mirror of
https://github.com/TomHarte/CLK.git
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764 lines
23 KiB
Plaintext
764 lines
23 KiB
Plaintext
//
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// 8088Tests.m
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// Clock SignalTests
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//
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// Created by Thomas Harte on 13/09/2023.
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// Copyright © 2023 Thomas Harte. All rights reserved.
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//
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#import <XCTest/XCTest.h>
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#include <array>
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#include <cassert>
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#include <iostream>
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#include <sstream>
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#include <fstream>
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#include <unordered_map>
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#include <unordered_set>
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#include "NSData+dataWithContentsOfGZippedFile.h"
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#include "../../../InstructionSets/x86/AccessType.hpp"
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#include "../../../InstructionSets/x86/Decoder.hpp"
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#include "../../../InstructionSets/x86/Perform.hpp"
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#include "../../../InstructionSets/x86/Flags.hpp"
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#include "../../../Numeric/RegisterSizes.hpp"
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namespace {
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// The tests themselves are not duplicated in this repository;
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// provide their real path here.
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constexpr char TestSuiteHome[] = "/Users/tharte/Projects/ProcessorTests/8088/v1";
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using Flags = InstructionSet::x86::Flags;
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struct Registers {
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CPU::RegisterPair16 ax_;
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uint8_t &al() { return ax_.halves.low; }
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uint8_t &ah() { return ax_.halves.high; }
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uint16_t &ax() { return ax_.full; }
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CPU::RegisterPair16 &axp() { return ax_; }
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CPU::RegisterPair16 cx_;
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uint8_t &cl() { return cx_.halves.low; }
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uint8_t &ch() { return cx_.halves.high; }
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uint16_t &cx() { return cx_.full; }
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CPU::RegisterPair16 dx_;
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uint8_t &dl() { return dx_.halves.low; }
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uint8_t &dh() { return dx_.halves.high; }
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uint16_t &dx() { return dx_.full; }
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CPU::RegisterPair16 bx_;
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uint8_t &bl() { return bx_.halves.low; }
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uint8_t &bh() { return bx_.halves.high; }
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uint16_t &bx() { return bx_.full; }
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uint16_t sp_;
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uint16_t &sp() { return sp_; }
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uint16_t bp_;
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uint16_t &bp() { return bp_; }
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uint16_t si_;
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uint16_t &si() { return si_; }
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uint16_t di_;
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uint16_t &di() { return di_; }
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uint16_t es_, cs_, ds_, ss_;
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uint16_t ip_;
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uint16_t &ip() { return ip_; }
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uint16_t &es() { return es_; }
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uint16_t &cs() { return cs_; }
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uint16_t &ds() { return ds_; }
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uint16_t &ss() { return ss_; }
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bool operator ==(const Registers &rhs) const {
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return
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ax_.full == rhs.ax_.full &&
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cx_.full == rhs.cx_.full &&
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dx_.full == rhs.dx_.full &&
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bx_.full == rhs.bx_.full &&
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sp_ == rhs.sp_ &&
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bp_ == rhs.bp_ &&
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si_ == rhs.si_ &&
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di_ == rhs.di_ &&
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es_ == rhs.es_ &&
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cs_ == rhs.cs_ &&
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ds_ == rhs.ds_ &&
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si_ == rhs.si_ &&
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ip_ == rhs.ip_;
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}
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};
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struct Memory {
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public:
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using AccessType = InstructionSet::x86::AccessType;
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// Constructor.
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Memory(Registers ®isters) : registers_(registers) {
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memory.resize(1024*1024);
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}
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// Initialisation.
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void clear() {
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tags.clear();
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}
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void seed(uint32_t address, uint8_t value) {
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memory[address] = value;
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tags[address] = Tag::Seeded;
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}
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void touch(uint32_t address) {
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tags[address] = Tag::AccessExpected;
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}
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//
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// Preauthorisation call-ins.
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//
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void preauthorise_stack_write(uint32_t length) {
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uint16_t sp = registers_.sp_;
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while(length--) {
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--sp;
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preauthorise(InstructionSet::x86::Source::SS, sp);
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}
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}
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void preauthorise_stack_read(uint32_t length) {
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uint16_t sp = registers_.sp_;
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while(length--) {
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preauthorise(InstructionSet::x86::Source::SS, sp);
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++sp;
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}
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}
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void preauthorise_read(InstructionSet::x86::Source segment, uint16_t start, uint32_t length) {
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while(length--) {
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preauthorise(segment, start);
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++start;
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}
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}
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void preauthorise_read(uint32_t start, uint32_t length) {
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while(length--) {
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preauthorise(start);
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++start;
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}
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}
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//
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// Access call-ins.
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//
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// Accesses an address based on segment:offset.
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template <typename IntT, AccessType type>
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typename InstructionSet::x86::Accessor<IntT, type>::type access(InstructionSet::x86::Source segment, uint16_t offset) {
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return access<IntT, type>(segment, offset, Tag::Accessed);
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}
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// Accesses an address based on physical location.
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template <typename IntT, AccessType type>
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typename InstructionSet::x86::Accessor<IntT, type>::type access(uint32_t address) {
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return access<IntT, type>(address, Tag::Accessed);
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}
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template <typename IntT>
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void write_back() {
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if constexpr (std::is_same_v<IntT, uint16_t>) {
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if(write_back_address_[0] != NoWriteBack) {
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memory[write_back_address_[0]] = write_back_value_ & 0xff;
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memory[write_back_address_[1]] = write_back_value_ >> 8;
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write_back_address_[0] = 0;
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}
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}
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}
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//
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// Direct write.
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//
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template <typename IntT>
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void preauthorised_write(InstructionSet::x86::Source segment, uint16_t offset, IntT value) {
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if(!test_preauthorisation(address(segment, offset))) {
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printf("Non-preauthorised access\n");
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}
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// Bytes can be written without further ado.
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if constexpr (std::is_same_v<IntT, uint8_t>) {
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memory[address(segment, offset) & 0xf'ffff] = value;
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return;
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}
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// Words that straddle the segment end must be split in two.
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if(offset == 0xffff) {
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memory[address(segment, offset) & 0xf'ffff] = value & 0xff;
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memory[address(segment, 0x0000) & 0xf'ffff] = value >> 8;
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return;
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}
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const uint32_t target = address(segment, offset) & 0xf'ffff;
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// Words that straddle the end of physical RAM must also be split in two.
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if(target == 0xf'ffff) {
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memory[0xf'ffff] = value & 0xff;
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memory[0x0'0000] = value >> 8;
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return;
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}
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// It's safe just to write then.
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*reinterpret_cast<uint16_t *>(&memory[target]) = value;
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}
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private:
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enum class Tag {
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Seeded,
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AccessExpected,
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Accessed,
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};
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std::unordered_set<uint32_t> preauthorisations;
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std::unordered_map<uint32_t, Tag> tags;
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std::vector<uint8_t> memory;
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const Registers ®isters_;
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void preauthorise(uint32_t address) {
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preauthorisations.insert(address);
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}
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void preauthorise(InstructionSet::x86::Source segment, uint16_t address) {
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preauthorise((segment_base(segment) + address) & 0xf'ffff);
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}
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bool test_preauthorisation(uint32_t address) {
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auto authorisation = preauthorisations.find(address);
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if(authorisation == preauthorisations.end()) {
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return false;
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}
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preauthorisations.erase(authorisation);
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return true;
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}
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uint32_t segment_base(InstructionSet::x86::Source segment) {
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uint32_t physical_address;
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using Source = InstructionSet::x86::Source;
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switch(segment) {
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default: physical_address = registers_.ds_; break;
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case Source::ES: physical_address = registers_.es_; break;
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case Source::CS: physical_address = registers_.cs_; break;
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case Source::SS: physical_address = registers_.ss_; break;
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}
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return physical_address << 4;
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}
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uint32_t address(InstructionSet::x86::Source segment, uint16_t offset) {
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return (segment_base(segment) + offset) & 0xf'ffff;
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}
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// Entry point used by the flow controller so that it can mark up locations at which the flags were written,
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// so that defined-flag-only masks can be applied while verifying RAM contents.
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template <typename IntT, AccessType type>
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typename InstructionSet::x86::Accessor<IntT, type>::type access(InstructionSet::x86::Source segment, uint16_t offset, Tag tag) {
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const uint32_t physical_address = address(segment, offset);
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if constexpr (std::is_same_v<IntT, uint16_t>) {
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// If this is a 16-bit access that runs past the end of the segment, it'll wrap back
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// to the start. So the 16-bit value will need to be a local cache.
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if(offset == 0xffff) {
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return split_word<type>(physical_address, address(segment, 0), tag);
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}
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}
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return access<IntT, type>(physical_address, tag);
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}
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// An additional entry point for the flow controller; on the original 8086 interrupt vectors aren't relative
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// to a selector, they're just at an absolute location.
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template <typename IntT, AccessType type>
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typename InstructionSet::x86::Accessor<IntT, type>::type access(uint32_t address, Tag tag) {
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if constexpr (type == AccessType::PreauthorisedRead) {
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if(!test_preauthorisation(address)) {
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printf("Non preauthorised access\n");
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}
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}
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for(size_t c = 0; c < sizeof(IntT); c++) {
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tags[(address + c) & 0xf'ffff] = tag;
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}
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// Dispense with the single-byte case trivially.
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if constexpr (std::is_same_v<IntT, uint8_t>) {
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return memory[address];
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} else if(address != 0xf'ffff) {
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return *reinterpret_cast<IntT *>(&memory[address]);
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} else {
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return split_word<type>(address, 0, tag);
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}
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}
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template <AccessType type>
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typename InstructionSet::x86::Accessor<uint16_t, type>::type
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split_word(uint32_t low_address, uint32_t high_address, Tag tag) {
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if constexpr (is_writeable(type)) {
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write_back_address_[0] = low_address;
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write_back_address_[1] = high_address;
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tags[low_address] = tag;
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tags[high_address] = tag;
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// Prepopulate only if this is a modify.
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if constexpr (type == AccessType::ReadModifyWrite) {
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write_back_value_ = memory[write_back_address_[0]] | (memory[write_back_address_[1]] << 8);
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}
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return write_back_value_;
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} else {
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return memory[low_address] | (memory[high_address] << 8);
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}
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}
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static constexpr uint32_t NoWriteBack = 0; // A low byte address of 0 can't require write-back.
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uint32_t write_back_address_[2] = {NoWriteBack, NoWriteBack};
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uint16_t write_back_value_;
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};
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struct IO {
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template <typename IntT> void out([[maybe_unused]] uint16_t port, [[maybe_unused]] IntT value) {}
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template <typename IntT> IntT in([[maybe_unused]] uint16_t port) { return IntT(~0); }
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};
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class FlowController {
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public:
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FlowController(Memory &memory, Registers ®isters, Flags &flags) :
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memory_(memory), registers_(registers), flags_(flags) {}
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// Requirements for perform.
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void jump(uint16_t address) {
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registers_.ip_ = address;
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}
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void jump(uint16_t segment, uint16_t address) {
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registers_.cs_ = segment;
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registers_.ip_ = address;
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}
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void halt() {}
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void wait() {}
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void repeat_last() {
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should_repeat_ = true;
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}
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// Other actions.
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void begin_instruction() {
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should_repeat_ = false;
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}
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bool should_repeat() const {
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return should_repeat_;
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}
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private:
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Memory &memory_;
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Registers ®isters_;
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Flags &flags_;
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bool should_repeat_ = false;
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};
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struct ExecutionSupport {
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Flags flags;
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Registers registers;
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Memory memory;
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FlowController flow_controller;
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IO io;
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static constexpr auto model = InstructionSet::x86::Model::i8086;
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ExecutionSupport(): memory(registers), flow_controller(memory, registers, flags) {}
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void clear() {
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memory.clear();
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}
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};
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struct FailedExecution {
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std::string test_name;
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std::string reason;
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InstructionSet::x86::Instruction<false> instruction;
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};
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}
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@interface i8088Tests : XCTestCase
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@end
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@implementation i8088Tests {
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std::vector<FailedExecution> execution_failures;
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ExecutionSupport execution_support;
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}
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- (NSArray<NSString *> *)testFiles {
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NSString *path = [NSString stringWithUTF8String:TestSuiteHome];
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NSSet *allowList = [NSSet setWithArray:@[
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// Current execution failures:
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// @"D4.json.gz", // AAM
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// @"F6.7.json.gz", // IDIV
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// @"F7.7.json.gz", // IDIV
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]];
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NSSet *ignoreList = nil;
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NSArray<NSString *> *files = [[NSFileManager defaultManager] contentsOfDirectoryAtPath:path error:nil];
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files = [files filteredArrayUsingPredicate:[NSPredicate predicateWithBlock:^BOOL(NSString* evaluatedObject, NSDictionary<NSString *,id> *) {
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if(allowList.count && ![allowList containsObject:[evaluatedObject lastPathComponent]]) {
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return NO;
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}
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if([ignoreList containsObject:[evaluatedObject lastPathComponent]]) {
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return NO;
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}
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return [evaluatedObject hasSuffix:@"json.gz"];
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}]];
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NSMutableArray<NSString *> *fullPaths = [[NSMutableArray alloc] init];
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for(NSString *file in files) {
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[fullPaths addObject:[path stringByAppendingPathComponent:file]];
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}
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return [fullPaths sortedArrayUsingSelector:@selector(compare:)];
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}
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- (NSArray<NSDictionary *> *)testsInFile:(NSString *)file {
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NSData *data = [NSData dataWithContentsOfGZippedFile:file];
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return [NSJSONSerialization JSONObjectWithData:data options:0 error:nil];
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}
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- (NSDictionary *)metadata {
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NSString *path = [[NSString stringWithUTF8String:TestSuiteHome] stringByAppendingPathComponent:@"8088.json"];
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return [NSJSONSerialization JSONObjectWithData:[NSData dataWithContentsOfGZippedFile:path] options:0 error:nil];
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}
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- (NSString *)toString:(const std::pair<int, InstructionSet::x86::Instruction<false>> &)instruction offsetLength:(int)offsetLength immediateLength:(int)immediateLength {
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const auto operation = to_string(instruction, InstructionSet::x86::Model::i8086, offsetLength, immediateLength);
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return [[NSString stringWithUTF8String:operation.c_str()] stringByTrimmingCharactersInSet:[NSCharacterSet whitespaceCharacterSet]];
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}
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- (std::vector<uint8_t>)bytes:(NSArray<NSNumber *> *)encoding {
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std::vector<uint8_t> data;
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data.reserve(encoding.count);
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for(NSNumber *number in encoding) {
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data.push_back([number intValue]);
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}
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return data;
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}
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- (bool)applyDecodingTest:(NSDictionary *)test file:(NSString *)file assert:(BOOL)assert {
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InstructionSet::x86::Decoder<InstructionSet::x86::Model::i8086> decoder;
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// Build a vector of the instruction bytes; this makes manual step debugging easier.
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const auto data = [self bytes:test[@"bytes"]];
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auto hex_instruction = [&]() -> NSString * {
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NSMutableString *hexInstruction = [[NSMutableString alloc] init];
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for(uint8_t byte: data) {
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[hexInstruction appendFormat:@"%02x ", byte];
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}
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return hexInstruction;
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};
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const auto decoded = decoder.decode(data.data(), data.size());
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const bool sizeMatched = decoded.first == data.size();
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if(assert) {
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XCTAssert(
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sizeMatched,
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"Wrong length of instruction decoded for %@ — decoded %d rather than %lu from %@; file %@",
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test[@"name"],
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decoded.first,
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(unsigned long)data.size(),
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hex_instruction(),
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file
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);
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}
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if(!sizeMatched) {
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return false;
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}
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// The decoder doesn't preserve the original offset length, which makes no functional difference but
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// does affect the way that offsets are printed in the test set.
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NSSet<NSString *> *decodings = [NSSet setWithObjects:
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[self toString:decoded offsetLength:4 immediateLength:4],
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[self toString:decoded offsetLength:2 immediateLength:4],
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[self toString:decoded offsetLength:0 immediateLength:4],
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[self toString:decoded offsetLength:4 immediateLength:2],
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[self toString:decoded offsetLength:2 immediateLength:2],
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[self toString:decoded offsetLength:0 immediateLength:2],
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nil];
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auto compare_decoding = [&](NSString *name) -> bool {
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return [decodings containsObject:name];
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};
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bool isEqual = compare_decoding(test[@"name"]);
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// Attempt clerical reconciliation:
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//
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// * the test suite retains a distinction between SHL and SAL, which the decoder doesn't;
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// * the decoder treats INT3 and INT 3 as the same thing; and
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// * the decoder doesn't record whether a segment override was present, just the final segment.
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int adjustment = 7;
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while(!isEqual && adjustment) {
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NSString *alteredName = [test[@"name"] stringByTrimmingCharactersInSet:[NSCharacterSet whitespaceCharacterSet]];
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if(adjustment & 2) {
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alteredName = [alteredName stringByReplacingOccurrencesOfString:@"shl" withString:@"sal"];
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}
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if(adjustment & 1) {
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alteredName = [alteredName stringByReplacingOccurrencesOfString:@"int3" withString:@"int 3h"];
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}
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if(adjustment & 4) {
|
|
alteredName = [@"ds " stringByAppendingString:alteredName];
|
|
}
|
|
|
|
isEqual = compare_decoding(alteredName);
|
|
--adjustment;
|
|
}
|
|
|
|
if(assert) {
|
|
XCTAssert(
|
|
isEqual,
|
|
"%@ doesn't match %@ or similar, was %@",
|
|
test[@"name"],
|
|
[decodings anyObject],
|
|
hex_instruction()
|
|
);
|
|
}
|
|
|
|
return isEqual;
|
|
}
|
|
|
|
- (void)populate:(Registers &)registers flags:(Flags &)flags value:(NSDictionary *)value {
|
|
registers.ax_.full = [value[@"ax"] intValue];
|
|
registers.bx_.full = [value[@"bx"] intValue];
|
|
registers.cx_.full = [value[@"cx"] intValue];
|
|
registers.dx_.full = [value[@"dx"] intValue];
|
|
|
|
registers.bp_ = [value[@"bp"] intValue];
|
|
registers.cs_ = [value[@"cs"] intValue];
|
|
registers.di_ = [value[@"di"] intValue];
|
|
registers.ds_ = [value[@"ds"] intValue];
|
|
registers.es_ = [value[@"es"] intValue];
|
|
registers.si_ = [value[@"si"] intValue];
|
|
registers.sp_ = [value[@"sp"] intValue];
|
|
registers.ss_ = [value[@"ss"] intValue];
|
|
registers.ip_ = [value[@"ip"] intValue];
|
|
|
|
const uint16_t flags_value = [value[@"flags"] intValue];
|
|
flags.set(flags_value);
|
|
|
|
// Apply a quick test of flag packing/unpacking.
|
|
constexpr auto defined_flags = static_cast<uint16_t>(
|
|
InstructionSet::x86::FlagValue::Carry |
|
|
InstructionSet::x86::FlagValue::Parity |
|
|
InstructionSet::x86::FlagValue::AuxiliaryCarry |
|
|
InstructionSet::x86::FlagValue::Zero |
|
|
InstructionSet::x86::FlagValue::Sign |
|
|
InstructionSet::x86::FlagValue::Trap |
|
|
InstructionSet::x86::FlagValue::Interrupt |
|
|
InstructionSet::x86::FlagValue::Direction |
|
|
InstructionSet::x86::FlagValue::Overflow
|
|
);
|
|
XCTAssert((flags.get() & defined_flags) == (flags_value & defined_flags),
|
|
"Set flags of %04x was returned as %04x",
|
|
flags_value & defined_flags,
|
|
(flags.get() & defined_flags)
|
|
);
|
|
}
|
|
|
|
- (void)applyExecutionTest:(NSDictionary *)test metadata:(NSDictionary *)metadata {
|
|
InstructionSet::x86::Decoder<InstructionSet::x86::Model::i8086> decoder;
|
|
const auto data = [self bytes:test[@"bytes"]];
|
|
const auto decoded = decoder.decode(data.data(), data.size());
|
|
|
|
execution_support.clear();
|
|
|
|
const uint16_t flags_mask = metadata[@"flags-mask"] ? [metadata[@"flags-mask"] intValue] : 0xffff;
|
|
NSDictionary *const initial_state = test[@"initial"];
|
|
NSDictionary *const final_state = test[@"final"];
|
|
|
|
// Apply initial state.
|
|
Flags initial_flags;
|
|
for(NSArray<NSNumber *> *ram in initial_state[@"ram"]) {
|
|
execution_support.memory.seed([ram[0] intValue], [ram[1] intValue]);
|
|
}
|
|
for(NSArray<NSNumber *> *ram in final_state[@"ram"]) {
|
|
execution_support.memory.touch([ram[0] intValue]);
|
|
}
|
|
Registers initial_registers;
|
|
[self populate:initial_registers flags:initial_flags value:initial_state[@"regs"]];
|
|
execution_support.flags = initial_flags;
|
|
execution_support.registers = initial_registers;
|
|
|
|
// Execute instruction.
|
|
//
|
|
// TODO: enquire of the actual mechanism of repetition; if it were stateful as below then
|
|
// would it survive interrupts? So is it just IP adjustment?
|
|
execution_support.registers.ip_ += decoded.first;
|
|
do {
|
|
execution_support.flow_controller.begin_instruction();
|
|
InstructionSet::x86::perform(
|
|
decoded.second,
|
|
execution_support
|
|
);
|
|
} while (execution_support.flow_controller.should_repeat());
|
|
|
|
// Compare final state.
|
|
Registers intended_registers;
|
|
InstructionSet::x86::Flags intended_flags;
|
|
|
|
bool ramEqual = true;
|
|
int mask_position = 0;
|
|
for(NSArray<NSNumber *> *ram in final_state[@"ram"]) {
|
|
const uint32_t address = [ram[0] intValue];
|
|
const auto value = execution_support.memory.access<uint8_t, Memory::AccessType::Read>(address);
|
|
|
|
if((mask_position != 1) && value == [ram[1] intValue]) {
|
|
continue;
|
|
}
|
|
|
|
// Consider whether this apparent mismatch might be because flags have been written to memory;
|
|
// allow only one use of the [16-bit] mask per test.
|
|
bool matched_with_mask = false;
|
|
while(mask_position < 2) {
|
|
const uint8_t mask = mask_position ? (flags_mask >> 8) : (flags_mask & 0xff);
|
|
++mask_position;
|
|
if((value & mask) == ([ram[1] intValue] & mask)) {
|
|
matched_with_mask = true;
|
|
break;
|
|
}
|
|
}
|
|
if(matched_with_mask) {
|
|
continue;
|
|
}
|
|
|
|
ramEqual = false;
|
|
break;
|
|
}
|
|
|
|
[self populate:intended_registers flags:intended_flags value:final_state[@"regs"]];
|
|
const bool registersEqual = intended_registers == execution_support.registers;
|
|
const bool flagsEqual = (intended_flags.get() & flags_mask) == (execution_support.flags.get() & flags_mask);
|
|
|
|
if(!flagsEqual || !registersEqual || !ramEqual) {
|
|
FailedExecution failure;
|
|
failure.instruction = decoded.second;
|
|
failure.test_name = std::string([test[@"name"] UTF8String]);
|
|
|
|
NSMutableArray<NSString *> *reasons = [[NSMutableArray alloc] init];
|
|
if(!flagsEqual) {
|
|
Flags difference;
|
|
difference.set((intended_flags.get() ^ execution_support.flags.get()) & flags_mask);
|
|
[reasons addObject:
|
|
[NSString stringWithFormat:@"flags differs; errors in %s",
|
|
difference.to_string().c_str()]];
|
|
}
|
|
if(!registersEqual) {
|
|
NSMutableArray<NSString *> *registers = [[NSMutableArray alloc] init];
|
|
#define Reg(x) \
|
|
if(intended_registers.x() != execution_support.registers.x()) \
|
|
[registers addObject: \
|
|
[NSString stringWithFormat: \
|
|
@#x" is %04x rather than %04x", execution_support.registers.x(), intended_registers.x()]];
|
|
|
|
Reg(ax);
|
|
Reg(cx);
|
|
Reg(dx);
|
|
Reg(bx);
|
|
Reg(sp);
|
|
Reg(bp);
|
|
Reg(si);
|
|
Reg(di);
|
|
Reg(ip);
|
|
Reg(es);
|
|
Reg(cs);
|
|
Reg(ds);
|
|
Reg(ss);
|
|
|
|
#undef Reg
|
|
[reasons addObject:[NSString stringWithFormat:
|
|
@"registers don't match: %@", [registers componentsJoinedByString:@", "]
|
|
]];
|
|
}
|
|
if(!ramEqual) {
|
|
[reasons addObject:@"RAM contents don't match"];
|
|
}
|
|
|
|
failure.reason = std::string([reasons componentsJoinedByString:@"; "].UTF8String);
|
|
execution_failures.push_back(std::move(failure));
|
|
}
|
|
}
|
|
|
|
- (void)printFailures:(NSArray<NSString *> *)failures {
|
|
NSLog(
|
|
@"%ld failures out of %ld tests: %@",
|
|
failures.count,
|
|
[self testFiles].count,
|
|
[failures sortedArrayUsingSelector:@selector(caseInsensitiveCompare:)]);
|
|
}
|
|
|
|
- (void)testDecoding {
|
|
NSMutableArray<NSString *> *failures = [[NSMutableArray alloc] init];
|
|
for(NSString *file in [self testFiles]) @autoreleasepool {
|
|
for(NSDictionary *test in [self testsInFile:file]) {
|
|
// A single failure per instruction is fine.
|
|
if(![self applyDecodingTest:test file:file assert:YES]) {
|
|
[failures addObject:file];
|
|
|
|
// Attempt a second decoding, to provide a debugger hook.
|
|
[self applyDecodingTest:test file:file assert:NO];
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
|
|
[self printFailures:failures];
|
|
}
|
|
|
|
- (void)testExecution {
|
|
NSDictionary *metadata = [self metadata];
|
|
NSMutableArray<NSString *> *failures = [[NSMutableArray alloc] init];
|
|
|
|
for(NSString *file in [self testFiles]) @autoreleasepool {
|
|
const auto failures_before = execution_failures.size();
|
|
|
|
// Determine the metadata key.
|
|
NSString *const name = [file lastPathComponent];
|
|
NSRange first_dot = [name rangeOfString:@"."];
|
|
NSString *metadata_key = [name substringToIndex:first_dot.location];
|
|
|
|
// Grab the metadata. If it wants a reg field, inspect a little further.
|
|
NSDictionary *test_metadata = metadata[metadata_key];
|
|
if(test_metadata[@"reg"]) {
|
|
test_metadata = test_metadata[@"reg"][[NSString stringWithFormat:@"%c", [name characterAtIndex:first_dot.location+1]]];
|
|
}
|
|
|
|
int index = 0;
|
|
for(NSDictionary *test in [self testsInFile:file]) {
|
|
[self applyExecutionTest:test metadata:test_metadata];
|
|
++index;
|
|
}
|
|
|
|
if (execution_failures.size() != failures_before) {
|
|
[failures addObject:file];
|
|
}
|
|
}
|
|
|
|
// Lock in current failure rate.
|
|
XCTAssertLessThanOrEqual(execution_failures.size(), 4009);
|
|
|
|
// Current accepted failures:
|
|
// * 2484 instances of LEA from a register, which officially has undefined results;
|
|
// * 42 instances of AAM 00h for which I can't figure out what to do with flags; and
|
|
// * 1486 instances of IDIV, most either with a rep or repne that on the 8086 specifically negatives the result,
|
|
// but some admittedly still unexplained (primarily setting overflow even though the result doesn't overflow;
|
|
// a couple of online 8086 emulators also didn't throw so maybe this is an 8086 quirk?)
|
|
|
|
for(const auto &failure: execution_failures) {
|
|
NSLog(@"Failed %s — %s", failure.test_name.c_str(), failure.reason.c_str());
|
|
}
|
|
|
|
NSLog(@"Files with failures were: %@", failures);
|
|
}
|
|
|
|
@end
|