson_result is_empty() noexcept; + inline simdjson_result count_fields() & noexcept; + inline simdjson_result raw_json() noexcept; + + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_H +/* end file simdjson/generic/ondemand/object.h for westmere */ +/* including simdjson/generic/ondemand/object_iterator.h for westmere: #include "simdjson/generic/ondemand/object_iterator.h" */ +/* begin file simdjson/generic/ondemand/object_iterator.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + class object_iterator { + public: + /** + * Create a new invalid object_iterator. + * + * Exists so you can declare a variable and later assign to it before use. + */ + simdjson_inline object_iterator() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + // MUST ONLY BE CALLED ONCE PER ITERATION. + simdjson_inline simdjson_result operator*() noexcept; + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const object_iterator&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const object_iterator&) const noexcept; + // Checks for ']' and ',' + simdjson_inline object_iterator& operator++() noexcept; + + private: + /** + * The underlying JSON iterator. + * + * PERF NOTE: expected to be elided in favor of the parent document: this is set when the object + * is first used, and never changes afterwards. + */ + value_iterator iter{}; + + simdjson_inline object_iterator(const value_iterator& iter) noexcept; + friend struct simdjson_result; + friend class object; + }; + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + template<> + struct simdjson_result : public westmere::implementation_simdjson_result_base { + public: + simdjson_inline simdjson_result(westmere::ondemand::object_iterator&& value) noexcept; ///< @private + simdjson_inline simdjson_result(error_code error) noexcept; ///< @private + simdjson_inline simdjson_result() noexcept = default; + + // + // Iterator interface + // + + // Reads key and value, yielding them to the user. + simdjson_inline simdjson_result operator*() noexcept; // MUST ONLY BE CALLED ONCE PER ITERATION. + // Assumes it's being compared with the end. true if depth < iter->depth. + simdjson_inline bool operator==(const simdjson_result&) const noexcept; + // Assumes it's being compared with the end. true if depth >= iter->depth. + simdjson_inline bool operator!=(const simdjson_result&) const noexcept; + // Checks for ']' and ',' + simdjson_inline simdjson_result& operator++() noexcept; + }; + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_H +/* end file simdjson/generic/ondemand/object_iterator.h for westmere */ +/* including simdjson/generic/ondemand/serialization.h for westmere: #include "simdjson/generic/ondemand/serialization.h" */ +/* begin file simdjson/generic/ondemand/serialization.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + /** + * Create a string-view instance out of a document instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(westmere::ondemand::document& x) noexcept; + /** + * Create a string-view instance out of a value instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. The value must + * not have been accessed previously. It does not + * validate the content. + */ + inline simdjson_result to_json_string(westmere::ondemand::value& x) noexcept; + /** + * Create a string-view instance out of an object instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(westmere::ondemand::object& x) noexcept; + /** + * Create a string-view instance out of an array instance. The string-view instance + * contains JSON text that is suitable to be parsed as JSON again. It does not + * validate the content. + */ + inline simdjson_result to_json_string(westmere::ondemand::array& x) noexcept; + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); + inline simdjson_result to_json_string(simdjson_result x); +} // namespace simdjson + +/** + * We want to support argument-dependent lookup (ADL). + * Hence we should define operator<< in the namespace + * where the argument (here value, object, etc.) resides. + * Credit: @madhur4127 + * See https://github.com/simdjson/simdjson/issues/1768 + */ +namespace simdjson { + namespace westmere { + namespace ondemand { + + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The element. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::value x); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::array value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The array. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::document& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::document_reference& value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x); +#endif + /** + * Print JSON to an output stream. It does not + * validate the content. + * + * @param out The output stream. + * @param value The object. + * @throw if there is an error with the underlying output stream. simdjson itself will not throw. + */ + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::object value); +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x); +#endif + } + } +} // namespace simdjson::westmere::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_H +/* end file simdjson/generic/ondemand/serialization.h for westmere */ + +// Inline definitions +/* including simdjson/generic/ondemand/array-inl.h for westmere: #include "simdjson/generic/ondemand/array-inl.h" */ +/* begin file simdjson/generic/ondemand/array-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter->depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the array is first found and the iterator is just past the `{`. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the `,` before the next value (or `]`). In this state, + // depth == iter->depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter->depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter->depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the array iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet element may be missing or not be an + // array--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter->depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between elements, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter->depth == depth, and at_start == false. + // + // ## Terminal State + // + // The terminal state has iter->depth < depth. at_start is always false. + // + // - Finished: When we have reached a `]` or have reported an error, we are finished. We signal this + // by decrementing depth. In this state, iter->depth < depth, at_start == false, and + // error == SUCCESS. + // + + simdjson_inline array::array(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result array::start(value_iterator& iter) noexcept { + // We don't need to know if the array is empty to start iteration, but we do want to know if there + // is an error--thus `simdjson_unused`. + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::start_root(value_iterator& iter) noexcept { + simdjson_unused bool has_value; + SIMDJSON_TRY(iter.start_root_array().get(has_value)); + return array(iter); + } + simdjson_inline simdjson_result array::started(value_iterator& iter) noexcept { + bool has_value; + SIMDJSON_TRY(iter.started_array().get(has_value)); + return array(iter); + } + + simdjson_inline simdjson_result array::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return array_iterator(iter); + } + simdjson_inline simdjson_result array::end() noexcept { + return array_iterator(iter); + } + simdjson_inline error_code array::consume() noexcept { + auto error = iter.json_iter().skip_child(iter.depth() - 1); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result array::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter._json_iter->unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline simdjson_result array::count_elements() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the array after counting the number of elements. + iter.reset_array(); + return count; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline simdjson_result array::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_array().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + inline simdjson_result array::reset() & noexcept { + return iter.reset_array(); + } + + inline simdjson_result array::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + // - means "the append position" or "the element after the end of the array" + // We don't support this, because we're returning a real element, not a position. + if (json_pointer == "-") { return INDEX_OUT_OF_BOUNDS; } + + // Read the array index + size_t array_index = 0; + size_t i; + for (i = 0; i < json_pointer.length() && json_pointer[i] != '/'; i++) { + uint8_t digit = uint8_t(json_pointer[i] - '0'); + // Check for non-digit in array index. If it's there, we're trying to get a field in an object + if (digit > 9) { return INCORRECT_TYPE; } + array_index = array_index * 10 + digit; + } + + // 0 followed by other digits is invalid + if (i > 1 && json_pointer[0] == '0') { return INVALID_JSON_POINTER; } // "JSON pointer array index has other characters after 0" + + // Empty string is invalid; so is a "/" with no digits before it + if (i == 0) { return INVALID_JSON_POINTER; } // "Empty string in JSON pointer array index" + // Get the child + auto child = at(array_index); + // If there is an error, it ends here + if (child.error()) { + return child; + } + + // If there is a /, we're not done yet, call recursively. + if (i < json_pointer.length()) { + child = child.at_pointer(json_pointer.substr(i)); + } + return child; + } + + simdjson_inline simdjson_result array::at(size_t index) noexcept { + size_t i = 0; + for (auto value : *this) { + if (i == index) { return value; } + i++; + } + return INDEX_OUT_OF_BOUNDS; + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + westmere::ondemand::array&& value + ) noexcept + : implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept + : implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::is_empty() & noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_INL_H +/* end file simdjson/generic/ondemand/array-inl.h for westmere */ +/* including simdjson/generic/ondemand/array_iterator-inl.h for westmere: #include "simdjson/generic/ondemand/array_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/array_iterator-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline array_iterator::array_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result array_iterator::operator*() noexcept { + if (iter.error()) { iter.abandon(); return iter.error(); } + return value(iter.child()); + } + simdjson_inline bool array_iterator::operator==(const array_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool array_iterator::operator!=(const array_iterator&) const noexcept { + return iter.is_open(); + } + simdjson_inline array_iterator& array_iterator::operator++() noexcept { + error_code error; + // PERF NOTE this is a safety rail ... users should exit loops as soon as they receive an error, so we'll never get here. + // However, it does not seem to make a perf difference, so we add it out of an abundance of caution. + if ((error = iter.error())) { return *this; } + if ((error = iter.skip_child())) { return *this; } + if ((error = iter.has_next_element().error())) { return *this; } + return *this; + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + westmere::ondemand::array_iterator&& value + ) noexcept + : westmere::implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : westmere::implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++(first); + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_ARRAY_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/array_iterator-inl.h for westmere */ +/* including simdjson/generic/ondemand/document-inl.h for westmere: #include "simdjson/generic/ondemand/document-inl.h" */ +/* begin file simdjson/generic/ondemand/document-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline document::document(ondemand::json_iterator&& _iter) noexcept + : iter{ std::forward(_iter) } + { + logger::log_start_value(iter, "document"); + } + + simdjson_inline document document::start(json_iterator&& iter) noexcept { + return document(std::forward(iter)); + } + + inline void document::rewind() noexcept { + iter.rewind(); + } + + inline std::string document::to_debug_string() noexcept { + return iter.to_string(); + } + + inline simdjson_result document::current_location() const noexcept { + return iter.current_location(); + } + + inline int32_t document::current_depth() const noexcept { + return iter.depth(); + } + + inline bool document::at_end() const noexcept { + return iter.at_end(); + } + + + inline bool document::is_alive() noexcept { + return iter.is_alive(); + } + simdjson_inline value_iterator document::resume_value_iterator() noexcept { + return value_iterator(&iter, 1, iter.root_position()); + } + simdjson_inline value_iterator document::get_root_value_iterator() noexcept { + return resume_value_iterator(); + } + simdjson_inline simdjson_result document::start_or_resume_object() noexcept { + if (iter.at_root()) { + return get_object(); + } + else { + return object::resume(resume_value_iterator()); + } + } + simdjson_inline simdjson_result document::get_value() noexcept { + // Make sure we start any arrays or objects before returning, so that start_root_() + // gets called. + + // It is the convention throughout the code that the macro `SIMDJSON_DEVELOPMENT_CHECKS` determines whether + // we check for OUT_OF_ORDER_ITERATION. Proper on::demand code should never trigger this error. +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.at_root()) { return OUT_OF_ORDER_ITERATION; } +#endif + // assert_at_root() serves two purposes: in Debug mode, whether or not + // SIMDJSON_DEVELOPMENT_CHECKS is set or not, it checks that we are at the root of + // the document (this will typically be redundant). In release mode, it generates + // SIMDJSON_ASSUME statements to allow the compiler to make assumptions. + iter.assert_at_root(); + switch (*iter.peek()) { + case '[': { + // The following lines check that the document ends with ]. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_array(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + case '{': { + // The following lines would check that the document ends with }. + auto value_iterator = get_root_value_iterator(); + auto error = value_iterator.check_root_object(); + if (error) { return error; } + return value(get_root_value_iterator()); + } + default: + // Unfortunately, scalar documents are a special case in simdjson and they cannot + // be safely converted to value instances. + return SCALAR_DOCUMENT_AS_VALUE; + } + } + simdjson_inline simdjson_result document::get_array() & noexcept { + auto value = get_root_value_iterator(); + return array::start_root(value); + } + simdjson_inline simdjson_result document::get_object() & noexcept { + auto value = get_root_value_iterator(); + return object::start_root(value); + } + + /** + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. We want to disallow trailing + * content. + * Thus, in several implementations below, we pass a 'true' parameter value to + * a get_root_value_iterator() method: this indicates that we disallow trailing content. + */ + + simdjson_inline simdjson_result document::get_uint64() noexcept { + return get_root_value_iterator().get_root_uint64(true); + } + simdjson_inline simdjson_result document::get_uint64_in_string() noexcept { + return get_root_value_iterator().get_root_uint64_in_string(true); + } + simdjson_inline simdjson_result document::get_int64() noexcept { + return get_root_value_iterator().get_root_int64(true); + } + simdjson_inline simdjson_result document::get_int64_in_string() noexcept { + return get_root_value_iterator().get_root_int64_in_string(true); + } + simdjson_inline simdjson_result document::get_double() noexcept { + return get_root_value_iterator().get_root_double(true); + } + simdjson_inline simdjson_result document::get_double_in_string() noexcept { + return get_root_value_iterator().get_root_double_in_string(true); + } + simdjson_inline simdjson_result document::get_string(bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(true, allow_replacement); + } + template + simdjson_inline error_code document::get_string(string_type& receiver, bool allow_replacement) noexcept { + return get_root_value_iterator().get_root_string(receiver, true, allow_replacement); + } + simdjson_inline simdjson_result document::get_wobbly_string() noexcept { + return get_root_value_iterator().get_root_wobbly_string(true); + } + simdjson_inline simdjson_result document::get_raw_json_string() noexcept { + return get_root_value_iterator().get_root_raw_json_string(true); + } + simdjson_inline simdjson_result document::get_bool() noexcept { + return get_root_value_iterator().get_root_bool(true); + } + simdjson_inline simdjson_result document::is_null() noexcept { + return get_root_value_iterator().is_root_null(true); + } + + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_array(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_object(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_double(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_bool(); } + template<> simdjson_inline simdjson_result document::get() & noexcept { return get_value(); } + + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_double(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_uint64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_int64(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return std::forward(*this).get_bool(); } + template<> simdjson_inline simdjson_result document::get() && noexcept { return get_value(); } + + template simdjson_inline error_code document::get(T& out) & noexcept { + return get().get(out); + } + template simdjson_inline error_code document::get(T& out) && noexcept { + return std::forward(*this).get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document::operator array() & noexcept(false) { return get_array(); } + simdjson_inline document::operator object() & noexcept(false) { return get_object(); } + simdjson_inline document::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document::operator double() noexcept(false) { return get_double(); } + simdjson_inline document::operator std::string_view() noexcept(false) { return get_string(false); } + simdjson_inline document::operator raw_json_string() noexcept(false) { return get_raw_json_string(); } + simdjson_inline document::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document::operator value() noexcept(false) { return get_value(); } + +#endif + simdjson_inline simdjson_result document::count_elements() & noexcept { + auto a = get_array(); + simdjson_result answer = a.count_elements(); + /* If there was an array, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::count_fields() & noexcept { + auto a = get_object(); + simdjson_result answer = a.count_fields(); + /* If there was an object, we are now left pointing at its first element. */ + if (answer.error() == SUCCESS) { rewind(); } + return answer; + } + simdjson_inline simdjson_result document::at(size_t index) & noexcept { + auto a = get_array(); + return a.at(index); + } + simdjson_inline simdjson_result document::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result document::end() & noexcept { + return {}; + } + + simdjson_inline simdjson_result document::find_field(std::string_view key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field(const char* key) & noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result document::find_field_unordered(std::string_view key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::find_field_unordered(const char* key) & noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result document::operator[](std::string_view key) & noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result document::operator[](const char* key) & noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline error_code document::consume() noexcept { + auto error = iter.skip_child(0); + if (error) { iter.abandon(); } + return error; + } + + simdjson_inline simdjson_result document::raw_json() noexcept { + auto _iter = get_root_value_iterator(); + const uint8_t* starting_point{ _iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + // After 'consume()', we could be left pointing just beyond the document, but that + // is ok because we are not going to dereference the final pointer position, we just + // use it to compute the length in bytes. + const uint8_t* final_point{ iter.unsafe_pointer() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result document::type() noexcept { + return get_root_value_iterator().type(); + } + + simdjson_inline simdjson_result document::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool document::is_negative() noexcept { + return get_root_value_iterator().is_root_negative(); + } + + simdjson_inline simdjson_result document::is_integer() noexcept { + return get_root_value_iterator().is_root_integer(true); + } + + simdjson_inline simdjson_result document::get_number_type() noexcept { + return get_root_value_iterator().get_root_number_type(true); + } + + simdjson_inline simdjson_result document::get_number() noexcept { + return get_root_value_iterator().get_root_number(true); + } + + + simdjson_inline simdjson_result document::raw_json_token() noexcept { + auto _iter = get_root_value_iterator(); + return std::string_view(reinterpret_cast(_iter.peek_start()), _iter.peek_start_length()); + } + + simdjson_inline simdjson_result document::at_pointer(std::string_view json_pointer) noexcept { + rewind(); // Rewind the document each time at_pointer is called + if (json_pointer.empty()) { + return this->get_value(); + } + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + westmere::ondemand::document&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base( + error + ) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template + simdjson_inline simdjson_result simdjson_result::get() & noexcept { + if (error()) { return error(); } + return first.get(); + } + template + simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first).get(); + } + template + simdjson_inline error_code simdjson_result::get(T& out) & noexcept { + if (error()) { return error(); } + return first.get(out); + } + template + simdjson_inline error_code simdjson_result::get(T& out) && noexcept { + if (error()) { return error(); } + return std::forward(first).get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() & noexcept = delete; + template<> simdjson_inline simdjson_result simdjson_result::get() && noexcept { + if (error()) { return error(); } + return std::forward(first); + } + template<> simdjson_inline error_code simdjson_result::get(westmere::ondemand::document& out) & noexcept = delete; + template<> simdjson_inline error_code simdjson_result::get(westmere::ondemand::document& out) && noexcept { + if (error()) { return error(); } + out = std::forward(first); + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + + + simdjson_inline bool simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } + + +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator westmere::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline bool simdjson_result::at_end() const noexcept { + if (error()) { return error(); } + return first.at_end(); + } + + + simdjson_inline int32_t simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline document_reference::document_reference() noexcept : doc{ nullptr } {} + simdjson_inline document_reference::document_reference(document& d) noexcept : doc(&d) {} + simdjson_inline void document_reference::rewind() noexcept { doc->rewind(); } + simdjson_inline simdjson_result document_reference::get_array() & noexcept { return doc->get_array(); } + simdjson_inline simdjson_result document_reference::get_object() & noexcept { return doc->get_object(); } + /** + * The document_reference instances are used primarily/solely for streams of JSON + * documents. + * We decided that calling 'get_double()' on the JSON document '1.233 blabla' should + * give an error, so we check for trailing content. + * + * However, for streams of JSON documents, we want to be able to start from + * "321" "321" "321" + * and parse it successfully as a stream of JSON documents, calling get_uint64_in_string() + * successfully each time. + * + * To achieve this result, we pass a 'false' to a get_root_value_iterator() method: + * this indicates that we allow trailing content. + */ + simdjson_inline simdjson_result document_reference::get_uint64() noexcept { return doc->get_root_value_iterator().get_root_uint64(false); } + simdjson_inline simdjson_result document_reference::get_uint64_in_string() noexcept { return doc->get_root_value_iterator().get_root_uint64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_int64() noexcept { return doc->get_root_value_iterator().get_root_int64(false); } + simdjson_inline simdjson_result document_reference::get_int64_in_string() noexcept { return doc->get_root_value_iterator().get_root_int64_in_string(false); } + simdjson_inline simdjson_result document_reference::get_double() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_double_in_string() noexcept { return doc->get_root_value_iterator().get_root_double(false); } + simdjson_inline simdjson_result document_reference::get_string(bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(false, allow_replacement); } + template + simdjson_inline error_code document_reference::get_string(string_type& receiver, bool allow_replacement) noexcept { return doc->get_root_value_iterator().get_root_string(receiver, false, allow_replacement); } + simdjson_inline simdjson_result document_reference::get_wobbly_string() noexcept { return doc->get_root_value_iterator().get_root_wobbly_string(false); } + simdjson_inline simdjson_result document_reference::get_raw_json_string() noexcept { return doc->get_root_value_iterator().get_root_raw_json_string(false); } + simdjson_inline simdjson_result document_reference::get_bool() noexcept { return doc->get_root_value_iterator().get_root_bool(false); } + simdjson_inline simdjson_result document_reference::get_value() noexcept { return doc->get_value(); } + simdjson_inline simdjson_result document_reference::is_null() noexcept { return doc->get_root_value_iterator().is_root_null(false); } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline document_reference::operator array() & noexcept(false) { return array(*doc); } + simdjson_inline document_reference::operator object() & noexcept(false) { return object(*doc); } + simdjson_inline document_reference::operator uint64_t() noexcept(false) { return get_uint64(); } + simdjson_inline document_reference::operator int64_t() noexcept(false) { return get_int64(); } + simdjson_inline document_reference::operator double() noexcept(false) { return get_double(); } + simdjson_inline document_reference::operator std::string_view() noexcept(false) { return std::string_view(*doc); } + simdjson_inline document_reference::operator raw_json_string() noexcept(false) { return raw_json_string(*doc); } + simdjson_inline document_reference::operator bool() noexcept(false) { return get_bool(); } + simdjson_inline document_reference::operator value() noexcept(false) { return value(*doc); } +#endif + simdjson_inline simdjson_result document_reference::count_elements() & noexcept { return doc->count_elements(); } + simdjson_inline simdjson_result document_reference::count_fields() & noexcept { return doc->count_fields(); } + simdjson_inline simdjson_result document_reference::at(size_t index) & noexcept { return doc->at(index); } + simdjson_inline simdjson_result document_reference::begin() & noexcept { return doc->begin(); } + simdjson_inline simdjson_result document_reference::end() & noexcept { return doc->end(); } + simdjson_inline simdjson_result document_reference::find_field(std::string_view key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::find_field(const char* key) & noexcept { return doc->find_field(key); } + simdjson_inline simdjson_result document_reference::operator[](std::string_view key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::operator[](const char* key) & noexcept { return (*doc)[key]; } + simdjson_inline simdjson_result document_reference::find_field_unordered(std::string_view key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::find_field_unordered(const char* key) & noexcept { return doc->find_field_unordered(key); } + simdjson_inline simdjson_result document_reference::type() noexcept { return doc->type(); } + simdjson_inline simdjson_result document_reference::is_scalar() noexcept { return doc->is_scalar(); } + simdjson_inline simdjson_result document_reference::current_location() noexcept { return doc->current_location(); } + simdjson_inline int32_t document_reference::current_depth() const noexcept { return doc->current_depth(); } + simdjson_inline bool document_reference::is_negative() noexcept { return doc->is_negative(); } + simdjson_inline simdjson_result document_reference::is_integer() noexcept { return doc->get_root_value_iterator().is_root_integer(false); } + simdjson_inline simdjson_result document_reference::get_number_type() noexcept { return doc->get_root_value_iterator().get_root_number_type(false); } + simdjson_inline simdjson_result document_reference::get_number() noexcept { return doc->get_root_value_iterator().get_root_number(false); } + simdjson_inline simdjson_result document_reference::raw_json_token() noexcept { return doc->raw_json_token(); } + simdjson_inline simdjson_result document_reference::at_pointer(std::string_view json_pointer) noexcept { return doc->at_pointer(json_pointer); } + simdjson_inline simdjson_result document_reference::raw_json() noexcept { return doc->raw_json(); } + simdjson_inline document_reference::operator document& () const noexcept { return *doc; } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + + + +namespace simdjson { + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::document_reference value, error_code error) + noexcept : implementation_simdjson_result_base(std::forward(value), error) {} + + + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) & noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline error_code simdjson_result::rewind() noexcept { + if (error()) { return error(); } + first.rewind(); + return SUCCESS; + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::get_array() & noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() & noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::get_value() noexcept { + if (error()) { return error(); } + return first.get_value(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator westmere::ondemand::array() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::object() & noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::value() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_INL_H +/* end file simdjson/generic/ondemand/document-inl.h for westmere */ +/* including simdjson/generic/ondemand/document_stream-inl.h for westmere: #include "simdjson/generic/ondemand/document_stream-inl.h" */ +/* begin file simdjson/generic/ondemand/document_stream-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace westmere { + namespace ondemand { + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void stage1_worker::finish() { + // After calling "run" someone would call finish() to wait + // for the end of the processing. + // This function will wait until either the thread has done + // the processing or, else, the destructor has been called. + std::unique_lock lock(locking_mutex); + cond_var.wait(lock, [this] {return has_work == false; }); + } + + inline stage1_worker::~stage1_worker() { + // The thread may never outlive the stage1_worker instance + // and will always be stopped/joined before the stage1_worker + // instance is gone. + stop_thread(); + } + + inline void stage1_worker::start_thread() { + std::unique_lock lock(locking_mutex); + if (thread.joinable()) { + return; // This should never happen but we never want to create more than one thread. + } + thread = std::thread([this] { + while (true) { + std::unique_lock thread_lock(locking_mutex); + // We wait for either "run" or "stop_thread" to be called. + cond_var.wait(thread_lock, [this] {return has_work || !can_work; }); + // If, for some reason, the stop_thread() method was called (i.e., the + // destructor of stage1_worker is called, then we want to immediately destroy + // the thread (and not do any more processing). + if (!can_work) { + break; + } + this->owner->stage1_thread_error = this->owner->run_stage1(*this->stage1_thread_parser, + this->_next_batch_start); + this->has_work = false; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify "finish" + thread_lock.unlock(); + } + } + ); + } + + + inline void stage1_worker::stop_thread() { + std::unique_lock lock(locking_mutex); + // We have to make sure that all locks can be released. + can_work = false; + has_work = false; + cond_var.notify_all(); + lock.unlock(); + if (thread.joinable()) { + thread.join(); + } + } + + inline void stage1_worker::run(document_stream* ds, parser* stage1, size_t next_batch_start) { + std::unique_lock lock(locking_mutex); + owner = ds; + _next_batch_start = next_batch_start; + stage1_thread_parser = stage1; + has_work = true; + // The condition variable call should be moved after thread_lock.unlock() for performance + // reasons but thread sanitizers may report it as a data race if we do. + // See https://stackoverflow.com/questions/35775501/c-should-condition-variable-be-notified-under-lock + cond_var.notify_one(); // will notify the thread lock that we have work + lock.unlock(); + } + +#endif // SIMDJSON_THREADS_ENABLED + + simdjson_inline document_stream::document_stream( + ondemand::parser& _parser, + const uint8_t* _buf, + size_t _len, + size_t _batch_size, + bool _allow_comma_separated + ) noexcept + : parser{ &_parser }, + buf{ _buf }, + len{ _len }, + batch_size{ _batch_size <= MINIMAL_BATCH_SIZE ? MINIMAL_BATCH_SIZE : _batch_size }, + allow_comma_separated{ _allow_comma_separated }, + error{ SUCCESS } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(_parser.threaded) // we need to make a copy because _parser.threaded can change +#endif + { +#ifdef SIMDJSON_THREADS_ENABLED + if (worker.get() == nullptr) { + error = MEMALLOC; + } +#endif + } + + simdjson_inline document_stream::document_stream() noexcept + : parser{ nullptr }, + buf{ nullptr }, + len{ 0 }, + batch_size{ 0 }, + allow_comma_separated{ false }, + error{ UNINITIALIZED } +#ifdef SIMDJSON_THREADS_ENABLED + , use_thread(false) +#endif + { + } + + simdjson_inline document_stream::~document_stream() noexcept + { +#ifdef SIMDJSON_THREADS_ENABLED + worker.reset(); +#endif + } + + inline size_t document_stream::size_in_bytes() const noexcept { + return len; + } + + inline size_t document_stream::truncated_bytes() const noexcept { + if (error == CAPACITY) { return len - batch_start; } + return parser->implementation->structural_indexes[parser->implementation->n_structural_indexes] - parser->implementation->structural_indexes[parser->implementation->n_structural_indexes + 1]; + } + + simdjson_inline document_stream::iterator::iterator() noexcept + : stream{ nullptr }, finished{ true } { + } + + simdjson_inline document_stream::iterator::iterator(document_stream* _stream, bool is_end) noexcept + : stream{ _stream }, finished{ is_end } { + } + + simdjson_inline simdjson_result document_stream::iterator::operator*() noexcept { + //if(stream->error) { return stream->error; } + return simdjson_result(stream->doc, stream->error); + } + + simdjson_inline document_stream::iterator& document_stream::iterator::operator++() noexcept { + // If there is an error, then we want the iterator + // to be finished, no matter what. (E.g., we do not + // keep generating documents with errors, or go beyond + // a document with errors.) + // + // Users do not have to call "operator*()" when they use operator++, + // so we need to end the stream in the operator++ function. + // + // Note that setting finished = true is essential otherwise + // we would enter an infinite loop. + if (stream->error) { finished = true; } + // Note that stream->error() is guarded against error conditions + // (it will immediately return if stream->error casts to false). + // In effect, this next function does nothing when (stream->error) + // is true (hence the risk of an infinite loop). + stream->next(); + // If that was the last document, we're finished. + // It is the only type of error we do not want to appear + // in operator*. + if (stream->error == EMPTY) { finished = true; } + // If we had any other kind of error (not EMPTY) then we want + // to pass it along to the operator* and we cannot mark the result + // as "finished" just yet. + return *this; + } + + simdjson_inline bool document_stream::iterator::operator!=(const document_stream::iterator& other) const noexcept { + return finished != other.finished; + } + + simdjson_inline document_stream::iterator document_stream::begin() noexcept { + start(); + // If there are no documents, we're finished. + return iterator(this, error == EMPTY); + } + + simdjson_inline document_stream::iterator document_stream::end() noexcept { + return iterator(this, true); + } + + inline void document_stream::start() noexcept { + if (error) { return; } + error = parser->allocate(batch_size); + if (error) { return; } + // Always run the first stage 1 parse immediately + batch_start = 0; + error = run_stage1(*parser, batch_start); + while (error == EMPTY) { + // In exceptional cases, we may start with an empty block + batch_start = next_batch_start(); + if (batch_start >= len) { return; } + error = run_stage1(*parser, batch_start); + } + if (error) { return; } + doc_index = batch_start; + doc = document(json_iterator(&buf[batch_start], parser)); + doc.iter._streaming = true; + +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread && next_batch_start() < len) { + // Kick off the first thread on next batch if needed + error = stage1_thread_parser.allocate(batch_size); + if (error) { return; } + worker->start_thread(); + start_stage1_thread(); + if (error) { return; } + } +#endif // SIMDJSON_THREADS_ENABLED + } + + inline void document_stream::next() noexcept { + // We always enter at once once in an error condition. + if (error) { return; } + next_document(); + if (error) { return; } + auto cur_struct_index = doc.iter._root - parser->implementation->structural_indexes.get(); + doc_index = batch_start + parser->implementation->structural_indexes[cur_struct_index]; + + // Check if at end of structural indexes (i.e. at end of batch) + if (cur_struct_index >= static_cast(parser->implementation->n_structural_indexes)) { + error = EMPTY; + // Load another batch (if available) + while (error == EMPTY) { + batch_start = next_batch_start(); + if (batch_start >= len) { break; } +#ifdef SIMDJSON_THREADS_ENABLED + if (use_thread) { + load_from_stage1_thread(); + } + else { + error = run_stage1(*parser, batch_start); + } +#else + error = run_stage1(*parser, batch_start); +#endif + /** + * Whenever we move to another window, we need to update all pointers to make + * it appear as if the input buffer started at the beginning of the window. + * + * Take this input: + * + * {"z":5} {"1":1,"2":2,"4":4} [7, 10, 9] [15, 11, 12, 13] [154, 110, 112, 1311] + * + * Say you process the following window... + * + * '{"z":5} {"1":1,"2":2,"4":4} [7, 10, 9]' + * + * When you do so, the json_iterator has a pointer at the beginning of the memory region + * (pointing at the beginning of '{"z"...'. + * + * When you move to the window that starts at... + * + * '[7, 10, 9] [15, 11, 12, 13] ... + * + * then it is not sufficient to just run stage 1. You also need to re-anchor the + * json_iterator so that it believes we are starting at '[7, 10, 9]...'. + * + * Under the DOM front-end, this gets done automatically because the parser owns + * the pointer the data, and when you call stage1 and then stage2 on the same + * parser, then stage2 will run on the pointer acquired by stage1. + * + * That is, stage1 calls "this->buf = _buf" so the parser remembers the buffer that + * we used. But json_iterator has no callback when stage1 is called on the parser. + * In fact, I think that the parser is unaware of json_iterator. + * + * + * So we need to re-anchor the json_iterator after each call to stage 1 so that + * all of the pointers are in sync. + */ + doc.iter = json_iterator(&buf[batch_start], parser); + doc.iter._streaming = true; + /** + * End of resync. + */ + + if (error) { continue; } // If the error was EMPTY, we may want to load another batch. + doc_index = batch_start; + } + } + } + + inline void document_stream::next_document() noexcept { + // Go to next place where depth=0 (document depth) + error = doc.iter.skip_child(0); + if (error) { return; } + // Always set depth=1 at the start of document + doc.iter._depth = 1; + // consume comma if comma separated is allowed + if (allow_comma_separated) { doc.iter.consume_character(','); } + // Resets the string buffer at the beginning, thus invalidating the strings. + doc.iter._string_buf_loc = parser->string_buf.get(); + doc.iter._root = doc.iter.position(); + } + + inline size_t document_stream::next_batch_start() const noexcept { + return batch_start + parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]; + } + + inline error_code document_stream::run_stage1(ondemand::parser& p, size_t _batch_start) noexcept { + // This code only updates the structural index in the parser, it does not update any json_iterator + // instance. + size_t remaining = len - _batch_start; + if (remaining <= batch_size) { + return p.implementation->stage1(&buf[_batch_start], remaining, stage1_mode::streaming_final); + } + else { + return p.implementation->stage1(&buf[_batch_start], batch_size, stage1_mode::streaming_partial); + } + } + + simdjson_inline size_t document_stream::iterator::current_index() const noexcept { + return stream->doc_index; + } + + simdjson_inline std::string_view document_stream::iterator::source() const noexcept { + auto depth = stream->doc.iter.depth(); + auto cur_struct_index = stream->doc.iter._root - stream->parser->implementation->structural_indexes.get(); + + // If at root, process the first token to determine if scalar value + if (stream->doc.iter.at_root()) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': // Depth=1 already at start of document + break; + case '}': case ']': + depth--; + break; + default: // Scalar value document + // TODO: Remove any trailing whitespaces + // This returns a string spanning from start of value to the beginning of the next document (excluded) + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[++cur_struct_index] - current_index() - 1); + } + cur_struct_index++; + } + + while (cur_struct_index <= static_cast(stream->parser->implementation->n_structural_indexes)) { + switch (stream->buf[stream->batch_start + stream->parser->implementation->structural_indexes[cur_struct_index]]) { + case '{': case '[': + depth++; + break; + case '}': case ']': + depth--; + break; + } + if (depth == 0) { break; } + cur_struct_index++; + } + + return std::string_view(reinterpret_cast(stream->buf) + current_index(), stream->parser->implementation->structural_indexes[cur_struct_index] - current_index() + stream->batch_start + 1);; + } + + inline error_code document_stream::iterator::error() const noexcept { + return stream->error; + } + +#ifdef SIMDJSON_THREADS_ENABLED + + inline void document_stream::load_from_stage1_thread() noexcept { + worker->finish(); + // Swap to the parser that was loaded up in the thread. Make sure the parser has + // enough memory to swap to, as well. + std::swap(stage1_thread_parser, *parser); + error = stage1_thread_error; + if (error) { return; } + + // If there's anything left, start the stage 1 thread! + if (next_batch_start() < len) { + start_stage1_thread(); + } + } + + inline void document_stream::start_stage1_thread() noexcept { + // we call the thread on a lambda that will update + // this->stage1_thread_error + // there is only one thread that may write to this value + // TODO this is NOT exception-safe. + this->stage1_thread_error = UNINITIALIZED; // In case something goes wrong, make sure it's an error + size_t _next_batch_start = this->next_batch_start(); + + worker->run(this, &this->stage1_thread_parser, _next_batch_start); + } + +#endif // SIMDJSON_THREADS_ENABLED + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result::simdjson_result( + westmere::ondemand::document_stream&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + +} + +#endif // SIMDJSON_GENERIC_ONDEMAND_DOCUMENT_STREAM_INL_H +/* end file simdjson/generic/ondemand/document_stream-inl.h for westmere */ +/* including simdjson/generic/ondemand/field-inl.h for westmere: #include "simdjson/generic/ondemand/field-inl.h" */ +/* begin file simdjson/generic/ondemand/field-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + // clang 6 doesn't think the default constructor can be noexcept, so we make it explicit + simdjson_inline field::field() noexcept : std::pair() {} + + simdjson_inline field::field(raw_json_string key, ondemand::value&& value) noexcept + : std::pair(key, std::forward(value)) + { + } + + simdjson_inline simdjson_result field::start(value_iterator& parent_iter) noexcept { + raw_json_string key; + SIMDJSON_TRY(parent_iter.field_key().get(key)); + SIMDJSON_TRY(parent_iter.field_value()); + return field::start(parent_iter, key); + } + + simdjson_inline simdjson_result field::start(const value_iterator& parent_iter, raw_json_string key) noexcept { + return field(key, parent_iter.child()); + } + + simdjson_inline simdjson_warn_unused simdjson_result field::unescaped_key(bool allow_replacement) noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() but Visual Studio won't let us. + simdjson_result answer = first.unescape(second.iter.json_iter(), allow_replacement); + first.consume(); + return answer; + } + + simdjson_inline raw_json_string field::key() const noexcept { + SIMDJSON_ASSUME(first.buf != nullptr); // We would like to call .alive() by Visual Studio won't let us. + return first; + } + + simdjson_inline value& field::value() & noexcept { + return second; + } + + simdjson_inline value field::value() && noexcept { + return std::forward(*this).second; + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + westmere::ondemand::field&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + + simdjson_inline simdjson_result simdjson_result::key() noexcept { + if (error()) { return error(); } + return first.key(); + } + simdjson_inline simdjson_result simdjson_result::unescaped_key(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.unescaped_key(allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::value() noexcept { + if (error()) { return error(); } + return std::move(first.value()); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_FIELD_INL_H +/* end file simdjson/generic/ondemand/field-inl.h for westmere */ +/* including simdjson/generic/ondemand/json_iterator-inl.h for westmere: #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/json_iterator-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline json_iterator::json_iterator(json_iterator&& other) noexcept + : token(std::forward(other.token)), + parser{ other.parser }, + _string_buf_loc{ other._string_buf_loc }, + error{ other.error }, + _depth{ other._depth }, + _root{ other._root }, + _streaming{ other._streaming } + { + other.parser = nullptr; + } + simdjson_inline json_iterator& json_iterator::operator=(json_iterator&& other) noexcept { + token = other.token; + parser = other.parser; + _string_buf_loc = other._string_buf_loc; + error = other.error; + _depth = other._depth; + _root = other._root; + _streaming = other._streaming; + other.parser = nullptr; + return *this; + } + + simdjson_inline json_iterator::json_iterator(const uint8_t* buf, ondemand::parser* _parser) noexcept + : token(buf, &_parser->implementation->structural_indexes[0]), + parser{ _parser }, + _string_buf_loc{ parser->string_buf.get() }, + _depth{ 1 }, + _root{ parser->implementation->structural_indexes.get() }, + _streaming{ false } + + { + logger::log_headers(); +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif + } + + inline void json_iterator::rewind() noexcept { + token.set_position(root_position()); + logger::log_headers(); // We start again + _string_buf_loc = parser->string_buf.get(); + _depth = 1; + } + + inline bool json_iterator::balanced() const noexcept { + token_iterator ti(token); + int32_t count{ 0 }; + ti.set_position(root_position()); + while (ti.peek() <= peek_last()) { + switch (*ti.return_current_and_advance()) + { + case '[': case '{': + count++; + break; + case ']': case '}': + count--; + break; + default: + break; + } + } + return count == 0; + } + + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and parent_depth, which is a desired effect. The warning does not show up if the + // skip_child() function is not marked inline). + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline error_code json_iterator::skip_child(depth_t parent_depth) noexcept { + if (depth() <= parent_depth) { return SUCCESS; } + switch (*return_current_and_advance()) { + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + + // For the first open array/object in a value, we've already incremented depth, so keep it the same + // We never stop at colon, but if we did, it wouldn't affect depth + case '[': case '{': case ':': + logger::log_start_value(*this, "skip"); + break; + // If there is a comma, we have just finished a value in an array/object, and need to get back in + case ',': + logger::log_value(*this, "skip"); + break; + // ] or } means we just finished a value and need to jump out of the array/object + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } +#if SIMDJSON_CHECK_EOF + // If there are no more tokens, the parent is incomplete. + if (at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "Missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + break; + case '"': + if (*peek() == ':') { + // We are at a key!!! + // This might happen if you just started an object and you skip it immediately. + // Performance note: it would be nice to get rid of this check as it is somewhat + // expensive. + // https://github.com/simdjson/simdjson/issues/1742 + logger::log_value(*this, "key"); + return_current_and_advance(); // eat up the ':' + break; // important!!! + } + simdjson_fallthrough; + // Anything else must be a scalar value + default: + // For the first scalar, we will have incremented depth already, so we decrement it here. + logger::log_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + } + + // Now that we've considered the first value, we only increment/decrement for arrays/objects + while (position() < end_position()) { + switch (*return_current_and_advance()) { + case '[': case '{': + logger::log_start_value(*this, "skip"); + _depth++; + break; + // TODO consider whether matching braces is a requirement: if non-matching braces indicates + // *missing* braces, then future lookups are not in the object/arrays they think they are, + // violating the rule "validate enough structure that the user can be confident they are + // looking at the right values." + // PERF TODO we can eliminate the switch here with a lookup of how much to add to depth + case ']': case '}': + logger::log_end_value(*this, "skip"); + _depth--; + if (depth() <= parent_depth) { return SUCCESS; } + break; + default: + logger::log_value(*this, "skip", ""); + break; + } + } + + return report_error(TAPE_ERROR, "not enough close braces"); + } + + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool json_iterator::at_root() const noexcept { + return position() == root_position(); + } + + simdjson_inline bool json_iterator::is_single_token() const noexcept { + return parser->implementation->n_structural_indexes == 1; + } + + simdjson_inline bool json_iterator::streaming() const noexcept { + return _streaming; + } + + simdjson_inline token_position json_iterator::root_position() const noexcept { + return _root; + } + + simdjson_inline void json_iterator::assert_at_document_depth() const noexcept { + SIMDJSON_ASSUME(_depth == 1); + } + + simdjson_inline void json_iterator::assert_at_root() const noexcept { + SIMDJSON_ASSUME(_depth == 1); +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + // Under Visual Studio, the next SIMDJSON_ASSUME fails with: the argument + // has side effects that will be discarded. + SIMDJSON_ASSUME(token.position() == _root); +#endif + } + + simdjson_inline void json_iterator::assert_more_tokens(uint32_t required_tokens) const noexcept { + assert_valid_position(token._position + required_tokens - 1); + } + + simdjson_inline void json_iterator::assert_valid_position(token_position position) const noexcept { +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(position >= &parser->implementation->structural_indexes[0]); + SIMDJSON_ASSUME(position < &parser->implementation->structural_indexes[parser->implementation->n_structural_indexes]); +#endif + } + + simdjson_inline bool json_iterator::at_end() const noexcept { + return position() == end_position(); + } + simdjson_inline token_position json_iterator::end_position() const noexcept { + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + return &parser->implementation->structural_indexes[n_structural_indexes]; + } + + inline std::string json_iterator::to_string() const noexcept { + if (!is_alive()) { return "dead json_iterator instance"; } + const char* current_structural = reinterpret_cast(token.peek()); + return std::string("json_iterator [ depth : ") + std::to_string(_depth) + + std::string(", structural : '") + std::string(current_structural, 1) + + std::string("', offset : ") + std::to_string(token.current_offset()) + + std::string("', error : ") + error_message(error) + + std::string(" ]"); + } + + inline simdjson_result json_iterator::current_location() const noexcept { + if (!is_alive()) { // Unrecoverable error + if (!at_root()) { + return reinterpret_cast(token.peek(-1)); + } + else { + return reinterpret_cast(token.peek()); + } + } + if (at_end()) { + return OUT_OF_BOUNDS; + } + return reinterpret_cast(token.peek()); + } + + simdjson_inline bool json_iterator::is_alive() const noexcept { + return parser; + } + + simdjson_inline void json_iterator::abandon() noexcept { + parser = nullptr; + _depth = 0; + } + + simdjson_inline const uint8_t* json_iterator::return_current_and_advance() noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(); +#endif // SIMDJSON_CHECK_EOF + return token.return_current_and_advance(); + } + + simdjson_inline const uint8_t* json_iterator::unsafe_pointer() const noexcept { + // deliberately done without safety guard: + return token.peek(); + } + + simdjson_inline const uint8_t* json_iterator::peek(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // SIMDJSON_CHECK_EOF + return token.peek(delta); + } + + simdjson_inline uint32_t json_iterator::peek_length(int32_t delta) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_more_tokens(delta + 1); +#endif // #if SIMDJSON_CHECK_EOF + return token.peek_length(delta); + } + + simdjson_inline const uint8_t* json_iterator::peek(token_position position) const noexcept { + // todo: currently we require end-of-string buffering, but the following + // assert_valid_position should be turned on if/when we lift that condition. + // assert_valid_position(position); + // This is almost surely related to SIMDJSON_CHECK_EOF but given that SIMDJSON_CHECK_EOF + // is ON by default, we have no choice but to disable it for real with a comment. + return token.peek(position); + } + + simdjson_inline uint32_t json_iterator::peek_length(token_position position) const noexcept { +#if SIMDJSON_CHECK_EOF + assert_valid_position(position); +#endif // SIMDJSON_CHECK_EOF + return token.peek_length(position); + } + + simdjson_inline token_position json_iterator::last_position() const noexcept { + // The following line fails under some compilers... + // SIMDJSON_ASSUME(parser->implementation->n_structural_indexes > 0); + // since it has side-effects. + uint32_t n_structural_indexes{ parser->implementation->n_structural_indexes }; + SIMDJSON_ASSUME(n_structural_indexes > 0); + return &parser->implementation->structural_indexes[n_structural_indexes - 1]; + } + simdjson_inline const uint8_t* json_iterator::peek_last() const noexcept { + return token.peek(last_position()); + } + + simdjson_inline void json_iterator::ascend_to(depth_t parent_depth) noexcept { + SIMDJSON_ASSUME(parent_depth >= 0 && parent_depth < INT32_MAX - 1); + SIMDJSON_ASSUME(_depth == parent_depth + 1); + _depth = parent_depth; + } + + simdjson_inline void json_iterator::descend_to(depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); + _depth = child_depth; + } + + simdjson_inline depth_t json_iterator::depth() const noexcept { + return _depth; + } + + simdjson_inline uint8_t*& json_iterator::string_buf_loc() noexcept { + return _string_buf_loc; + } + + simdjson_inline error_code json_iterator::report_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error != SUCCESS && _error != UNINITIALIZED && _error != INCORRECT_TYPE && _error != NO_SUCH_FIELD); + logger::log_error(*this, message); + error = _error; + return error; + } + + simdjson_inline token_position json_iterator::position() const noexcept { + return token.position(); + } + + simdjson_inline simdjson_result json_iterator::unescape(raw_json_string in, bool allow_replacement) noexcept { + return parser->unescape(in, _string_buf_loc, allow_replacement); + } + + simdjson_inline simdjson_result json_iterator::unescape_wobbly(raw_json_string in) noexcept { + return parser->unescape_wobbly(in, _string_buf_loc); + } + + simdjson_inline void json_iterator::reenter_child(token_position position, depth_t child_depth) noexcept { + SIMDJSON_ASSUME(child_depth >= 1 && child_depth < INT32_MAX); + SIMDJSON_ASSUME(_depth == child_depth - 1); +#if SIMDJSON_DEVELOPMENT_CHECKS +#ifndef SIMDJSON_CLANG_VISUAL_STUDIO + SIMDJSON_ASSUME(size_t(child_depth) < parser->max_depth()); + SIMDJSON_ASSUME(position >= parser->start_positions[child_depth]); +#endif +#endif + token.set_position(position); + _depth = child_depth; + } + + simdjson_inline error_code json_iterator::consume_character(char c) noexcept { + if (*peek() == c) { + return_current_and_advance(); + return SUCCESS; + } + return TAPE_ERROR; + } + +#if SIMDJSON_DEVELOPMENT_CHECKS + + simdjson_inline token_position json_iterator::start_position(depth_t depth) const noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + return size_t(depth) < parser->max_depth() ? parser->start_positions[depth] : 0; + } + + simdjson_inline void json_iterator::set_start_position(depth_t depth, token_position position) noexcept { + SIMDJSON_ASSUME(size_t(depth) < parser->max_depth()); + if (size_t(depth) < parser->max_depth()) { parser->start_positions[depth] = position; } + } + +#endif + + + simdjson_inline error_code json_iterator::optional_error(error_code _error, const char* message) noexcept { + SIMDJSON_ASSUME(_error == INCORRECT_TYPE || _error == NO_SUCH_FIELD); + logger::log_error(*this, message); + return _error; + } + + + simdjson_warn_unused simdjson_inline bool json_iterator::copy_to_buffer(const uint8_t* json, uint32_t max_len, uint8_t* tmpbuf, size_t N) noexcept { + // This function is not expected to be called in performance-sensitive settings. + // Let us guard against silly cases: + if ((N < max_len) || (N == 0)) { return false; } + // Copy to the buffer. + std::memcpy(tmpbuf, json, max_len); + if (N > max_len) { // We pad whatever remains with ' '. + std::memset(tmpbuf + max_len, ' ', N - max_len); + } + return true; + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::json_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/json_iterator-inl.h for westmere */ +/* including simdjson/generic/ondemand/json_type-inl.h for westmere: #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* begin file simdjson/generic/ondemand/json_type-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + inline std::ostream& operator<<(std::ostream& out, json_type type) noexcept { + switch (type) { + case json_type::array: out << "array"; break; + case json_type::object: out << "object"; break; + case json_type::number: out << "number"; break; + case json_type::string: out << "string"; break; + case json_type::boolean: out << "boolean"; break; + case json_type::null: out << "null"; break; + default: SIMDJSON_UNREACHABLE(); + } + return out; + } + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson_result& type) noexcept(false) { + return out << type.value(); + } +#endif + + + + simdjson_inline number_type number::get_number_type() const noexcept { + return type; + } + + simdjson_inline bool number::is_uint64() const noexcept { + return get_number_type() == number_type::unsigned_integer; + } + + simdjson_inline uint64_t number::get_uint64() const noexcept { + return payload.unsigned_integer; + } + + simdjson_inline number::operator uint64_t() const noexcept { + return get_uint64(); + } + + + simdjson_inline bool number::is_int64() const noexcept { + return get_number_type() == number_type::signed_integer; + } + + simdjson_inline int64_t number::get_int64() const noexcept { + return payload.signed_integer; + } + + simdjson_inline number::operator int64_t() const noexcept { + return get_int64(); + } + + simdjson_inline bool number::is_double() const noexcept { + return get_number_type() == number_type::floating_point_number; + } + + simdjson_inline double number::get_double() const noexcept { + return payload.floating_point_number; + } + + simdjson_inline number::operator double() const noexcept { + return get_double(); + } + + simdjson_inline double number::as_double() const noexcept { + if (is_double()) { + return payload.floating_point_number; + } + if (is_int64()) { + return double(payload.signed_integer); + } + return double(payload.unsigned_integer); + } + + simdjson_inline void number::append_s64(int64_t value) noexcept { + payload.signed_integer = value; + type = number_type::signed_integer; + } + + simdjson_inline void number::append_u64(uint64_t value) noexcept { + payload.unsigned_integer = value; + type = number_type::unsigned_integer; + } + + simdjson_inline void number::append_double(double value) noexcept { + payload.floating_point_number = value; + type = number_type::floating_point_number; + } + + simdjson_inline void number::skip_double() noexcept { + type = number_type::floating_point_number; + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::json_type&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_JSON_TYPE_INL_H +/* end file simdjson/generic/ondemand/json_type-inl.h for westmere */ +/* including simdjson/generic/ondemand/logger-inl.h for westmere: #include "simdjson/generic/ondemand/logger-inl.h" */ +/* begin file simdjson/generic/ondemand/logger-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/logger.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#include +#include + +namespace simdjson { + namespace westmere { + namespace ondemand { + namespace logger { + + static constexpr const char* DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------"; + static constexpr const int LOG_EVENT_LEN = 20; + static constexpr const int LOG_BUFFER_LEN = 30; + static constexpr const int LOG_SMALL_BUFFER_LEN = 10; + static int log_depth = 0; // Not threadsafe. Log only. + + // Helper to turn unprintable or newline characters into spaces + static inline char printable_char(char c) { + if (c >= 0x20) { + return c; + } + else { + return ' '; + } + } + + template + static inline std::string string_format(const std::string& format, const Args&... args) + { + SIMDJSON_PUSH_DISABLE_ALL_WARNINGS + int size_s = std::snprintf(nullptr, 0, format.c_str(), args...) + 1; + auto size = static_cast(size_s); + if (size <= 0) return std::string(); + std::unique_ptr buf(new char[size]); + std::snprintf(buf.get(), size, format.c_str(), args...); + SIMDJSON_POP_DISABLE_WARNINGS + return std::string(buf.get(), buf.get() + size - 1); + } + + static inline log_level get_log_level_from_env() + { + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe + char* lvl = getenv("SIMDJSON_LOG_LEVEL"); + SIMDJSON_POP_DISABLE_WARNINGS + if (lvl && simdjson_strcasecmp(lvl, "ERROR") == 0) { return log_level::error; } + return log_level::info; + } + + static inline log_level log_threshold() + { + static log_level threshold = get_log_level_from_env(); + return threshold; + } + + static inline bool should_log(log_level level) + { + return level >= log_threshold(); + } + + inline void log_event(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "", type, detail, log_level::info); + } + inline void log_value(const json_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_line(iter, "", type, detail, delta, depth_delta, log_level::info); + } + + inline void log_start_value(const json_iterator& iter, token_position index, depth_t depth, const char* type, std::string_view detail) noexcept { + log_line(iter, index, depth, "+", type, detail, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + inline void log_start_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_line(iter, "+", type, "", delta, depth_delta, log_level::info); + if (LOG_ENABLED) { log_depth++; } + } + + inline void log_end_value(const json_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + if (LOG_ENABLED) { log_depth--; } + log_line(iter, "-", type, "", delta, depth_delta, log_level::info); + } + + inline void log_error(const json_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_line(iter, "ERROR: ", error, detail, delta, depth_delta, log_level::error); + } + inline void log_error(const json_iterator& iter, token_position index, depth_t depth, const char* error, const char* detail) noexcept { + log_line(iter, index, depth, "ERROR: ", error, detail, log_level::error); + } + + inline void log_event(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_event(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_value(const value_iterator& iter, const char* type, std::string_view detail, int delta, int depth_delta) noexcept { + log_value(iter.json_iter(), type, detail, delta, depth_delta); + } + + inline void log_start_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_start_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_end_value(const value_iterator& iter, const char* type, int delta, int depth_delta) noexcept { + log_end_value(iter.json_iter(), type, delta, depth_delta); + } + + inline void log_error(const value_iterator& iter, const char* error, const char* detail, int delta, int depth_delta) noexcept { + log_error(iter.json_iter(), error, detail, delta, depth_delta); + } + + inline void log_headers() noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(log_level::info))) { + // Technically a static variable is not thread-safe, but if you are using threads and logging... well... + static bool displayed_hint{ false }; + log_depth = 0; + printf("\n"); + if (!displayed_hint) { + // We only print this helpful header once. + printf("# Logging provides the depth and position of the iterator user-visible steps:\n"); + printf("# +array says 'this is where we were when we discovered the start array'\n"); + printf( + "# -array says 'this is where we were when we ended the array'\n"); + printf("# skip says 'this is a structural or value I am skipping'\n"); + printf("# +/-skip says 'this is a start/end array or object I am skipping'\n"); + printf("#\n"); + printf("# The indentation of the terms (array, string,...) indicates the depth,\n"); + printf("# in addition to the depth being displayed.\n"); + printf("#\n"); + printf("# Every token in the document has a single depth determined by the tokens before it,\n"); + printf("# and is not affected by what the token actually is.\n"); + printf("#\n"); + printf("# Not all structural elements are presented as tokens in the logs.\n"); + printf("#\n"); + printf("# We never give control to the user within an empty array or an empty object.\n"); + printf("#\n"); + printf("# Inside an array, having a depth greater than the array's depth means that\n"); + printf("# we are pointing inside a value.\n"); + printf("# Having a depth equal to the array means that we are pointing right before a value.\n"); + printf("# Having a depth smaller than the array means that we have moved beyond the array.\n"); + displayed_hint = true; + } + printf("\n"); + printf("| %-*s ", LOG_EVENT_LEN, "Event"); + printf("| %-*s ", LOG_BUFFER_LEN, "Buffer"); + printf("| %-*s ", LOG_SMALL_BUFFER_LEN, "Next"); + // printf("| %-*s ", 5, "Next#"); + printf("| %-*s ", 5, "Depth"); + printf("| Detail "); + printf("|\n"); + + printf("|%.*s", LOG_EVENT_LEN + 2, DASHES); + printf("|%.*s", LOG_BUFFER_LEN + 2, DASHES); + printf("|%.*s", LOG_SMALL_BUFFER_LEN + 2, DASHES); + // printf("|%.*s", 5+2, DASHES); + printf("|%.*s", 5 + 2, DASHES); + printf("|--------"); + printf("|\n"); + fflush(stdout); + } + } + } + + template + inline void log_line(const json_iterator& iter, const char* title_prefix, const char* title, std::string_view detail, int delta, int depth_delta, log_level level, Args&&... args) noexcept { + log_line(iter, iter.position() + delta, depth_t(iter.depth() + depth_delta), title_prefix, title, detail, level, std::forward(args)...); + } + + template + inline void log_line(const json_iterator& iter, token_position index, depth_t depth, const char* title_prefix, const char* title, std::string_view detail, log_level level, Args&&... args) noexcept { + if (LOG_ENABLED) { + if (simdjson_unlikely(should_log(level))) { + const int indent = depth * 2; + const auto buf = iter.token.buf; + auto msg = string_format(title, std::forward(args)...); + printf("| %*s%s%-*s ", indent, "", title_prefix, + LOG_EVENT_LEN - indent - int(strlen(title_prefix)), msg.c_str()); + { + // Print the current structural. + printf("| "); + // Before we begin, the index might point right before the document. + // This could be unsafe, see https://github.com/simdjson/simdjson/discussions/1938 + if (index < iter._root) { + printf("%*s", LOG_BUFFER_LEN, ""); + } + else { + auto current_structural = &buf[*index]; + for (int i = 0; i < LOG_BUFFER_LEN; i++) { + printf("%c", printable_char(current_structural[i])); + } + } + printf(" "); + } + { + // Print the next structural. + printf("| "); + auto next_structural = &buf[*(index + 1)]; + for (int i = 0; i < LOG_SMALL_BUFFER_LEN; i++) { + printf("%c", printable_char(next_structural[i])); + } + printf(" "); + } + // printf("| %5u ", *(index+1)); + printf("| %5i ", depth); + printf("| %6.*s ", int(detail.size()), detail.data()); + printf("|\n"); + fflush(stdout); + } + } + } + + } // namespace logger + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_LOGGER_INL_H +/* end file simdjson/generic/ondemand/logger-inl.h for westmere */ +/* including simdjson/generic/ondemand/object-inl.h for westmere: #include "simdjson/generic/ondemand/object-inl.h" */ +/* begin file simdjson/generic/ondemand/object-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field_unordered(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_unordered_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) & noexcept { + return find_field_unordered(key); + } + simdjson_inline simdjson_result object::operator[](const std::string_view key) && noexcept { + return std::forward(*this).find_field_unordered(key); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) & noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + simdjson_inline simdjson_result object::find_field(const std::string_view key) && noexcept { + bool has_value; + SIMDJSON_TRY(iter.find_field_raw(key).get(has_value)); + if (!has_value) { + logger::log_line(iter.json_iter(), "ERROR: ", "Cannot find key %.*s", "", -1, 0, logger::log_level::error, static_cast(key.size()), key.data()); + return NO_SUCH_FIELD; + } + return value(iter.child()); + } + + simdjson_inline simdjson_result object::start(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_object().error()); + return object(iter); + } + simdjson_inline simdjson_result object::start_root(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.start_root_object().error()); + return object(iter); + } + simdjson_inline error_code object::consume() noexcept { + if (iter.is_at_key()) { + /** + * whenever you are pointing at a key, calling skip_child() is + * unsafe because you will hit a string and you will assume that + * it is string value, and this mistake will lead you to make bad + * depth computation. + */ + /** + * We want to 'consume' the key. We could really + * just do _json_iter->return_current_and_advance(); at this + * point, but, for clarity, we will use the high-level API to + * eat the key. We assume that the compiler optimizes away + * most of the work. + */ + simdjson_unused raw_json_string actual_key; + auto error = iter.field_key().get(actual_key); + if (error) { iter.abandon(); return error; }; + // Let us move to the value while we are at it. + if ((error = iter.field_value())) { iter.abandon(); return error; } + } + auto error_skip = iter.json_iter().skip_child(iter.depth() - 1); + if (error_skip) { iter.abandon(); } + return error_skip; + } + + simdjson_inline simdjson_result object::raw_json() noexcept { + const uint8_t* starting_point{ iter.peek_start() }; + auto error = consume(); + if (error) { return error; } + const uint8_t* final_point{ iter._json_iter->peek() }; + return std::string_view(reinterpret_cast(starting_point), size_t(final_point - starting_point)); + } + + simdjson_inline simdjson_result object::started(value_iterator& iter) noexcept { + SIMDJSON_TRY(iter.started_object().error()); + return object(iter); + } + + simdjson_inline object object::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline object::object(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + + simdjson_inline simdjson_result object::begin() noexcept { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!iter.is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + return object_iterator(iter); + } + simdjson_inline simdjson_result object::end() noexcept { + return object_iterator(iter); + } + + inline simdjson_result object::at_pointer(std::string_view json_pointer) noexcept { + if (json_pointer[0] != '/') { return INVALID_JSON_POINTER; } + json_pointer = json_pointer.substr(1); + size_t slash = json_pointer.find('/'); + std::string_view key = json_pointer.substr(0, slash); + // Grab the child with the given key + simdjson_result child; + + // If there is an escape character in the key, unescape it and then get the child. + size_t escape = key.find('~'); + if (escape != std::string_view::npos) { + // Unescape the key + std::string unescaped(key); + do { + switch (unescaped[escape + 1]) { + case '0': + unescaped.replace(escape, 2, "~"); + break; + case '1': + unescaped.replace(escape, 2, "/"); + break; + default: + return INVALID_JSON_POINTER; // "Unexpected ~ escape character in JSON pointer"); + } + escape = unescaped.find('~', escape + 1); + } while (escape != std::string::npos); + child = find_field(unescaped); // Take note find_field does not unescape keys when matching + } + else { + child = find_field(key); + } + if (child.error()) { + return child; // we do not continue if there was an error + } + // If there is a /, we have to recurse and look up more of the path + if (slash != std::string_view::npos) { + child = child.at_pointer(json_pointer.substr(slash)); + } + return child; + } + + simdjson_inline simdjson_result object::count_fields() & noexcept { + size_t count{ 0 }; + // Important: we do not consume any of the values. + for (simdjson_unused auto v : *this) { count++; } + // The above loop will always succeed, but we want to report errors. + if (iter.error()) { return iter.error(); } + // We need to move back at the start because we expect users to iterate through + // the object after counting the number of elements. + iter.reset_object(); + return count; + } + + simdjson_inline simdjson_result object::is_empty() & noexcept { + bool is_not_empty; + auto error = iter.reset_object().get(is_not_empty); + if (error) { return error; } + return !is_not_empty; + } + + simdjson_inline simdjson_result object::reset() & noexcept { + return iter.reset_object(); + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::object&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::begin() noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() noexcept { + if (error()) { return error(); } + return first.end(); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) & noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first)[key]; + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) & noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) && noexcept { + if (error()) { return error(); } + return std::forward(first).find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + + inline simdjson_result simdjson_result::reset() noexcept { + if (error()) { return error(); } + return first.reset(); + } + + inline simdjson_result simdjson_result::is_empty() noexcept { + if (error()) { return error(); } + return first.is_empty(); + } + + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_INL_H +/* end file simdjson/generic/ondemand/object-inl.h for westmere */ +/* including simdjson/generic/ondemand/object_iterator-inl.h for westmere: #include "simdjson/generic/ondemand/object_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/object_iterator-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/field-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + // + // object_iterator + // + + simdjson_inline object_iterator::object_iterator(const value_iterator& _iter) noexcept + : iter{ _iter } + {} + + simdjson_inline simdjson_result object_iterator::operator*() noexcept { + error_code error = iter.error(); + if (error) { iter.abandon(); return error; } + auto result = field::start(iter); + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (result.error()) { iter.abandon(); } + return result; + } + simdjson_inline bool object_iterator::operator==(const object_iterator& other) const noexcept { + return !(*this != other); + } + simdjson_inline bool object_iterator::operator!=(const object_iterator&) const noexcept { + return iter.is_open(); + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline object_iterator& object_iterator::operator++() noexcept { + // TODO this is a safety rail ... users should exit loops as soon as they receive an error. + // Nonetheless, let's see if performance is OK with this if statement--the compiler may give it to us for free. + if (!iter.is_open()) { return *this; } // Iterator will be released if there is an error + + simdjson_unused error_code error; + if ((error = iter.skip_child())) { return *this; } + + simdjson_unused bool has_value; + if ((error = iter.has_next_field().get(has_value))) { return *this; }; + return *this; + } + SIMDJSON_POP_DISABLE_WARNINGS + + // + // ### Live States + // + // While iterating or looking up values, depth >= iter.depth. at_start may vary. Error is + // always SUCCESS: + // + // - Start: This is the state when the object is first found and the iterator is just past the {. + // In this state, at_start == true. + // - Next: After we hand a scalar value to the user, or an array/object which they then fully + // iterate over, the iterator is at the , or } before the next value. In this state, + // depth == iter.depth, at_start == false, and error == SUCCESS. + // - Unfinished Business: When we hand an array/object to the user which they do not fully + // iterate over, we need to finish that iteration by skipping child values until we reach the + // Next state. In this state, depth > iter.depth, at_start == false, and error == SUCCESS. + // + // ## Error States + // + // In error states, we will yield exactly one more value before stopping. iter.depth == depth + // and at_start is always false. We decrement after yielding the error, moving to the Finished + // state. + // + // - Chained Error: When the object iterator is part of an error chain--for example, in + // `for (auto tweet : doc["tweets"])`, where the tweet field may be missing or not be an + // object--we yield that error in the loop, exactly once. In this state, error != SUCCESS and + // iter.depth == depth, and at_start == false. We decrement depth when we yield the error. + // - Missing Comma Error: When the iterator ++ method discovers there is no comma between fields, + // we flag that as an error and treat it exactly the same as a Chained Error. In this state, + // error == TAPE_ERROR, iter.depth == depth, and at_start == false. + // + // Errors that occur while reading a field to give to the user (such as when the key is not a + // string or the field is missing a colon) are yielded immediately. Depth is then decremented, + // moving to the Finished state without transitioning through an Error state at all. + // + // ## Terminal State + // + // The terminal state has iter.depth < depth. at_start is always false. + // + // - Finished: When we have reached a }, we are finished. We signal this by decrementing depth. + // In this state, iter.depth < depth, at_start == false, and error == SUCCESS. + // + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + westmere::ondemand::object_iterator&& value + ) noexcept + : implementation_simdjson_result_base(std::forward(value)) + { + first.iter.assert_is_valid(); + } + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base({}, error) + { + } + + simdjson_inline simdjson_result simdjson_result::operator*() noexcept { + if (error()) { return error(); } + return *first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator==(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return !error(); } + return first == other.first; + } + // If we're iterating and there is an error, return the error once. + simdjson_inline bool simdjson_result::operator!=(const simdjson_result& other) const noexcept { + if (!first.iter.is_valid()) { return error(); } + return first != other.first; + } + // Checks for ']' and ',' + simdjson_inline simdjson_result& simdjson_result::operator++() noexcept { + // Clear the error if there is one, so we don't yield it twice + if (error()) { second = SUCCESS; return *this; } + ++first; + return *this; + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_OBJECT_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/object_iterator-inl.h for westmere */ +/* including simdjson/generic/ondemand/parser-inl.h for westmere: #include "simdjson/generic/ondemand/parser-inl.h" */ +/* begin file simdjson/generic/ondemand/parser-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/padded_string_view.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/internal/dom_parser_implementation.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/dom/base.h" // for MINIMAL_DOCUMENT_CAPACITY */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document_stream.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/parser.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline parser::parser(size_t max_capacity) noexcept + : _max_capacity{ max_capacity } { + } + + simdjson_warn_unused simdjson_inline error_code parser::allocate(size_t new_capacity, size_t new_max_depth) noexcept { + if (new_capacity > max_capacity()) { return CAPACITY; } + if (string_buf && new_capacity == capacity() && new_max_depth == max_depth()) { return SUCCESS; } + + // string_capacity copied from document::allocate + _capacity = 0; + size_t string_capacity = SIMDJSON_ROUNDUP_N(5 * new_capacity / 3 + SIMDJSON_PADDING, 64); + string_buf.reset(new (std::nothrow) uint8_t[string_capacity]); +#if SIMDJSON_DEVELOPMENT_CHECKS + start_positions.reset(new (std::nothrow) token_position[new_max_depth]); +#endif + if (implementation) { + SIMDJSON_TRY(implementation->set_capacity(new_capacity)); + SIMDJSON_TRY(implementation->set_max_depth(new_max_depth)); + } + else { + SIMDJSON_TRY(simdjson::get_active_implementation()->create_dom_parser_implementation(new_capacity, new_max_depth, implementation)); + } + _capacity = new_capacity; + _max_depth = new_max_depth; + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length() || !string_buf) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return document::start({ reinterpret_cast(json.data()), this }); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const char* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const uint8_t* json, size_t len, size_t allocated) & noexcept { + return iterate(padded_string_view(json, len, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string_view json, size_t allocated) & noexcept { + return iterate(padded_string_view(json, allocated)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(std::string& json) & noexcept { + if (json.capacity() - json.size() < SIMDJSON_PADDING) { + json.reserve(json.size() + SIMDJSON_PADDING); + } + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const std::string& json) & noexcept { + return iterate(padded_string_view(json)); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + padded_string_view json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate(const simdjson_result& result) & noexcept { + // We don't presently have a way to temporarily get a const T& from a simdjson_result without throwing an exception + SIMDJSON_TRY(result.error()); + const padded_string& json = result.value_unsafe(); + return iterate(json); + } + + simdjson_warn_unused simdjson_inline simdjson_result parser::iterate_raw(padded_string_view json) & noexcept { + if (json.padding() < SIMDJSON_PADDING) { return INSUFFICIENT_PADDING; } + + json.remove_utf8_bom(); + + // Allocate if needed + if (capacity() < json.length()) { + SIMDJSON_TRY(allocate(json.length(), max_depth())); + } + + // Run stage 1. + SIMDJSON_TRY(implementation->stage1(reinterpret_cast(json.data()), json.length(), stage1_mode::regular)); + return json_iterator(reinterpret_cast(json.data()), this); + } + + inline simdjson_result parser::iterate_many(const uint8_t* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + if (batch_size < MINIMAL_BATCH_SIZE) { batch_size = MINIMAL_BATCH_SIZE; } + if ((len >= 3) && (std::memcmp(buf, "\xEF\xBB\xBF", 3) == 0)) { + buf += 3; + len -= 3; + } + if (allow_comma_separated && batch_size < len) { batch_size = len; } + return document_stream(*this, buf, len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const char* buf, size_t len, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(reinterpret_cast(buf), len, batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const std::string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + inline simdjson_result parser::iterate_many(const padded_string& s, size_t batch_size, bool allow_comma_separated) noexcept { + return iterate_many(s.data(), s.length(), batch_size, allow_comma_separated); + } + + simdjson_inline size_t parser::capacity() const noexcept { + return _capacity; + } + simdjson_inline size_t parser::max_capacity() const noexcept { + return _max_capacity; + } + simdjson_inline size_t parser::max_depth() const noexcept { + return _max_depth; + } + + simdjson_inline void parser::set_max_capacity(size_t max_capacity) noexcept { + if (max_capacity < dom::MINIMAL_DOCUMENT_CAPACITY) { + _max_capacity = max_capacity; + } + else { + _max_capacity = dom::MINIMAL_DOCUMENT_CAPACITY; + } + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape(raw_json_string in, uint8_t*& dst, bool allow_replacement) const noexcept { + uint8_t* end = implementation->parse_string(in.buf, dst, allow_replacement); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + simdjson_inline simdjson_warn_unused simdjson_result parser::unescape_wobbly(raw_json_string in, uint8_t*& dst) const noexcept { + uint8_t* end = implementation->parse_wobbly_string(in.buf, dst); + if (!end) { return STRING_ERROR; } + std::string_view result(reinterpret_cast(dst), end - dst); + dst = end; + return result; + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::parser&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_PARSER_INL_H +/* end file simdjson/generic/ondemand/parser-inl.h for westmere */ +/* including simdjson/generic/ondemand/raw_json_string-inl.h for westmere: #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* begin file simdjson/generic/ondemand/raw_json_string-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + namespace westmere { + namespace ondemand { + + simdjson_inline raw_json_string::raw_json_string(const uint8_t* _buf) noexcept : buf{ _buf } {} + + simdjson_inline const char* raw_json_string::raw() const noexcept { return reinterpret_cast(buf); } + + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(std::string_view target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; pos < target.size() && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + simdjson_inline bool raw_json_string::is_free_from_unescaped_quote(const char* target) noexcept { + size_t pos{ 0 }; + // if the content has no escape character, just scan through it quickly! + for (; target[pos] && target[pos] != '\\'; pos++) {} + // slow path may begin. + bool escaping{ false }; + for (; target[pos]; pos++) { + if ((target[pos] == '"') && !escaping) { + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(size_t length, std::string_view target) const noexcept { + // If we are going to call memcmp, then we must know something about the length of the raw_json_string. + return (length >= target.size()) && (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + + simdjson_inline bool raw_json_string::unsafe_is_equal(std::string_view target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + if (target.size() <= SIMDJSON_PADDING) { + return (raw()[target.size()] == '"') && !memcmp(raw(), target.data(), target.size()); + } + const char* r{ raw() }; + size_t pos{ 0 }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(std::string_view target) const noexcept { + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; pos < target.size(); pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + + simdjson_inline bool raw_json_string::unsafe_is_equal(const char* target) const noexcept { + // Assumptions: 'target' does not contain unescaped quote characters, is null terminated and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_inline bool raw_json_string::is_equal(const char* target) const noexcept { + // Assumptions: does not contain unescaped quote characters, and + // the raw content is quote terminated within a valid JSON string. + const char* r{ raw() }; + size_t pos{ 0 }; + bool escaping{ false }; + for (; target[pos]; pos++) { + if (r[pos] != target[pos]) { return false; } + // if target is a compile-time constant and it is free from + // quotes, then the next part could get optimized away through + // inlining. + if ((target[pos] == '"') && !escaping) { + // We have reached the end of the raw_json_string but + // the target is not done. + return false; + } + else if (target[pos] == '\\') { + escaping = !escaping; + } + else { + escaping = false; + } + } + if (r[pos] != '"') { return false; } + return true; + } + + simdjson_unused simdjson_inline bool operator==(const raw_json_string& a, std::string_view c) noexcept { + return a.unsafe_is_equal(c); + } + + simdjson_unused simdjson_inline bool operator==(std::string_view c, const raw_json_string& a) noexcept { + return a == c; + } + + simdjson_unused simdjson_inline bool operator!=(const raw_json_string& a, std::string_view c) noexcept { + return !(a == c); + } + + simdjson_unused simdjson_inline bool operator!=(std::string_view c, const raw_json_string& a) noexcept { + return !(a == c); + } + + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape(json_iterator& iter, bool allow_replacement) const noexcept { + return iter.unescape(*this, allow_replacement); + } + + simdjson_inline simdjson_warn_unused simdjson_result raw_json_string::unescape_wobbly(json_iterator& iter) const noexcept { + return iter.unescape_wobbly(*this); + } + + simdjson_unused simdjson_inline std::ostream& operator<<(std::ostream& out, const raw_json_string& str) noexcept { + bool in_escape = false; + const char* s = str.raw(); + while (true) { + switch (*s) { + case '\\': in_escape = !in_escape; break; + case '"': if (in_escape) { in_escape = false; } + else { return out; } break; + default: if (in_escape) { in_escape = false; } + } + out << *s; + s++; + } + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::raw_json_string&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + + simdjson_inline simdjson_result simdjson_result::raw() const noexcept { + if (error()) { return error(); } + return first.raw(); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape(westmere::ondemand::json_iterator& iter, bool allow_replacement) const noexcept { + if (error()) { return error(); } + return first.unescape(iter, allow_replacement); + } + simdjson_inline simdjson_warn_unused simdjson_result simdjson_result::unescape_wobbly(westmere::ondemand::json_iterator& iter) const noexcept { + if (error()) { return error(); } + return first.unescape_wobbly(iter); + } +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_RAW_JSON_STRING_INL_H +/* end file simdjson/generic/ondemand/raw_json_string-inl.h for westmere */ +/* including simdjson/generic/ondemand/serialization-inl.h for westmere: #include "simdjson/generic/ondemand/serialization-inl.h" */ +/* begin file simdjson/generic/ondemand/serialization-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/document-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/serialization.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + + inline std::string_view trim(const std::string_view str) noexcept { + // We can almost surely do better by rolling our own find_first_not_of function. + size_t first = str.find_first_not_of(" \t\n\r"); + // If we have the empty string (just white space), then no trimming is possible, and + // we return the empty string_view. + if (std::string_view::npos == first) { return std::string_view(); } + size_t last = str.find_last_not_of(" \t\n\r"); + return str.substr(first, (last - first + 1)); + } + + + inline simdjson_result to_json_string(westmere::ondemand::document& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(westmere::ondemand::document_reference& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(westmere::ondemand::value& x) noexcept { + /** + * If we somehow receive a value that has already been consumed, + * then the following code could be in trouble. E.g., we create + * an array as needed, but if an array was already created, then + * it could be bad. + */ + using namespace westmere::ondemand; + westmere::ondemand::json_type t; + auto error = x.type().get(t); + if (error != SUCCESS) { return error; } + switch (t) + { + case json_type::array: + { + westmere::ondemand::array array; + error = x.get_array().get(array); + if (error) { return error; } + return to_json_string(array); + } + case json_type::object: + { + westmere::ondemand::object object; + error = x.get_object().get(object); + if (error) { return error; } + return to_json_string(object); + } + default: + return trim(x.raw_json_token()); + } + } + + inline simdjson_result to_json_string(westmere::ondemand::object& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(westmere::ondemand::array& x) noexcept { + std::string_view v; + auto error = x.raw_json().get(v); + if (error) { return error; } + return trim(v); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } + + inline simdjson_result to_json_string(simdjson_result x) { + if (x.error()) { return x.error(); } + return to_json_string(x.value_unsafe()); + } +} // namespace simdjson + +namespace simdjson { + namespace westmere { + namespace ondemand { + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::value x) { + std::string_view v; + auto error = simdjson::to_json_string(x).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::array value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::document_reference& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result&& x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::document& value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + +#if SIMDJSON_EXCEPTIONS + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + throw simdjson::simdjson_error(error); + } + } + inline std::ostream& operator<<(std::ostream& out, simdjson::simdjson_result x) { + if (x.error()) { throw simdjson::simdjson_error(x.error()); } + return (out << x.value()); + } +#else + inline std::ostream& operator<<(std::ostream& out, simdjson::westmere::ondemand::object value) { + std::string_view v; + auto error = simdjson::to_json_string(value).get(v); + if (error == simdjson::SUCCESS) { + return (out << v); + } + else { + return (out << error); + } + } +#endif + } + } +} // namespace simdjson::westmere::ondemand + +#endif // SIMDJSON_GENERIC_ONDEMAND_SERIALIZATION_INL_H +/* end file simdjson/generic/ondemand/serialization-inl.h for westmere */ +/* including simdjson/generic/ondemand/token_iterator-inl.h for westmere: #include "simdjson/generic/ondemand/token_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/token_iterator-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/token_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/implementation_simdjson_result_base-inl.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline token_iterator::token_iterator( + const uint8_t* _buf, + token_position position + ) noexcept : buf{ _buf }, _position{ position } + { + } + + simdjson_inline uint32_t token_iterator::current_offset() const noexcept { + return *(_position); + } + + + simdjson_inline const uint8_t* token_iterator::return_current_and_advance() noexcept { + return &buf[*(_position++)]; + } + + simdjson_inline const uint8_t* token_iterator::peek(token_position position) const noexcept { + return &buf[*position]; + } + simdjson_inline uint32_t token_iterator::peek_index(token_position position) const noexcept { + return *position; + } + simdjson_inline uint32_t token_iterator::peek_length(token_position position) const noexcept { + return *(position + 1) - *position; + } + + simdjson_inline const uint8_t* token_iterator::peek(int32_t delta) const noexcept { + return &buf[*(_position + delta)]; + } + simdjson_inline uint32_t token_iterator::peek_index(int32_t delta) const noexcept { + return *(_position + delta); + } + simdjson_inline uint32_t token_iterator::peek_length(int32_t delta) const noexcept { + return *(_position + delta + 1) - *(_position + delta); + } + + simdjson_inline token_position token_iterator::position() const noexcept { + return _position; + } + simdjson_inline void token_iterator::set_position(token_position target_position) noexcept { + _position = target_position; + } + + simdjson_inline bool token_iterator::operator==(const token_iterator& other) const noexcept { + return _position == other._position; + } + simdjson_inline bool token_iterator::operator!=(const token_iterator& other) const noexcept { + return _position != other._position; + } + simdjson_inline bool token_iterator::operator>(const token_iterator& other) const noexcept { + return _position > other._position; + } + simdjson_inline bool token_iterator::operator>=(const token_iterator& other) const noexcept { + return _position >= other._position; + } + simdjson_inline bool token_iterator::operator<(const token_iterator& other) const noexcept { + return _position < other._position; + } + simdjson_inline bool token_iterator::operator<=(const token_iterator& other) const noexcept { + return _position <= other._position; + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::token_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_TOKEN_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/token_iterator-inl.h for westmere */ +/* including simdjson/generic/ondemand/value-inl.h for westmere: #include "simdjson/generic/ondemand/value-inl.h" */ +/* begin file simdjson/generic/ondemand/value-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/array_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/object.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline value::value(const value_iterator& _iter) noexcept + : iter{ _iter } + { + } + simdjson_inline value value::start(const value_iterator& iter) noexcept { + return iter; + } + simdjson_inline value value::resume(const value_iterator& iter) noexcept { + return iter; + } + + simdjson_inline simdjson_result value::get_array() noexcept { + return array::start(iter); + } + simdjson_inline simdjson_result value::get_object() noexcept { + return object::start(iter); + } + simdjson_inline simdjson_result value::start_or_resume_object() noexcept { + if (iter.at_start()) { + return get_object(); + } + else { + return object::resume(iter); + } + } + + simdjson_inline simdjson_result value::get_raw_json_string() noexcept { + return iter.get_raw_json_string(); + } + simdjson_inline simdjson_result value::get_string(bool allow_replacement) noexcept { + return iter.get_string(allow_replacement); + } + template + simdjson_inline error_code value::get_string(string_type& receiver, bool allow_replacement) noexcept { + return iter.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result value::get_wobbly_string() noexcept { + return iter.get_wobbly_string(); + } + simdjson_inline simdjson_result value::get_double() noexcept { + return iter.get_double(); + } + simdjson_inline simdjson_result value::get_double_in_string() noexcept { + return iter.get_double_in_string(); + } + simdjson_inline simdjson_result value::get_uint64() noexcept { + return iter.get_uint64(); + } + simdjson_inline simdjson_result value::get_uint64_in_string() noexcept { + return iter.get_uint64_in_string(); + } + simdjson_inline simdjson_result value::get_int64() noexcept { + return iter.get_int64(); + } + simdjson_inline simdjson_result value::get_int64_in_string() noexcept { + return iter.get_int64_in_string(); + } + simdjson_inline simdjson_result value::get_bool() noexcept { + return iter.get_bool(); + } + simdjson_inline simdjson_result value::is_null() noexcept { + return iter.is_null(); + } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_array(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_object(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_raw_json_string(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_string(false); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_number(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_double(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_uint64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_int64(); } + template<> simdjson_inline simdjson_result value::get() noexcept { return get_bool(); } + + template simdjson_inline error_code value::get(T& out) noexcept { + return get().get(out); + } + +#if SIMDJSON_EXCEPTIONS + simdjson_inline value::operator array() noexcept(false) { + return get_array(); + } + simdjson_inline value::operator object() noexcept(false) { + return get_object(); + } + simdjson_inline value::operator uint64_t() noexcept(false) { + return get_uint64(); + } + simdjson_inline value::operator int64_t() noexcept(false) { + return get_int64(); + } + simdjson_inline value::operator double() noexcept(false) { + return get_double(); + } + simdjson_inline value::operator std::string_view() noexcept(false) { + return get_string(false); + } + simdjson_inline value::operator raw_json_string() noexcept(false) { + return get_raw_json_string(); + } + simdjson_inline value::operator bool() noexcept(false) { + return get_bool(); + } +#endif + + simdjson_inline simdjson_result value::begin() & noexcept { + return get_array().begin(); + } + simdjson_inline simdjson_result value::end() & noexcept { + return {}; + } + simdjson_inline simdjson_result value::count_elements() & noexcept { + simdjson_result answer; + auto a = get_array(); + answer = a.count_elements(); + // count_elements leaves you pointing inside the array, at the first element. + // We need to move back so that the user can create a new array (which requires that + // we point at '['). + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::count_fields() & noexcept { + simdjson_result answer; + auto a = get_object(); + answer = a.count_fields(); + iter.move_at_start(); + return answer; + } + simdjson_inline simdjson_result value::at(size_t index) noexcept { + auto a = get_array(); + return a.at(index); + } + + simdjson_inline simdjson_result value::find_field(std::string_view key) noexcept { + return start_or_resume_object().find_field(key); + } + simdjson_inline simdjson_result value::find_field(const char* key) noexcept { + return start_or_resume_object().find_field(key); + } + + simdjson_inline simdjson_result value::find_field_unordered(std::string_view key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + simdjson_inline simdjson_result value::find_field_unordered(const char* key) noexcept { + return start_or_resume_object().find_field_unordered(key); + } + + simdjson_inline simdjson_result value::operator[](std::string_view key) noexcept { + return start_or_resume_object()[key]; + } + simdjson_inline simdjson_result value::operator[](const char* key) noexcept { + return start_or_resume_object()[key]; + } + + simdjson_inline simdjson_result value::type() noexcept { + return iter.type(); + } + + simdjson_inline simdjson_result value::is_scalar() noexcept { + json_type this_type; + auto error = type().get(this_type); + if (error) { return error; } + return !((this_type == json_type::array) || (this_type == json_type::object)); + } + + simdjson_inline bool value::is_negative() noexcept { + return iter.is_negative(); + } + + simdjson_inline simdjson_result value::is_integer() noexcept { + return iter.is_integer(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number_type() noexcept { + return iter.get_number_type(); + } + simdjson_warn_unused simdjson_inline simdjson_result value::get_number() noexcept { + return iter.get_number(); + } + + simdjson_inline std::string_view value::raw_json_token() noexcept { + return std::string_view(reinterpret_cast(iter.peek_start()), iter.peek_start_length()); + } + + simdjson_inline simdjson_result value::raw_json() noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: { + ondemand::array array; + SIMDJSON_TRY(get_array().get(array)); + return array.raw_json(); + } + case json_type::object: { + ondemand::object object; + SIMDJSON_TRY(get_object().get(object)); + return object.raw_json(); + } + default: + return raw_json_token(); + } + } + + simdjson_inline simdjson_result value::current_location() noexcept { + return iter.json_iter().current_location(); + } + + simdjson_inline int32_t value::current_depth() const noexcept { + return iter.json_iter().depth(); + } + + simdjson_inline simdjson_result value::at_pointer(std::string_view json_pointer) noexcept { + json_type t; + SIMDJSON_TRY(type().get(t)); + switch (t) + { + case json_type::array: + return (*this).get_array().at_pointer(json_pointer); + case json_type::object: + return (*this).get_object().at_pointer(json_pointer); + default: + return INVALID_JSON_POINTER; + } + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result( + westmere::ondemand::value&& value + ) noexcept : + implementation_simdjson_result_base( + std::forward(value) + ) + { + } + simdjson_inline simdjson_result::simdjson_result( + error_code error + ) noexcept : + implementation_simdjson_result_base(error) + { + } + simdjson_inline simdjson_result simdjson_result::count_elements() & noexcept { + if (error()) { return error(); } + return first.count_elements(); + } + simdjson_inline simdjson_result simdjson_result::count_fields() & noexcept { + if (error()) { return error(); } + return first.count_fields(); + } + simdjson_inline simdjson_result simdjson_result::at(size_t index) noexcept { + if (error()) { return error(); } + return first.at(index); + } + simdjson_inline simdjson_result simdjson_result::begin() & noexcept { + if (error()) { return error(); } + return first.begin(); + } + simdjson_inline simdjson_result simdjson_result::end() & noexcept { + if (error()) { return error(); } + return {}; + } + + simdjson_inline simdjson_result simdjson_result::find_field(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + simdjson_inline simdjson_result simdjson_result::find_field(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field(key); + } + + simdjson_inline simdjson_result simdjson_result::find_field_unordered(std::string_view key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + simdjson_inline simdjson_result simdjson_result::find_field_unordered(const char* key) noexcept { + if (error()) { return error(); } + return first.find_field_unordered(key); + } + + simdjson_inline simdjson_result simdjson_result::operator[](std::string_view key) noexcept { + if (error()) { return error(); } + return first[key]; + } + simdjson_inline simdjson_result simdjson_result::operator[](const char* key) noexcept { + if (error()) { return error(); } + return first[key]; + } + + simdjson_inline simdjson_result simdjson_result::get_array() noexcept { + if (error()) { return error(); } + return first.get_array(); + } + simdjson_inline simdjson_result simdjson_result::get_object() noexcept { + if (error()) { return error(); } + return first.get_object(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64() noexcept { + if (error()) { return error(); } + return first.get_uint64(); + } + simdjson_inline simdjson_result simdjson_result::get_uint64_in_string() noexcept { + if (error()) { return error(); } + return first.get_uint64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_int64() noexcept { + if (error()) { return error(); } + return first.get_int64(); + } + simdjson_inline simdjson_result simdjson_result::get_int64_in_string() noexcept { + if (error()) { return error(); } + return first.get_int64_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_double() noexcept { + if (error()) { return error(); } + return first.get_double(); + } + simdjson_inline simdjson_result simdjson_result::get_double_in_string() noexcept { + if (error()) { return error(); } + return first.get_double_in_string(); + } + simdjson_inline simdjson_result simdjson_result::get_string(bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(allow_replacement); + } + template + simdjson_inline error_code simdjson_result::get_string(string_type& receiver, bool allow_replacement) noexcept { + if (error()) { return error(); } + return first.get_string(receiver, allow_replacement); + } + simdjson_inline simdjson_result simdjson_result::get_wobbly_string() noexcept { + if (error()) { return error(); } + return first.get_wobbly_string(); + } + simdjson_inline simdjson_result simdjson_result::get_raw_json_string() noexcept { + if (error()) { return error(); } + return first.get_raw_json_string(); + } + simdjson_inline simdjson_result simdjson_result::get_bool() noexcept { + if (error()) { return error(); } + return first.get_bool(); + } + simdjson_inline simdjson_result simdjson_result::is_null() noexcept { + if (error()) { return error(); } + return first.is_null(); + } + + template simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return first.get(); + } + template simdjson_inline error_code simdjson_result::get(T& out) noexcept { + if (error()) { return error(); } + return first.get(out); + } + + template<> simdjson_inline simdjson_result simdjson_result::get() noexcept { + if (error()) { return error(); } + return std::move(first); + } + template<> simdjson_inline error_code simdjson_result::get(westmere::ondemand::value& out) noexcept { + if (error()) { return error(); } + out = first; + return SUCCESS; + } + + simdjson_inline simdjson_result simdjson_result::type() noexcept { + if (error()) { return error(); } + return first.type(); + } + simdjson_inline simdjson_result simdjson_result::is_scalar() noexcept { + if (error()) { return error(); } + return first.is_scalar(); + } + simdjson_inline simdjson_result simdjson_result::is_negative() noexcept { + if (error()) { return error(); } + return first.is_negative(); + } + simdjson_inline simdjson_result simdjson_result::is_integer() noexcept { + if (error()) { return error(); } + return first.is_integer(); + } + simdjson_inline simdjson_result simdjson_result::get_number_type() noexcept { + if (error()) { return error(); } + return first.get_number_type(); + } + simdjson_inline simdjson_result simdjson_result::get_number() noexcept { + if (error()) { return error(); } + return first.get_number(); + } +#if SIMDJSON_EXCEPTIONS + simdjson_inline simdjson_result::operator westmere::ondemand::array() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::object() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator uint64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator int64_t() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator double() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator std::string_view() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator westmere::ondemand::raw_json_string() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } + simdjson_inline simdjson_result::operator bool() noexcept(false) { + if (error()) { throw simdjson_error(error()); } + return first; + } +#endif + + simdjson_inline simdjson_result simdjson_result::raw_json_token() noexcept { + if (error()) { return error(); } + return first.raw_json_token(); + } + + simdjson_inline simdjson_result simdjson_result::raw_json() noexcept { + if (error()) { return error(); } + return first.raw_json(); + } + + simdjson_inline simdjson_result simdjson_result::current_location() noexcept { + if (error()) { return error(); } + return first.current_location(); + } + + simdjson_inline simdjson_result simdjson_result::current_depth() const noexcept { + if (error()) { return error(); } + return first.current_depth(); + } + + simdjson_inline simdjson_result simdjson_result::at_pointer(std::string_view json_pointer) noexcept { + if (error()) { return error(); } + return first.at_pointer(json_pointer); + } + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_INL_H +/* end file simdjson/generic/ondemand/value-inl.h for westmere */ +/* including simdjson/generic/ondemand/value_iterator-inl.h for westmere: #include "simdjson/generic/ondemand/value_iterator-inl.h" */ +/* begin file simdjson/generic/ondemand/value_iterator-inl.h for westmere */ +#ifndef SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H + +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #define SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/base.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/atomparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/numberparsing.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_iterator.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/json_type-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/raw_json_string-inl.h" */ +/* amalgamation skipped (editor-only): #include "simdjson/generic/ondemand/value_iterator.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +namespace simdjson { + namespace westmere { + namespace ondemand { + + simdjson_inline value_iterator::value_iterator( + json_iterator* json_iter, + depth_t depth, + token_position start_position + ) noexcept : _json_iter{ json_iter }, _depth{ depth }, _start_position{ start_position } + { + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_object() noexcept { + SIMDJSON_TRY(start_container('{', "Not an object", "object")); + return started_root_object(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_object() noexcept { + assert_at_container_start(); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + if (*_json_iter->peek() == '}') { + logger::log_value(*_json_iter, "empty object"); + _json_iter->return_current_and_advance(); + end_container(); + return false; + } + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_object() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // object: e.g., `{"a":2} foo }`. Users concerned with garbage content should + // call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != '}') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing } at end"); + } + // If the last character is } *and* the first gibberish character is also '}' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == '}') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed object. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_object() noexcept { + auto error = check_root_object(); + if (error) { return error; } + return started_object(); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::end_container() noexcept { +#if SIMDJSON_CHECK_EOF + if (depth() > 1 && at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing parent ] or }"); } + // if (depth() <= 1 && !at_end()) { return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing [ or { at start"); } +#endif // SIMDJSON_CHECK_EOF + _json_iter->ascend_to(depth() - 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_field() noexcept { + assert_at_next(); + + // It's illegal to call this unless there are more tokens: anything that ends in } or ] is + // obligated to verify there are more tokens if they are not the top level. + switch (*_json_iter->return_current_and_advance()) { + case '}': + logger::log_end_value(*_json_iter, "object"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between object fields"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_raw(const std::string_view key) noexcept { + error_code error; + bool has_value; + // + // Initially, the object can be in one of a few different places: + // + // 1. The start of the object, at the first field: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + if (at_first_field()) { + has_value = true; + + // + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + return false; + + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + if ((error = skip_child())) { abandon(); return error; } + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + while (has_value) { + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + //if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); // Skip the value entirely + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + + // If the loop ended, we're out of fields to look at. + return false; + } + + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::find_field_unordered_raw(const std::string_view key) noexcept { + /** + * When find_field_unordered_raw is called, we can either be pointing at the + * first key, pointing outside (at the closing brace) or if a key was matched + * we can be either pointing right afterthe ':' right before the value (that we need skip), + * or we may have consumed the value and we might be at a comma or at the + * final brace (ready for a call to has_next_field()). + */ + error_code error; + bool has_value; + + // First, we scan from that point to the end. + // If we don't find a match, we may loop back around, and scan from the beginning to that point. + token_position search_start = _json_iter->position(); + + // We want to know whether we need to go back to the beginning. + bool at_first = at_first_field(); + /////////////// + // Initially, the object can be in one of a few different places: + // + // 1. At the first key: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2, index 1) + // ``` + // + if (at_first) { + has_value = true; + + // 2. When a previous search did not yield a value or the object is empty: + // + // ``` + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // { } + // ^ (depth 0, index 2) + // ``` + // + } + else if (!is_open()) { + +#if SIMDJSON_DEVELOPMENT_CHECKS + // If we're past the end of the object, we're being iterated out of order. + // Note: this isn't perfect detection. It's possible the user is inside some other object; if so, + // this object iterator will blithely scan that object for fields. + if (_json_iter->depth() < depth() - 1) { return OUT_OF_ORDER_ITERATION; } +#endif + SIMDJSON_TRY(reset_object().get(has_value)); + at_first = true; + // 3. When a previous search found a field or an iterator yielded a value: + // + // ``` + // // When a field was not fully consumed (or not even touched at all) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 2) + // // When a field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // When the last field was fully consumed + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // ``` + // + } + else { + // If someone queried a key but they not did access the value, then we are left pointing + // at the ':' and we need to move forward through the value... If the value was + // processed then skip_child() does not move the iterator (but may adjust the depth). + if ((error = skip_child())) { abandon(); return error; } + search_start = _json_iter->position(); + if ((error = has_next_field().get(has_value))) { abandon(); return error; } +#if SIMDJSON_DEVELOPMENT_CHECKS + if (_json_iter->start_position(_depth) != start_position()) { return OUT_OF_ORDER_ITERATION; } +#endif + } + + // After initial processing, we will be in one of two states: + // + // ``` + // // At the beginning of a field + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 1) + // // At the end of the object + // { "a": [ 1, 2 ], "b": [ 3, 4 ] } + // ^ (depth 0) + // ``` + // + // Next, we find a match starting from the current position. + while (has_value) { + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + if ((error = field_key().get(actual_key))) { abandon(); return error; }; + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + if ((error = field_value())) { abandon(); return error; } + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + if ((error = has_next_field().get(has_value))) { abandon(); return error; } + } + // Performance note: it maybe wasteful to rewind to the beginning when there might be + // no other query following. Indeed, it would require reskipping the whole object. + // Instead, you can just stay where you are. If there is a new query, there is always time + // to rewind. + if (at_first) { return false; } + + // If we reach the end without finding a match, search the rest of the fields starting at the + // beginning of the object. + // (We have already run through the object before, so we've already validated its structure. We + // don't check errors in this bit.) + SIMDJSON_TRY(reset_object().get(has_value)); + while (true) { + SIMDJSON_ASSUME(has_value); // we should reach search_start before ever reaching the end of the object + SIMDJSON_ASSUME(_json_iter->_depth == _depth); // We must be at the start of a field + + // Get the key and colon, stopping at the value. + raw_json_string actual_key; + // size_t max_key_length = _json_iter->peek_length() - 2; // -2 for the two quotes + // Note: _json_iter->peek_length() - 2 might overflow if _json_iter->peek_length() < 2. + // field_key() advances the pointer and checks that '"' is found (corresponding to a key). + // The depth is left unchanged by field_key(). + error = field_key().get(actual_key); SIMDJSON_ASSUME(!error); + // field_value() will advance and check that we find a ':' separating the + // key and the value. It will also increment the depth by one. + error = field_value(); SIMDJSON_ASSUME(!error); + + // If it matches, stop and return + // We could do it this way if we wanted to allow arbitrary + // key content (including escaped quotes). + // if (actual_key.unsafe_is_equal(max_key_length, key)) { + // Instead we do the following which may trigger buffer overruns if the + // user provides an adversarial key (containing a well placed unescaped quote + // character and being longer than the number of bytes remaining in the JSON + // input). + if (actual_key.unsafe_is_equal(key)) { + logger::log_event(*this, "match", key, -2); + // If we return here, then we return while pointing at the ':' that we just checked. + return true; + } + + // No match: skip the value and see if , or } is next + logger::log_event(*this, "no match", key, -2); + // The call to skip_child is meant to skip over the value corresponding to the key. + // After skip_child(), we are right before the next comma (',') or the final brace ('}'). + SIMDJSON_TRY(skip_child()); + // If we reached the end of the key-value pair we started from, then we know + // that the key is not there so we return false. We are either right before + // the next comma or the final brace. + if (_json_iter->position() == search_start) { return false; } + // The has_next_field() advances the pointer and check that either ',' or '}' is found. + // It returns true if ',' is found, false otherwise. If anything other than ',' or '}' is found, + // then we are in error and we abort. + error = has_next_field().get(has_value); SIMDJSON_ASSUME(!error); + // If we make the mistake of exiting here, then we could be left pointing at a key + // in the middle of an object. That's not an allowable state. + } + // If the loop ended, we're out of fields to look at. The program should + // never reach this point. + return false; + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::field_key() noexcept { + assert_at_next(); + + const uint8_t* key = _json_iter->return_current_and_advance(); + if (*(key++) != '"') { return report_error(TAPE_ERROR, "Object key is not a string"); } + return raw_json_string(key); + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::field_value() noexcept { + assert_at_next(); + + if (*_json_iter->return_current_and_advance() != ':') { return report_error(TAPE_ERROR, "Missing colon in object field"); } + _json_iter->descend_to(depth() + 1); + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::start_root_array() noexcept { + SIMDJSON_TRY(start_container('[', "Not an array", "array")); + return started_root_array(); + } + + inline std::string value_iterator::to_string() const noexcept { + auto answer = std::string("value_iterator [ depth : ") + std::to_string(_depth) + std::string(", "); + if (_json_iter != nullptr) { answer += _json_iter->to_string(); } + answer += std::string(" ]"); + return answer; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_array() noexcept { + assert_at_container_start(); + if (*_json_iter->peek() == ']') { + logger::log_value(*_json_iter, "empty array"); + _json_iter->return_current_and_advance(); + SIMDJSON_TRY(end_container()); + return false; + } + _json_iter->descend_to(depth() + 1); +#if SIMDJSON_DEVELOPMENT_CHECKS + _json_iter->set_start_position(_depth, start_position()); +#endif + return true; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::check_root_array() noexcept { + // When in streaming mode, we cannot expect peek_last() to be the last structural element of the + // current document. It only works in the normal mode where we have indexed a single document. + // Note that adding a check for 'streaming' is not expensive since we only have at most + // one root element. + if (!_json_iter->streaming()) { + // The following lines do not fully protect against garbage content within the + // array: e.g., `[1, 2] foo]`. Users concerned with garbage content should + // also call `at_end()` on the document instance at the end of the processing to + // ensure that the processing has finished at the end. + // + if (*_json_iter->peek_last() != ']') { + _json_iter->abandon(); + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "missing ] at end"); + } + // If the last character is ] *and* the first gibberish character is also ']' + // then on-demand could accidentally go over. So we need additional checks. + // https://github.com/simdjson/simdjson/issues/1834 + // Checking that the document is balanced requires a full scan which is potentially + // expensive, but it only happens in edge cases where the first padding character is + // a closing bracket. + if ((*_json_iter->peek(_json_iter->end_position()) == ']') && (!_json_iter->balanced())) { + _json_iter->abandon(); + // The exact error would require more work. It will typically be an unclosed array. + return report_error(INCOMPLETE_ARRAY_OR_OBJECT, "the document is unbalanced"); + } + } + return SUCCESS; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::started_root_array() noexcept { + auto error = check_root_array(); + if (error) { return error; } + return started_array(); + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::has_next_element() noexcept { + assert_at_next(); + + logger::log_event(*this, "has_next_element"); + switch (*_json_iter->return_current_and_advance()) { + case ']': + logger::log_end_value(*_json_iter, "array"); + SIMDJSON_TRY(end_container()); + return false; + case ',': + _json_iter->descend_to(depth() + 1); + return true; + default: + return report_error(TAPE_ERROR, "Missing comma between array elements"); + } + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_bool(const uint8_t* json) const noexcept { + auto not_true = atomparsing::str4ncmp(json, "true"); + auto not_false = atomparsing::str4ncmp(json, "fals") | (json[4] ^ 'e'); + bool error = (not_true && not_false) || jsoncharutils::is_not_structural_or_whitespace(json[not_true ? 5 : 4]); + if (error) { return incorrect_type_error("Not a boolean"); } + return simdjson_result(!not_true); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::parse_null(const uint8_t* json) const noexcept { + bool is_null_string = !atomparsing::str4ncmp(json, "null") && jsoncharutils::is_structural_or_whitespace(json[4]); + // if we start with 'n', we must be a null + if (!is_null_string && json[0] == 'n') { return incorrect_type_error("Not a null but starts with n"); } + return is_null_string; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_string(bool allow_replacement) noexcept { + return get_raw_json_string().unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_string(string_type& receiver, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_string(allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_wobbly_string() noexcept { + return get_raw_json_string().unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_raw_json_string() noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64() noexcept { + auto result = numberparsing::parse_unsigned(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_uint64_in_string() noexcept { + auto result = numberparsing::parse_unsigned_in_string(peek_non_root_scalar("uint64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("uint64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64() noexcept { + auto result = numberparsing::parse_integer(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_int64_in_string() noexcept { + auto result = numberparsing::parse_integer_in_string(peek_non_root_scalar("int64")); + if (result.error() == SUCCESS) { advance_non_root_scalar("int64"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double() noexcept { + auto result = numberparsing::parse_double(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_double_in_string() noexcept { + auto result = numberparsing::parse_double_in_string(peek_non_root_scalar("double")); + if (result.error() == SUCCESS) { advance_non_root_scalar("double"); } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_bool() noexcept { + auto result = parse_bool(peek_non_root_scalar("bool")); + if (result.error() == SUCCESS) { advance_non_root_scalar("bool"); } + return result; + } + simdjson_inline simdjson_result value_iterator::is_null() noexcept { + bool is_null_value; + SIMDJSON_TRY(parse_null(peek_non_root_scalar("null")).get(is_null_value)); + if (is_null_value) { advance_non_root_scalar("null"); } + return is_null_value; + } + simdjson_inline bool value_iterator::is_negative() noexcept { + return numberparsing::is_negative(peek_non_root_scalar("numbersign")); + } + simdjson_inline bool value_iterator::is_root_negative() noexcept { + return numberparsing::is_negative(peek_root_scalar("numbersign")); + } + simdjson_inline simdjson_result value_iterator::is_integer() noexcept { + return numberparsing::is_integer(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number_type() noexcept { + return numberparsing::get_number_type(peek_non_root_scalar("integer")); + } + simdjson_inline simdjson_result value_iterator::get_number() noexcept { + number num; + error_code error = numberparsing::parse_number(peek_non_root_scalar("number"), num); + if (error) { return error; } + return num; + } + + simdjson_inline simdjson_result value_iterator::is_root_integer(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("is_root_integer"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + return false; // if there are more than 20 characters, it cannot be represented as an integer. + } + auto answer = numberparsing::is_integer(tmpbuf); + // If the parsing was a success, we must still check that it is + // a single scalar. Note that we parse first because of cases like '[]' where + // getting TRAILING_CONTENT is wrong. + if (check_trailing && (answer.error() == SUCCESS) && (!_json_iter->is_single_token())) { return TRAILING_CONTENT; } + return answer; + } + + simdjson_inline simdjson_result value_iterator::get_root_number_type(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto answer = numberparsing::get_number_type(tmpbuf); + if (check_trailing && (answer.error() == SUCCESS) && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + return answer; + } + simdjson_inline simdjson_result value_iterator::get_root_number(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("number"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + number num; + error_code error = numberparsing::parse_number(tmpbuf, num); + if (error) { return error; } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("number"); + return num; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_string(bool check_trailing, bool allow_replacement) noexcept { + return get_root_raw_json_string(check_trailing).unescape(json_iter(), allow_replacement); + } + template + simdjson_warn_unused simdjson_inline error_code value_iterator::get_root_string(string_type& receiver, bool check_trailing, bool allow_replacement) noexcept { + std::string_view content; + auto err = get_root_string(check_trailing, allow_replacement).get(content); + if (err) { return err; } + receiver = content; + return SUCCESS; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_wobbly_string(bool check_trailing) noexcept { + return get_root_raw_json_string(check_trailing).unescape_wobbly(json_iter()); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_raw_json_string(bool check_trailing) noexcept { + auto json = peek_scalar("string"); + if (*json != '"') { return incorrect_type_error("Not a string"); } + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_scalar("string"); + return raw_json_string(json + 1); + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_uint64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("uint64"); + uint8_t tmpbuf[20 + 1 + 1]{}; // <20 digits> is the longest possible unsigned integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_unsigned_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("uint64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_int64_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("int64"); + uint8_t tmpbuf[20 + 1 + 1]; // -<19 digits> is the longest possible integer + tmpbuf[20 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 20 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 20 characters"); + return NUMBER_ERROR; + } + + auto result = numberparsing::parse_integer_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("int64"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_double_in_string(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("double"); + // Per https://www.exploringbinary.com/maximum-number-of-decimal-digits-in-binary-floating-point-numbers/, + // 1074 is the maximum number of significant fractional digits. Add 8 more digits for the biggest + // number: -0.e-308. + uint8_t tmpbuf[1074 + 8 + 1 + 1]; // +1 for null termination. + tmpbuf[1074 + 8 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 1074 + 8 + 1)) { + logger::log_error(*_json_iter, start_position(), depth(), "Root number more than 1082 characters"); + return NUMBER_ERROR; + } + auto result = numberparsing::parse_double_in_string(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("double"); + } + return result; + } + simdjson_warn_unused simdjson_inline simdjson_result value_iterator::get_root_bool(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("bool"); + uint8_t tmpbuf[5 + 1 + 1]; // +1 for null termination + tmpbuf[5 + 1] = '\0'; // make sure that buffer is always null terminated. + if (!_json_iter->copy_to_buffer(json, max_len, tmpbuf, 5 + 1)) { return incorrect_type_error("Not a boolean"); } + auto result = parse_bool(tmpbuf); + if (result.error() == SUCCESS) { + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("bool"); + } + return result; + } + simdjson_inline simdjson_result value_iterator::is_root_null(bool check_trailing) noexcept { + auto max_len = peek_start_length(); + auto json = peek_root_scalar("null"); + bool result = (max_len >= 4 && !atomparsing::str4ncmp(json, "null") && + (max_len == 4 || jsoncharutils::is_structural_or_whitespace(json[4]))); + if (result) { // we have something that looks like a null. + if (check_trailing && !_json_iter->is_single_token()) { return TRAILING_CONTENT; } + advance_root_scalar("null"); + } + return result; + } + + simdjson_warn_unused simdjson_inline error_code value_iterator::skip_child() noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth >= _depth); + + return _json_iter->skip_child(depth()); + } + + simdjson_inline value_iterator value_iterator::child() const noexcept { + assert_at_child(); + return { _json_iter, depth() + 1, _json_iter->token.position() }; + } + + // GCC 7 warns when the first line of this function is inlined away into oblivion due to the caller + // relating depth and iterator depth, which is a desired effect. It does not happen if is_open is + // marked non-inline. + SIMDJSON_PUSH_DISABLE_WARNINGS + SIMDJSON_DISABLE_STRICT_OVERFLOW_WARNING + simdjson_inline bool value_iterator::is_open() const noexcept { + return _json_iter->depth() >= depth(); + } + SIMDJSON_POP_DISABLE_WARNINGS + + simdjson_inline bool value_iterator::at_end() const noexcept { + return _json_iter->at_end(); + } + + simdjson_inline bool value_iterator::at_start() const noexcept { + return _json_iter->token.position() == start_position(); + } + + simdjson_inline bool value_iterator::at_first_field() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + return _json_iter->token.position() == start_position() + 1; + } + + simdjson_inline void value_iterator::abandon() noexcept { + _json_iter->abandon(); + } + + simdjson_warn_unused simdjson_inline depth_t value_iterator::depth() const noexcept { + return _depth; + } + simdjson_warn_unused simdjson_inline error_code value_iterator::error() const noexcept { + return _json_iter->error; + } + simdjson_warn_unused simdjson_inline uint8_t*& value_iterator::string_buf_loc() noexcept { + return _json_iter->string_buf_loc(); + } + simdjson_warn_unused simdjson_inline const json_iterator& value_iterator::json_iter() const noexcept { + return *_json_iter; + } + simdjson_warn_unused simdjson_inline json_iterator& value_iterator::json_iter() noexcept { + return *_json_iter; + } + + simdjson_inline const uint8_t* value_iterator::peek_start() const noexcept { + return _json_iter->peek(start_position()); + } + simdjson_inline uint32_t value_iterator::peek_start_length() const noexcept { + return _json_iter->peek_length(start_position()); + } + + simdjson_inline const uint8_t* value_iterator::peek_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return peek_start(); } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + if (!is_at_start()) { return; } + + // Get the JSON and advance the cursor, decreasing depth to signify that we have retrieved the value. + assert_at_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::start_container(uint8_t start_char, const char* incorrect_type_message, const char* type) noexcept { + logger::log_start_value(*_json_iter, start_position(), depth(), type); + // If we're not at the position anymore, we don't want to advance the cursor. + const uint8_t* json; + if (!is_at_start()) { +#if SIMDJSON_DEVELOPMENT_CHECKS + if (!is_at_iterator_start()) { return OUT_OF_ORDER_ITERATION; } +#endif + json = peek_start(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + } + else { + assert_at_start(); + /** + * We should be prudent. Let us peek. If it is not the right type, we + * return an error. Only once we have determined that we have the right + * type are we allowed to advance! + */ + json = _json_iter->peek(); + if (*json != start_char) { return incorrect_type_error(incorrect_type_message); } + _json_iter->return_current_and_advance(); + } + + + return SUCCESS; + } + + + simdjson_inline const uint8_t* value_iterator::peek_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_root(); + return _json_iter->peek(); + } + simdjson_inline const uint8_t* value_iterator::peek_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return peek_start(); } + + assert_at_non_root_start(); + return _json_iter->peek(); + } + + simdjson_inline void value_iterator::advance_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_root(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + simdjson_inline void value_iterator::advance_non_root_scalar(const char* type) noexcept { + logger::log_value(*_json_iter, start_position(), depth(), type); + if (!is_at_start()) { return; } + + assert_at_non_root_start(); + _json_iter->return_current_and_advance(); + _json_iter->ascend_to(depth() - 1); + } + + simdjson_inline error_code value_iterator::incorrect_type_error(const char* message) const noexcept { + logger::log_error(*_json_iter, start_position(), depth(), message); + return INCORRECT_TYPE; + } + + simdjson_inline bool value_iterator::is_at_start() const noexcept { + return position() == start_position(); + } + + simdjson_inline bool value_iterator::is_at_key() const noexcept { + // Keys are at the same depth as the object. + // Note here that we could be safer and check that we are within an object, + // but we do not. + return _depth == _json_iter->_depth && *_json_iter->peek() == '"'; + } + + simdjson_inline bool value_iterator::is_at_iterator_start() const noexcept { + // We can legitimately be either at the first value ([1]), or after the array if it's empty ([]). + auto delta = position() - start_position(); + return delta == 1 || delta == 2; + } + + inline void value_iterator::assert_at_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_container_start() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position == _start_position + 1); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_next() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth); + SIMDJSON_ASSUME(_depth > 0); + } + + simdjson_inline void value_iterator::move_at_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position); + } + + simdjson_inline void value_iterator::move_at_container_start() noexcept { + _json_iter->_depth = _depth; + _json_iter->token.set_position(_start_position + 1); + } + + simdjson_inline simdjson_result value_iterator::reset_array() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_array(); + } + + simdjson_inline simdjson_result value_iterator::reset_object() noexcept { + if (error()) { return error(); } + move_at_container_start(); + return started_object(); + } + + inline void value_iterator::assert_at_child() const noexcept { + SIMDJSON_ASSUME(_json_iter->token._position > _start_position); + SIMDJSON_ASSUME(_json_iter->_depth == _depth + 1); + SIMDJSON_ASSUME(_depth > 0); + } + + inline void value_iterator::assert_at_root() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth == 1); + } + + inline void value_iterator::assert_at_non_root_start() const noexcept { + assert_at_start(); + SIMDJSON_ASSUME(_depth > 1); + } + + inline void value_iterator::assert_is_valid() const noexcept { + SIMDJSON_ASSUME(_json_iter != nullptr); + } + + simdjson_inline bool value_iterator::is_valid() const noexcept { + return _json_iter != nullptr; + } + + simdjson_inline simdjson_result value_iterator::type() const noexcept { + switch (*peek_start()) { + case '{': + return json_type::object; + case '[': + return json_type::array; + case '"': + return json_type::string; + case 'n': + return json_type::null; + case 't': case 'f': + return json_type::boolean; + case '-': + case '0': case '1': case '2': case '3': case '4': + case '5': case '6': case '7': case '8': case '9': + return json_type::number; + default: + return TAPE_ERROR; + } + } + + simdjson_inline token_position value_iterator::start_position() const noexcept { + return _start_position; + } + + simdjson_inline token_position value_iterator::position() const noexcept { + return _json_iter->position(); + } + + simdjson_inline token_position value_iterator::end_position() const noexcept { + return _json_iter->end_position(); + } + + simdjson_inline token_position value_iterator::last_position() const noexcept { + return _json_iter->last_position(); + } + + simdjson_inline error_code value_iterator::report_error(error_code error, const char* message) noexcept { + return _json_iter->report_error(error, message); + } + + } // namespace ondemand + } // namespace westmere +} // namespace simdjson + +namespace simdjson { + + simdjson_inline simdjson_result::simdjson_result(westmere::ondemand::value_iterator&& value) noexcept + : implementation_simdjson_result_base(std::forward(value)) {} + simdjson_inline simdjson_result::simdjson_result(error_code error) noexcept + : implementation_simdjson_result_base(error) {} + +} // namespace simdjson + +#endif // SIMDJSON_GENERIC_ONDEMAND_VALUE_ITERATOR_INL_H +/* end file simdjson/generic/ondemand/value_iterator-inl.h for westmere */ +/* end file simdjson/generic/ondemand/amalgamated.h for westmere */ +/* including simdjson/westmere/end.h: #include "simdjson/westmere/end.h" */ +/* begin file simdjson/westmere/end.h */ +/* amalgamation skipped (editor-only): #ifndef SIMDJSON_CONDITIONAL_INCLUDE */ +/* amalgamation skipped (editor-only): #include "simdjson/westmere/base.h" */ +/* amalgamation skipped (editor-only): #endif // SIMDJSON_CONDITIONAL_INCLUDE */ + +#if !SIMDJSON_CAN_ALWAYS_RUN_WESTMERE +SIMDJSON_UNTARGET_REGION +#endif + +/* undefining SIMDJSON_IMPLEMENTATION from "westmere" */ +#undef SIMDJSON_IMPLEMENTATION +/* end file simdjson/westmere/end.h */ + +#endif // SIMDJSON_WESTMERE_IMPLEMENTATION_H +/* end file simdjson/westmere/ondemand.h */ +#else +#error Unknown SIMDJSON_BUILTIN_IMPLEMENTATION +#endif + +/* undefining SIMDJSON_CONDITIONAL_INCLUDE */ +#undef SIMDJSON_CONDITIONAL_INCLUDE + +namespace simdjson { /** * @copydoc simdjson::SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand */ namespace ondemand = SIMDJSON_BUILTIN_IMPLEMENTATION::ondemand; - /** - * Function which returns a pointer to an implementation matching the "builtin" implementation. - * The builtin implementation is the best statically linked simdjson implementation that can be used by the compiling - * program. If you compile with g++ -march=haswell, this will return the haswell implementation. - * It is handy to be able to check what builtin was used: builtin_implementation()->name(). - */ - const implementation* builtin_implementation(); } // namespace simdjson -#endif // SIMDJSON_BUILTIN_H -/* end file include/simdjson/builtin.h */ +#endif // SIMDJSON_BUILTIN_ONDEMAND_H +/* end file simdjson/builtin/ondemand.h */ + +namespace simdjson { + /** + * @copydoc simdjson::builtin::ondemand + */ + namespace ondemand = builtin::ondemand; +} // namespace simdjson + +#endif // SIMDJSON_ONDEMAND_H +/* end file simdjson/ondemand.h */ #endif // SIMDJSON_H -/* end file include/simdjson.h */ +/* end file simdjson.h */