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0f9950ed0c
PDB stores some of its data in streams and some in tables. This patch teaches llvm-pdbdump to dump basic summary data for the debug tables. In support of this, this patch also adds some DIA helper classes, such as a wrapper around an IDiaSymbol interface, as well as helpers for outputting various enumerations to a raw_ostream. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@227257 91177308-0d34-0410-b5e6-96231b3b80d8
296 lines
10 KiB
C++
296 lines
10 KiB
C++
//===- COMExtras.h - Helper files for COM operations -------------*- C++-*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_TOOLS_LLVM_PDBDUMP_COMEXTRAS_H
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#define LLVM_TOOLS_LLVM_PDBDUMP_COMEXTRAS_H
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#include "llvm/ADT/ArrayRef.h"
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#include "llvm/ADT/SmallVector.h"
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#include "llvm/Support/ConvertUTF.h"
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#include <tuple>
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namespace llvm {
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template <typename F> struct function_traits;
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#if LLVM_HAS_VARIADIC_TEMPLATES
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template <typename R, typename... Args>
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struct function_traits<R (*)(Args...)> : public function_traits<R(Args...)> {};
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template <typename C, typename R, typename... Args>
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struct function_traits<R (__stdcall C::*)(Args...)> {
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using args_tuple = std::tuple<Args...>;
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};
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#else
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// For the sake of COM, we only need a 3 argument version and a 5 argument
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// version. We could provide 1, 2, 4, and other length of argument lists if
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// this were intended to be more generic. Alternatively, this will "just work"
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// if VS2012 support is dropped and we can use the variadic template case
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// exclusively.
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template <typename C, typename R, typename A1, typename A2, typename A3>
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struct function_traits<R (__stdcall C::*)(A1, A2, A3)> {
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using args_tuple = std::tuple<A1, A2, A3>;
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};
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template <typename C, typename R, typename A1, typename A2, typename A3,
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typename A4, typename A5>
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struct function_traits<R (__stdcall C::*)(A1, A2, A3, A4, A5)> {
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using args_tuple = std::tuple<A1, A2, A3, A4, A5>;
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};
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#endif
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template <class FuncTraits, std::size_t arg> struct function_arg {
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// Writing function_arg as a separate class that accesses the tuple from
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// function_traits is necessary due to what appears to be a bug in MSVC.
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// If you write a nested class inside function_traits like this:
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// template<std::size_t ArgIndex>
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// struct Argument
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// {
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// typedef typename
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// std::tuple_element<ArgIndex, std::tuple<Args...>>::type type;
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// };
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// MSVC encounters a parsing error.
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typedef
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typename std::tuple_element<arg, typename FuncTraits::args_tuple>::type
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type;
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};
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template <class T> struct remove_double_pointer {};
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template <class T> struct remove_double_pointer<T **> { typedef T type; };
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namespace sys {
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namespace windows {
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/// A helper class for allowing the use of COM enumerators in range-based
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/// for loops.
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///
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/// A common idiom in the COM world is to have an enumerator interface, say
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/// IMyEnumerator. It's responsible for enumerating over some child data type,
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/// say IChildType. You do the enumeration by calling IMyEnumerator::Next()
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/// one of whose arguments will be an IChildType**. Eventually Next() fails,
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/// indicating that there are no more items.
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///
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/// com_iterator represents a single point-in-time of this iteration. It is
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/// used by ComEnumerator to support iterating in this fashion via range-based
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/// for loops and other common C++ paradigms.
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template <class EnumeratorType, std::size_t ArgIndex> class com_iterator {
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using FunctionTraits = function_traits<decltype(&EnumeratorType::Next)>;
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typedef typename function_arg<FunctionTraits, ArgIndex>::type FuncArgType;
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// FuncArgType is now something like ISomeCOMInterface **. Remove both
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// pointers, so we can make a CComPtr<T> out of it.
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typedef typename remove_double_pointer<FuncArgType>::type EnumDataType;
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CComPtr<EnumeratorType> EnumeratorObject;
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CComPtr<EnumDataType> CurrentItem;
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public:
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typedef CComPtr<EnumDataType> value_type;
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typedef std::ptrdiff_t difference_type;
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typedef value_type *pointer_type;
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typedef value_type &reference_type;
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typedef std::forward_iterator_tag iterator_category;
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explicit com_iterator(CComPtr<EnumeratorType> Enumerator,
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CComPtr<EnumDataType> Current)
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: EnumeratorObject(Enumerator), CurrentItem(Current) {}
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com_iterator() {}
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com_iterator &operator++() {
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// EnumeratorObject->Next() expects CurrentItem to be NULL.
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CurrentItem.Release();
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ULONG Count = 0;
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HRESULT hr = EnumeratorObject->Next(1, &CurrentItem, &Count);
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if (FAILED(hr) || Count == 0)
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*this = com_iterator();
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return *this;
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}
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value_type operator*() { return CurrentItem; }
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bool operator==(const com_iterator &other) const {
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return (EnumeratorObject == other.EnumeratorObject) &&
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(CurrentItem == other.CurrentItem);
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}
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bool operator!=(const com_iterator &other) const { return !(*this == other); }
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com_iterator &operator=(const com_iterator &other) {
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EnumeratorObject = other.EnumeratorObject;
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CurrentItem = other.CurrentItem;
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return *this;
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}
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};
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/// ComEnumerator implements the interfaced required for C++ to allow its use
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/// in range-based for loops. In particular, a begin() and end() method.
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/// These methods simply construct and return an appropriate ComIterator
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/// instance.
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template <class EnumeratorType, std::size_t ArgIndex> class com_enumerator {
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typedef function_traits<decltype(&EnumeratorType::Next)> FunctionTraits;
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typedef typename function_arg<FunctionTraits, ArgIndex>::type FuncArgType;
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typedef typename remove_double_pointer<FuncArgType>::type EnumDataType;
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CComPtr<EnumeratorType> EnumeratorObject;
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public:
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com_enumerator(CComPtr<EnumeratorType> Enumerator)
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: EnumeratorObject(Enumerator) {}
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com_iterator<EnumeratorType, ArgIndex> begin() {
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if (!EnumeratorObject)
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return end();
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EnumeratorObject->Reset();
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ULONG Count = 0;
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CComPtr<EnumDataType> FirstItem;
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HRESULT hr = EnumeratorObject->Next(1, &FirstItem, &Count);
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return (FAILED(hr) || Count == 0) ? end()
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: com_iterator<EnumeratorType, ArgIndex>(
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EnumeratorObject, FirstItem);
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}
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com_iterator<EnumeratorType, ArgIndex> end() {
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return com_iterator<EnumeratorType, ArgIndex>();
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}
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};
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/// A helper class for allowing the use of COM record enumerators in range-
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/// based for loops.
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///
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/// A record enumerator is almost the same as a regular enumerator, except
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/// that it returns raw byte-data instead of interfaces to other COM objects.
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/// As a result, the enumerator's Next() method has a slightly different
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/// signature, and an iterator dereferences to an ArrayRef instead of a
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/// CComPtr.
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template <class EnumeratorType> class com_data_record_iterator {
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public:
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typedef llvm::ArrayRef<uint8_t> value_type;
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typedef std::ptrdiff_t difference_type;
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typedef value_type *pointer_type;
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typedef value_type &reference_type;
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typedef std::forward_iterator_tag iterator_category;
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explicit com_data_record_iterator(CComPtr<EnumeratorType> enumerator)
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: Enumerator(enumerator), CurrentRecord(0) {
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// Make sure we start at the beginning. If there are no records,
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// immediately set ourselves equal to end().
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if (enumerator)
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enumerator->Reset();
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if (!ReadNextRecord())
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*this = com_data_record_iterator();
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}
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com_data_record_iterator() {}
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com_data_record_iterator &operator++() {
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++CurrentRecord;
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// If we can't read any more records, either because there are no more
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// or because we encountered an error, we should compare equal to end.
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if (!ReadNextRecord())
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*this = com_data_record_iterator();
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return *this;
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}
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value_type operator*() {
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return llvm::ArrayRef<uint8_t>(RecordData.begin(), RecordData.end());
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}
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bool operator==(const com_data_record_iterator &other) const {
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return (Enumerator == other.Enumerator) &&
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(CurrentRecord == other.CurrentRecord);
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}
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bool operator!=(const com_data_record_iterator &other) const {
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return !(*this == other);
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}
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private:
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bool ReadNextRecord() {
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RecordData.clear();
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ULONG Count = 0;
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DWORD RequiredBufferSize;
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HRESULT hr = Enumerator->Next(1, 0, &RequiredBufferSize, nullptr, &Count);
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if (hr == S_OK) {
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RecordData.resize(RequiredBufferSize);
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DWORD BytesRead = 0;
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hr = Enumerator->Next(1, RequiredBufferSize, &BytesRead,
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RecordData.data(), &Count);
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}
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if (hr != S_OK)
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RecordData.clear();
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return (hr == S_OK);
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}
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CComPtr<EnumeratorType> Enumerator;
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uint32_t CurrentRecord;
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llvm::SmallVector<uint8_t, 32> RecordData;
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};
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/// Similar to ComEnumerator, com_data_record_enumerator implements the range
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/// interface for ComDataRecordIterators.
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template <class EnumeratorType> class com_data_record_enumerator {
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public:
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com_data_record_enumerator(CComPtr<EnumeratorType> enumerator)
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: Enumerator(enumerator) {}
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com_data_record_iterator<EnumeratorType> begin() {
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return com_data_record_iterator<EnumeratorType>(Enumerator);
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}
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com_data_record_iterator<EnumeratorType> end() {
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LONG NumElts = 0;
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HRESULT hr = Enumerator->get_Count(&NumElts);
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return (FAILED(hr)) ? com_data_record_iterator<EnumeratorType>(Enumerator)
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: com_data_record_iterator<EnumeratorType>();
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}
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private:
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CComPtr<EnumeratorType> Enumerator;
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};
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/// com_enumerator is a simple helper function to allow the enumerator
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/// class's type to be inferred automatically.
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/// This allows you to write simply:
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/// for (auto item : com_enumerator(MyEnumerator)) {
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/// }
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template <class EnumeratorType>
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com_enumerator<EnumeratorType, 1>
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make_com_enumerator(CComPtr<EnumeratorType> Enumerator) {
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return com_enumerator<EnumeratorType, 1>(Enumerator);
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}
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/// com_data_record_enumerator is a simple helper function to allow the
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/// enumerator class's type to be inferred automatically.
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/// This allows you to write simply:
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/// for (auto item : com_data_record_enumerator(MyEnumerator)) {
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/// }
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//=============================================================================
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template <class EnumeratorType>
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com_data_record_enumerator<EnumeratorType>
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make_com_data_record_enumerator(CComPtr<EnumeratorType> Enumerator) {
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return com_data_record_enumerator<EnumeratorType>(Enumerator);
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}
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inline bool BSTRToUTF8(BSTR String16, std::string &String8) {
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UINT ByteLength = ::SysStringByteLen(String16);
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char *Bytes = reinterpret_cast<char *>(String16);
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String8.clear();
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return llvm::convertUTF16ToUTF8String(ArrayRef<char>(Bytes, ByteLength),
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String8);
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}
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} // namespace windows
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} // namespace sys
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} // namespace llvm
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#endif
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