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chromium / external / github.com / microsoft / DirectXShaderCompiler / refs/heads/upstream/version-2005 / . / lib / DxcSupport / FileIOHelper.cpp
blob: 2eeac0b8a43dba8b0fe0d51794ccef7d92403e87 [file] [log] [blame] [edit]
///////////////////////////////////////////////////////////////////////////////
// //
// FileIOHelper.cpp //
// Copyright (C) Microsoft Corporation. All rights reserved. //
// This file is distributed under the University of Illinois Open Source //
// License. See LICENSE.TXT for details. //
// //
// TODO: consider including an empty blob singleton (possibly UTF-8/16 too). //
// //
///////////////////////////////////////////////////////////////////////////////
#include "dxc/Support/Global.h"
#include "dxc/Support/WinIncludes.h"
#include "dxc/Support/microcom.h"
#include "dxc/Support/Unicode.h"
#include "dxc/Support/FileIOHelper.h"
#include "dxc/Support/WinFunctions.h"
#include "dxc/dxcapi.h"
#include <algorithm>
#include <memory>
#ifdef _WIN32
#include <intsafe.h>
#endif
#define CP_UTF16 1200
struct HeapMalloc : public IMalloc {
public:
ULONG STDMETHODCALLTYPE AddRef() override { return 1; }
ULONG STDMETHODCALLTYPE Release() override { return 1; }
STDMETHODIMP QueryInterface(REFIID iid, void** ppvObject) override {
return DoBasicQueryInterface<IMalloc>(this, iid, ppvObject);
}
virtual void *STDMETHODCALLTYPE Alloc (
/* [annotation][in] */
_In_ SIZE_T cb) override {
return HeapAlloc(GetProcessHeap(), 0, cb);
}
virtual void *STDMETHODCALLTYPE Realloc (
/* [annotation][in] */
_In_opt_ void *pv,
/* [annotation][in] */
_In_ SIZE_T cb) override
{
return HeapReAlloc(GetProcessHeap(), 0, pv, cb);
}
virtual void STDMETHODCALLTYPE Free (
/* [annotation][in] */
_In_opt_ void *pv) override
{
HeapFree(GetProcessHeap(), 0, pv);
}
virtual SIZE_T STDMETHODCALLTYPE GetSize(
/* [annotation][in] */
_In_opt_ _Post_writable_byte_size_(return) void *pv)
{
return HeapSize(GetProcessHeap(), 0, pv);
}
virtual int STDMETHODCALLTYPE DidAlloc(
/* [annotation][in] */
_In_opt_ void *pv)
{
return -1; // don't know
}
virtual void STDMETHODCALLTYPE HeapMinimize(void) {}
};
static HeapMalloc g_HeapMalloc;
namespace hlsl {
IMalloc *GetGlobalHeapMalloc() throw() {
return &g_HeapMalloc;
}
_Use_decl_annotations_
void ReadBinaryFile(IMalloc *pMalloc, LPCWSTR pFileName, void **ppData,
DWORD *pDataSize) {
HANDLE hFile = CreateFileW(pFileName, GENERIC_READ, FILE_SHARE_READ, NULL,
OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, nullptr);
if (hFile == INVALID_HANDLE_VALUE) {
IFT(HRESULT_FROM_WIN32(GetLastError()));
}
CHandle h(hFile);
LARGE_INTEGER FileSize;
if (!GetFileSizeEx(hFile, &FileSize)) {
IFT(HRESULT_FROM_WIN32(GetLastError()));
}
if (FileSize.u.HighPart != 0) {
throw(hlsl::Exception(DXC_E_INPUT_FILE_TOO_LARGE, "input file is too large"));
}
char *pData = (char *)pMalloc->Alloc(FileSize.u.LowPart);
if (!pData) {
throw std::bad_alloc();
}
DWORD BytesRead;
if (!ReadFile(hFile, pData, FileSize.u.LowPart, &BytesRead, nullptr)) {
HRESULT hr = HRESULT_FROM_WIN32(GetLastError());
pMalloc->Free(pData);
throw ::hlsl::Exception(hr);
}
DXASSERT(FileSize.u.LowPart == BytesRead, "ReadFile operation failed");
*ppData = pData;
*pDataSize = FileSize.u.LowPart;
}
_Use_decl_annotations_
void ReadBinaryFile(LPCWSTR pFileName, void **ppData, DWORD *pDataSize) {
return ReadBinaryFile(GetGlobalHeapMalloc(), pFileName, ppData, pDataSize);
}
_Use_decl_annotations_
void WriteBinaryFile(LPCWSTR pFileName, const void *pData, DWORD DataSize) {
HANDLE hFile = CreateFileW(pFileName, GENERIC_WRITE, 0, NULL, CREATE_ALWAYS, FILE_ATTRIBUTE_NORMAL, nullptr);
if(hFile == INVALID_HANDLE_VALUE) {
IFT(HRESULT_FROM_WIN32(GetLastError()));
}
CHandle h(hFile);
DWORD BytesWritten;
if(!WriteFile(hFile, pData, DataSize, &BytesWritten, nullptr)) {
IFT(HRESULT_FROM_WIN32(GetLastError()));
}
DXASSERT(DataSize == BytesWritten, "WriteFile operation failed");
}
_Use_decl_annotations_
UINT32 DxcCodePageFromBytes(const char *bytes, size_t byteLen) throw() {
UINT32 codePage;
if (byteLen >= 4) {
// Now try to use the BOM to check for Unicode encodings
char bom[4] = { bytes[0], bytes[1], bytes[2], bytes[3] };
if (strncmp(bom, "\xef\xbb\xbf", 3) == 0) {
codePage = CP_UTF8;
}
else if (strncmp(bom, "\xff\xfe\x00\x00", 4) == 0) {
codePage = 12000; //UTF-32 LE
}
else if (strncmp(bom, "\x00\x00\xfe\xff", 4) == 0) {
codePage = 12001; //UTF-32 BE
}
else if (strncmp(bom, "\xff\xfe", 2) == 0) {
codePage = 1200; //UTF-16 LE
}
else if (strncmp(bom, "\xfe\xff", 2) == 0) {
codePage = 1201; //UTF-16 BE
}
else {
codePage = CP_ACP;
}
}
else {
codePage = CP_ACP;
}
return codePage;
}
static bool IsSizeWcharAligned(SIZE_T size) { return (size & (sizeof(wchar_t) - 1)) == 0; }
template<typename _char>
bool IsUtfBufferNullTerminated(LPCVOID pBuffer, SIZE_T size) {
return (size >= sizeof(_char) && (size & (sizeof(_char) - 1)) == 0 &&
reinterpret_cast<const _char*>(pBuffer)[(size / sizeof(_char)) - 1] == 0);
}
static bool IsBufferNullTerminated(LPCVOID pBuffer, SIZE_T size, UINT32 codePage) {
switch (codePage) {
case DXC_CP_UTF8: return IsUtfBufferNullTerminated<char>(pBuffer, size);
case DXC_CP_UTF16: return IsUtfBufferNullTerminated<wchar_t>(pBuffer, size);
default: return false;
}
}
template<typename _char>
bool IsUtfBufferEmptyString(LPCVOID pBuffer, SIZE_T size) {
return (size == 0 || (size == sizeof(_char) &&
reinterpret_cast<const _char*>(pBuffer)[0] == 0));
}
static bool IsBufferEmptyString(LPCVOID pBuffer, SIZE_T size, UINT32 codePage) {
switch (codePage) {
case DXC_CP_UTF8: return IsUtfBufferEmptyString<char>(pBuffer, size);
case DXC_CP_UTF16: return IsUtfBufferEmptyString<wchar_t>(pBuffer, size);
default: return IsUtfBufferEmptyString<char>(pBuffer, size);
}
}
class DxcBlobNoEncoding_Impl : public IDxcBlobEncoding {
public:
typedef IDxcBlobEncoding Base;
static const UINT32 CodePage = CP_ACP;
};
class DxcBlobUtf16_Impl : public IDxcBlobUtf16 {
public:
static const UINT32 CodePage = CP_UTF16;
typedef IDxcBlobUtf16 Base;
virtual LPCWSTR STDMETHODCALLTYPE GetStringPointer(void) override {
if (GetBufferSize() < sizeof(wchar_t)) {
return L""; // Special case for empty string blob
}
DXASSERT(IsSizeWcharAligned(GetBufferSize()),
"otherwise, buffer size is not even multiple of wchar_t");
DXASSERT(*(const wchar_t*)
((const BYTE*)GetBufferPointer() + GetBufferSize() - sizeof(wchar_t))
== L'\0',
"otherwise buffer is not null terminated.");
return (LPCWSTR)GetBufferPointer();
}
virtual SIZE_T STDMETHODCALLTYPE GetStringLength(void) override {
SIZE_T bufSize = GetBufferSize();
return bufSize ? (bufSize / sizeof(wchar_t)) - 1 : 0;
}
};
class DxcBlobUtf8_Impl : public IDxcBlobUtf8 {
public:
static const UINT32 CodePage = CP_UTF8;
typedef IDxcBlobUtf8 Base;
virtual LPCSTR STDMETHODCALLTYPE GetStringPointer(void) override {
if (GetBufferSize() < sizeof(char)) {
return ""; // Special case for empty string blob
}
DXASSERT(*((const char*)GetBufferPointer() + GetBufferSize() - 1) == '\0',
"otherwise buffer is not null terminated.");
return (LPCSTR)GetBufferPointer();
}
virtual SIZE_T STDMETHODCALLTYPE GetStringLength(void) override {
SIZE_T bufSize = GetBufferSize();
return bufSize ? (bufSize / sizeof(char)) - 1 : 0;
}
};
template <typename _T>
class InternalDxcBlobEncoding_Impl : public _T {
private:
DXC_MICROCOM_TM_REF_FIELDS() // an underlying m_pMalloc that owns this
LPCVOID m_Buffer = nullptr;
IUnknown* m_Owner = nullptr; // IMalloc when MallocFree is true, owning the buffer
SIZE_T m_BufferSize;
unsigned m_EncodingKnown : 1;
unsigned m_MallocFree : 1;
UINT32 m_CodePage;
public:
DXC_MICROCOM_ADDREF_IMPL(m_dwRef)
ULONG STDMETHODCALLTYPE Release() override {
// Because blobs are also used by tests and utilities, we avoid using TLS.
ULONG result = (ULONG)--m_dwRef;
if (result == 0) {
CComPtr<IMalloc> pTmp(m_pMalloc);
this->~InternalDxcBlobEncoding_Impl();
pTmp->Free(this);
}
return result;
}
DXC_MICROCOM_TM_CTOR(InternalDxcBlobEncoding_Impl)
HRESULT STDMETHODCALLTYPE QueryInterface(REFIID iid, void **ppvObject) override {
return DoBasicQueryInterface<IDxcBlob, IDxcBlobEncoding, typename _T::Base>(this, iid, ppvObject);
}
~InternalDxcBlobEncoding_Impl() {
if (m_MallocFree) {
((IMalloc *)m_Owner)->Free(const_cast<void *>(m_Buffer));
}
if (m_Owner != nullptr) {
m_Owner->Release();
}
}
static HRESULT
CreateFromBlob(_In_ IDxcBlob *pBlob, _In_ IMalloc *pMalloc, bool encodingKnown, UINT32 codePage,
_COM_Outptr_ InternalDxcBlobEncoding_Impl **pEncoding) {
*pEncoding = InternalDxcBlobEncoding_Impl::Alloc(pMalloc);
if (*pEncoding == nullptr) {
return E_OUTOFMEMORY;
}
DXASSERT(_T::CodePage == CP_ACP || (encodingKnown && _T::CodePage == codePage), "encoding must match type");
pBlob->AddRef();
(*pEncoding)->m_Owner = pBlob;
(*pEncoding)->m_Buffer = pBlob->GetBufferPointer();
(*pEncoding)->m_BufferSize = pBlob->GetBufferSize();
(*pEncoding)->m_EncodingKnown = encodingKnown;
(*pEncoding)->m_MallocFree = 0;
(*pEncoding)->m_CodePage = codePage;
(*pEncoding)->AddRef();
return S_OK;
}
static HRESULT
CreateFromMalloc(LPCVOID buffer, IMalloc *pIMalloc, SIZE_T bufferSize, bool encodingKnown,
UINT32 codePage, _COM_Outptr_ InternalDxcBlobEncoding_Impl **pEncoding) {
*pEncoding = InternalDxcBlobEncoding_Impl::Alloc(pIMalloc);
if (*pEncoding == nullptr) {
*pEncoding = nullptr;
return E_OUTOFMEMORY;
}
DXASSERT(_T::CodePage == CP_ACP || (encodingKnown && _T::CodePage == codePage), "encoding must match type");
DXASSERT(buffer || bufferSize == 0, "otherwise, nullptr with non-zero size provided");
pIMalloc->AddRef();
(*pEncoding)->m_Owner = pIMalloc;
(*pEncoding)->m_Buffer = buffer;
(*pEncoding)->m_BufferSize = bufferSize;
(*pEncoding)->m_EncodingKnown = encodingKnown;
(*pEncoding)->m_MallocFree = buffer != nullptr;
(*pEncoding)->m_CodePage = codePage;
(*pEncoding)->AddRef();
return S_OK;
}
void AdjustPtrAndSize(unsigned offset, unsigned size) {
DXASSERT(offset < m_BufferSize, "else caller will overflow");
DXASSERT(offset + size <= m_BufferSize, "else caller will overflow");
m_Buffer = (const uint8_t*)m_Buffer + offset;
m_BufferSize = size;
}
virtual LPVOID STDMETHODCALLTYPE GetBufferPointer(void) override {
return const_cast<LPVOID>(m_Buffer);
}
virtual SIZE_T STDMETHODCALLTYPE GetBufferSize(void) override {
return m_BufferSize;
}
virtual HRESULT STDMETHODCALLTYPE GetEncoding(_Out_ BOOL *pKnown, _Out_ UINT32 *pCodePage) override {
*pKnown = m_EncodingKnown ? TRUE : FALSE;
*pCodePage = m_CodePage;
return S_OK;
}
// Relatively dangerous API. This means the buffer should be pinned for as
// long as this object is alive.
void ClearFreeFlag() { m_MallocFree = 0; }
};
typedef InternalDxcBlobEncoding_Impl<DxcBlobNoEncoding_Impl> InternalDxcBlobEncoding;
typedef InternalDxcBlobEncoding_Impl<DxcBlobUtf16_Impl> InternalDxcBlobUtf16;
typedef InternalDxcBlobEncoding_Impl<DxcBlobUtf8_Impl> InternalDxcBlobUtf8;
static HRESULT CodePageBufferToUtf16(UINT32 codePage, LPCVOID bufferPointer,
SIZE_T bufferSize,
CDxcMallocHeapPtr<WCHAR> &utf16NewCopy,
_Out_ UINT32 *pConvertedCharCount) {
*pConvertedCharCount = 0;
// If the buffer is empty, don't dereference bufferPointer at all.
// Keep the null terminator post-condition.
if (IsBufferEmptyString(bufferPointer, bufferSize, codePage)) {
if (!utf16NewCopy.Allocate(1))
return E_OUTOFMEMORY;
utf16NewCopy.m_pData[0] = L'\0';
DXASSERT(*pConvertedCharCount == 0, "else didn't init properly");
return S_OK;
}
// Calculate the length of the buffer in wchar_t elements.
int numToConvertUTF16 =
MultiByteToWideChar(codePage, MB_ERR_INVALID_CHARS, (LPCSTR)bufferPointer,
bufferSize, nullptr, 0);
if (numToConvertUTF16 == 0)
return HRESULT_FROM_WIN32(GetLastError());
// Add an extra character in case we need it for null-termination
unsigned buffSizeUTF16;
IFR(Int32ToUInt32(numToConvertUTF16, &buffSizeUTF16));
IFR(UInt32Add(buffSizeUTF16, 1, &buffSizeUTF16));
IFR(UInt32Mult(buffSizeUTF16, sizeof(WCHAR), &buffSizeUTF16));
utf16NewCopy.AllocateBytes(buffSizeUTF16);
IFROOM(utf16NewCopy.m_pData);
int numActuallyConvertedUTF16 =
MultiByteToWideChar(codePage, MB_ERR_INVALID_CHARS, (LPCSTR)bufferPointer,
bufferSize, utf16NewCopy, buffSizeUTF16);
if (numActuallyConvertedUTF16 == 0)
return HRESULT_FROM_WIN32(GetLastError());
if (numActuallyConvertedUTF16 < 0)
return E_OUTOFMEMORY;
// If all we have is null terminator, return with zero count.
if (utf16NewCopy.m_pData[0] == L'\0') {
DXASSERT(*pConvertedCharCount == 0, "else didn't init properly");
return S_OK;
}
if ((UINT32)numActuallyConvertedUTF16 < (buffSizeUTF16 / sizeof(wchar_t)) &&
utf16NewCopy.m_pData[numActuallyConvertedUTF16 - 1] != L'\0') {
utf16NewCopy.m_pData[numActuallyConvertedUTF16++] = L'\0';
}
*pConvertedCharCount = (UINT32)numActuallyConvertedUTF16;
return S_OK;
}
static HRESULT CodePageBufferToUtf8(UINT32 codePage, LPCVOID bufferPointer,
SIZE_T bufferSize,
IMalloc *pMalloc,
CDxcMallocHeapPtr<char> &utf8NewCopy,
_Out_ UINT32 *pConvertedCharCount) {
*pConvertedCharCount = 0;
CDxcMallocHeapPtr<WCHAR> utf16NewCopy(pMalloc);
UINT32 utf16CharCount = 0;
const WCHAR *utf16Chars = nullptr;
if (codePage == CP_UTF16) {
DXASSERT(IsSizeWcharAligned(bufferSize), "otherwise, odd buffer size with UTF-16");
utf16Chars = (const WCHAR*)bufferPointer;
utf16CharCount = bufferSize / sizeof(wchar_t);
} else if (bufferSize) {
IFR(CodePageBufferToUtf16(codePage, bufferPointer, bufferSize,
utf16NewCopy, &utf16CharCount));
utf16Chars = utf16NewCopy.m_pData;
}
// If the buffer is empty, don't dereference bufferPointer at all.
// Keep the null terminator post-condition.
if (IsUtfBufferEmptyString<wchar_t>(utf16Chars, utf16CharCount)) {
if (!utf8NewCopy.Allocate(1))
return E_OUTOFMEMORY;
DXASSERT(*pConvertedCharCount == 0, "else didn't init properly");
utf8NewCopy.m_pData[0] = '\0';
return S_OK;
}
int numToConvertUtf8 =
WideCharToMultiByte(CP_UTF8, 0, utf16Chars, utf16CharCount,
NULL, 0, NULL, NULL);
if (numToConvertUtf8 == 0)
return HRESULT_FROM_WIN32(GetLastError());
UINT32 buffSizeUtf8;
IFR(Int32ToUInt32(numToConvertUtf8, &buffSizeUtf8));
if (!IsBufferNullTerminated(utf16Chars, utf16CharCount * sizeof(wchar_t), CP_UTF16)) {
// If original size doesn't include null-terminator,
// we have to add one to the converted buffer.
IFR(UInt32Add(buffSizeUtf8, 1, &buffSizeUtf8));
}
utf8NewCopy.AllocateBytes(buffSizeUtf8);
IFROOM(utf8NewCopy.m_pData);
int numActuallyConvertedUtf8 =
WideCharToMultiByte(CP_UTF8, 0, utf16Chars, utf16CharCount,
utf8NewCopy, buffSizeUtf8, NULL, NULL);
if (numActuallyConvertedUtf8 == 0)
return HRESULT_FROM_WIN32(GetLastError());
if (numActuallyConvertedUtf8 < 0)
return E_OUTOFMEMORY;
if ((UINT32)numActuallyConvertedUtf8 < buffSizeUtf8 &&
utf8NewCopy.m_pData[numActuallyConvertedUtf8 - 1] != '\0') {
utf8NewCopy.m_pData[numActuallyConvertedUtf8++] = '\0';
}
*pConvertedCharCount = (UINT32)numActuallyConvertedUtf8;
return S_OK;
}
static bool TryCreateEmptyBlobUtf(
UINT32 codePage, IMalloc *pMalloc, IDxcBlobEncoding **ppBlobEncoding) {
if (codePage == CP_UTF8) {
InternalDxcBlobUtf8 *internalUtf8;
IFR(InternalDxcBlobUtf8::CreateFromMalloc(
nullptr, pMalloc, 0, true, codePage, &internalUtf8));
*ppBlobEncoding = internalUtf8;
return true;
} else if (codePage == CP_UTF16) {
InternalDxcBlobUtf16 *internalUtf16;
IFR(InternalDxcBlobUtf16::CreateFromMalloc(
nullptr, pMalloc, 0, true, codePage, &internalUtf16));
*ppBlobEncoding = internalUtf16;
return true;
}
return false;
}
static bool TryCreateBlobUtfFromBlob(
IDxcBlob *pFromBlob, UINT32 codePage, IMalloc *pMalloc,
IDxcBlobEncoding **ppBlobEncoding) {
// Try to create a IDxcBlobUtf8 or IDxcBlobUtf16
if (IsBlobNullOrEmpty(pFromBlob)) {
return TryCreateEmptyBlobUtf(codePage, pMalloc, ppBlobEncoding);
} else if (IsBufferNullTerminated(pFromBlob->GetBufferPointer(),
pFromBlob->GetBufferSize(), codePage)) {
if (codePage == CP_UTF8) {
InternalDxcBlobUtf8 *internalUtf8;
IFR(InternalDxcBlobUtf8::CreateFromBlob(
pFromBlob, pMalloc, true, codePage, &internalUtf8));
*ppBlobEncoding = internalUtf8;
return true;
} else if (codePage == CP_UTF16) {
InternalDxcBlobUtf16 *internalUtf16;
IFR(InternalDxcBlobUtf16::CreateFromBlob(
pFromBlob, pMalloc, true, codePage, &internalUtf16));
*ppBlobEncoding = internalUtf16;
return true;
}
}
return false;
}
HRESULT DxcCreateBlob(
LPCVOID pPtr, SIZE_T size, bool bPinned, bool bCopy,
bool encodingKnown, UINT32 codePage,
IMalloc *pMalloc, IDxcBlobEncoding **ppBlobEncoding) throw() {
IFRBOOL(!(bPinned && bCopy), E_INVALIDARG);
IFRBOOL(ppBlobEncoding, E_INVALIDARG);
*ppBlobEncoding = nullptr;
bool bNullTerminated = encodingKnown ? IsBufferNullTerminated(pPtr, size, codePage) : false;
if (!pMalloc)
pMalloc = DxcGetThreadMallocNoRef();
// Handle empty blob
if (!pPtr || !size) {
if (encodingKnown && TryCreateEmptyBlobUtf(codePage, pMalloc, ppBlobEncoding))
return S_OK;
InternalDxcBlobEncoding *pInternalEncoding;
IFR(InternalDxcBlobEncoding::CreateFromMalloc(nullptr, pMalloc, 0, encodingKnown, codePage, &pInternalEncoding));
*ppBlobEncoding = pInternalEncoding;
}
if (bPinned) {
if (encodingKnown) {
if (bNullTerminated) {
if (codePage == CP_UTF8) {
InternalDxcBlobUtf8 *internalUtf8;
IFR(InternalDxcBlobUtf8::CreateFromMalloc(
pPtr, pMalloc, size, true, codePage, &internalUtf8));
*ppBlobEncoding = internalUtf8;
internalUtf8->ClearFreeFlag();
return S_OK;
} else if (codePage == CP_UTF16) {
InternalDxcBlobUtf16 *internalUtf16;
IFR(InternalDxcBlobUtf16::CreateFromMalloc(
pPtr, pMalloc, size, true, codePage, &internalUtf16));
*ppBlobEncoding = internalUtf16;
internalUtf16->ClearFreeFlag();
return S_OK;
}
}
}
InternalDxcBlobEncoding *internalEncoding;
IFR(InternalDxcBlobEncoding::CreateFromMalloc(
pPtr, pMalloc, size, encodingKnown, codePage, &internalEncoding));
*ppBlobEncoding = internalEncoding;
internalEncoding->ClearFreeFlag();
return S_OK;
}
void *pData = const_cast<void*>(pPtr);
SIZE_T newSize = size;
CDxcMallocHeapPtr<char> heapCopy(pMalloc);
if (bCopy) {
if (encodingKnown) {
if (!bNullTerminated) {
if (codePage == CP_UTF8) {
newSize += sizeof(char);
bNullTerminated = true;
} else if (codePage == CP_UTF16) {
newSize += sizeof(wchar_t);
bNullTerminated = true;
}
}
}
heapCopy.AllocateBytes(newSize);
pData = heapCopy.m_pData;
if (pData == nullptr)
return E_OUTOFMEMORY;
if (pPtr)
memcpy(pData, pPtr, size);
else
memset(pData, 0, size);
}
if (bNullTerminated && codePage == CP_UTF8) {
if (bCopy && newSize > size)
((char*)pData)[newSize - 1] = 0;
InternalDxcBlobUtf8 *internalUtf8;
IFR(InternalDxcBlobUtf8::CreateFromMalloc(
pData, pMalloc, newSize, true, codePage, &internalUtf8));
*ppBlobEncoding = internalUtf8;
} else if (bNullTerminated && codePage == CP_UTF16) {
if (bCopy && newSize > size)
((wchar_t*)pData)[(newSize / sizeof(wchar_t)) - 1] = 0;
InternalDxcBlobUtf16 *internalUtf16;
IFR(InternalDxcBlobUtf16::CreateFromMalloc(
pData, pMalloc, newSize, true, codePage, &internalUtf16));
*ppBlobEncoding = internalUtf16;
} else {
InternalDxcBlobEncoding *internalEncoding;
IFR(InternalDxcBlobEncoding::CreateFromMalloc(
pData, pMalloc, newSize, encodingKnown, codePage, &internalEncoding));
*ppBlobEncoding = internalEncoding;
}
if (bCopy)
heapCopy.Detach();
return S_OK;
}
HRESULT DxcCreateBlobEncodingFromBlob(
IDxcBlob *pFromBlob, UINT32 offset, UINT32 length,
bool encodingKnown, UINT32 codePage,
IMalloc *pMalloc, IDxcBlobEncoding **ppBlobEncoding) throw() {
IFRBOOL(pFromBlob, E_POINTER);
IFRBOOL(ppBlobEncoding, E_POINTER);
*ppBlobEncoding = nullptr;
if (!pMalloc)
pMalloc = DxcGetThreadMallocNoRef();
InternalDxcBlobEncoding *internalEncoding;
if (offset || length) {
UINT32 end;
IFR(UInt32Add(offset, length, &end));
SIZE_T blobSize = pFromBlob->GetBufferSize();
if (end > blobSize)
return E_INVALIDARG;
IFR(InternalDxcBlobEncoding::CreateFromBlob(
pFromBlob, pMalloc, encodingKnown, codePage, &internalEncoding));
internalEncoding->AdjustPtrAndSize(offset, length);
*ppBlobEncoding = internalEncoding;
return S_OK;
}
if (!encodingKnown || codePage == CP_UTF8) {
IDxcBlobUtf8 *pBlobUtf8;
if(SUCCEEDED(pFromBlob->QueryInterface(&pBlobUtf8))) {
*ppBlobEncoding = pBlobUtf8;
return S_OK;
}
}
if (!encodingKnown || codePage == CP_UTF16) {
IDxcBlobUtf16 *pBlobUtf16;
if (SUCCEEDED(pFromBlob->QueryInterface(&pBlobUtf16))) {
*ppBlobEncoding = pBlobUtf16;
return S_OK;
}
}
CComPtr<IDxcBlobEncoding> pBlobEncoding;
if (SUCCEEDED(pFromBlob->QueryInterface(&pBlobEncoding))) {
BOOL thisEncodingKnown;
UINT32 thisEncoding;
IFR(pBlobEncoding->GetEncoding(&thisEncodingKnown, &thisEncoding));
bool encodingMatches = thisEncodingKnown && encodingKnown &&
codePage == thisEncoding;
if (!encodingKnown && thisEncodingKnown) {
codePage = thisEncoding;
encodingKnown = thisEncodingKnown;
encodingMatches = true;
}
if (encodingMatches) {
if (!TryCreateBlobUtfFromBlob(pFromBlob, codePage, pMalloc, ppBlobEncoding)) {
*ppBlobEncoding = pBlobEncoding.Detach();
}
return S_OK;
}
if (encodingKnown) {
IFR(InternalDxcBlobEncoding::CreateFromBlob(
pFromBlob, pMalloc, true, codePage, &internalEncoding));
*ppBlobEncoding = internalEncoding;
return S_OK;
}
DXASSERT(!encodingKnown && !thisEncodingKnown, "otherwise, missing case");
*ppBlobEncoding = pBlobEncoding.Detach();
return S_OK;
}
if (encodingKnown && TryCreateBlobUtfFromBlob(pFromBlob, codePage, pMalloc, ppBlobEncoding)) {
return S_OK;
}
IFR(InternalDxcBlobEncoding::CreateFromBlob(
pFromBlob, pMalloc, encodingKnown, codePage, &internalEncoding));
*ppBlobEncoding = internalEncoding;
return S_OK;
}
_Use_decl_annotations_
HRESULT DxcCreateBlobFromBlob(
IDxcBlob *pBlob, UINT32 offset, UINT32 length, IDxcBlob **ppResult) throw() {
IFRBOOL(ppResult, E_POINTER);
*ppResult = nullptr;
IDxcBlobEncoding *pResult;
IFR(DxcCreateBlobEncodingFromBlob(pBlob, offset, length, false, 0, DxcGetThreadMallocNoRef(), &pResult));
*ppResult = pResult;
return S_OK;
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobOnMalloc(LPCVOID pData, IMalloc *pIMalloc, UINT32 size, IDxcBlob **ppResult) throw() {
IFRBOOL(ppResult, E_POINTER);
*ppResult = nullptr;
IDxcBlobEncoding *pResult;
IFR(DxcCreateBlob(pData, size, false, false, false, 0, pIMalloc, &pResult));
*ppResult = pResult;
return S_OK;
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobOnHeapCopy(_In_bytecount_(size) LPCVOID pData, UINT32 size,
_COM_Outptr_ IDxcBlob **ppResult) throw() {
IFRBOOL(ppResult, E_POINTER);
*ppResult = nullptr;
IDxcBlobEncoding *pResult;
IFR(DxcCreateBlob(pData, size, false, true, false, 0, DxcGetThreadMallocNoRef(), &pResult));
*ppResult = pResult;
return S_OK;
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobFromFile(IMalloc *pMalloc, LPCWSTR pFileName, UINT32 *pCodePage,
IDxcBlobEncoding **ppBlobEncoding) throw() {
if (pFileName == nullptr || ppBlobEncoding == nullptr) {
return E_POINTER;
}
LPVOID pData;
DWORD dataSize;
*ppBlobEncoding = nullptr;
try {
ReadBinaryFile(pMalloc, pFileName, &pData, &dataSize);
}
CATCH_CPP_RETURN_HRESULT();
bool known = (pCodePage != nullptr);
UINT32 codePage = (pCodePage != nullptr) ? *pCodePage : 0;
HRESULT hr = DxcCreateBlob(pData, dataSize, false, false, known, codePage, pMalloc, ppBlobEncoding);
if (FAILED(hr))
pMalloc->Free(pData);
return hr;
}
_Use_decl_annotations_
HRESULT DxcCreateBlobFromFile(LPCWSTR pFileName, UINT32 *pCodePage,
IDxcBlobEncoding **ppBlobEncoding) throw() {
return DxcCreateBlobFromFile(DxcGetThreadMallocNoRef(), pFileName, pCodePage, ppBlobEncoding);
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobWithEncodingSet(IMalloc *pMalloc, IDxcBlob *pBlob, UINT32 codePage,
IDxcBlobEncoding **ppBlobEncoding) throw() {
return DxcCreateBlobEncodingFromBlob(pBlob, 0, 0, true, codePage, pMalloc, ppBlobEncoding);
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobWithEncodingSet(IDxcBlob *pBlob, UINT32 codePage,
IDxcBlobEncoding **ppBlobEncoding) throw() {
return DxcCreateBlobEncodingFromBlob(pBlob, 0, 0, true, codePage, nullptr, ppBlobEncoding);
}
_Use_decl_annotations_
HRESULT DxcCreateBlobWithEncodingFromPinned(LPCVOID pText, UINT32 size,
UINT32 codePage,
IDxcBlobEncoding **pBlobEncoding) throw() {
return DxcCreateBlob(pText, size, true, false, true, codePage, nullptr, pBlobEncoding);
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobWithEncodingFromStream(IStream *pStream, bool newInstanceAlways,
UINT32 codePage,
IDxcBlobEncoding **ppBlobEncoding) throw() {
IFRBOOL(ppBlobEncoding, E_POINTER);
*ppBlobEncoding = nullptr;
if (pStream == nullptr) {
return S_OK;
}
// Try to reuse the existing stream.
if (!newInstanceAlways) {
CComPtr<IDxcBlobEncoding> blobEncoding;
if (SUCCEEDED(pStream->QueryInterface(&blobEncoding))) {
*ppBlobEncoding = blobEncoding.Detach();
return S_OK;
}
}
// Layer over the blob if possible.
CComPtr<IDxcBlob> blob;
if (SUCCEEDED(pStream->QueryInterface(&blob))) {
return DxcCreateBlobWithEncodingSet(blob, codePage, ppBlobEncoding);
}
// Create a copy of contents, last resort.
// TODO: implement when we find this codepath internally
return E_NOTIMPL;
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobWithEncodingOnHeapCopy(LPCVOID pText, UINT32 size, UINT32 codePage,
IDxcBlobEncoding **pBlobEncoding) throw() {
return DxcCreateBlob(pText, size, false, true, true, codePage, nullptr, pBlobEncoding);
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobWithEncodingOnMalloc(LPCVOID pText, IMalloc *pIMalloc, UINT32 size, UINT32 codePage,
IDxcBlobEncoding **pBlobEncoding) throw() {
return DxcCreateBlob(pText, size, false, false, true, codePage, pIMalloc, pBlobEncoding);
}
_Use_decl_annotations_
HRESULT
DxcCreateBlobWithEncodingOnMallocCopy(IMalloc *pIMalloc, LPCVOID pText, UINT32 size, UINT32 codePage,
IDxcBlobEncoding **ppBlobEncoding) throw() {
return DxcCreateBlob(pText, size, false, true, true, codePage, pIMalloc, ppBlobEncoding);
}
_Use_decl_annotations_
HRESULT DxcGetBlobAsUtf8(IDxcBlob *pBlob, IMalloc *pMalloc, IDxcBlobUtf8 **pBlobEncoding) throw() {
IFRBOOL(pBlob, E_POINTER);
IFRBOOL(pBlobEncoding, E_POINTER);
*pBlobEncoding = nullptr;
if (SUCCEEDED(pBlob->QueryInterface(pBlobEncoding)))
return S_OK;
HRESULT hr;
CComPtr<IDxcBlobEncoding> pSourceBlob;
UINT32 codePage = CP_ACP;
BOOL known = FALSE;
if (SUCCEEDED(pBlob->QueryInterface(&pSourceBlob))) {
if (FAILED(hr = pSourceBlob->GetEncoding(&known, &codePage)))
return hr;
}
SIZE_T blobLen = pBlob->GetBufferSize();
if (!known) {
codePage = DxcCodePageFromBytes((char *)pBlob->GetBufferPointer(), blobLen);
}
if (!pMalloc)
pMalloc = DxcGetThreadMallocNoRef();
CDxcMallocHeapPtr<char> utf8NewCopy(pMalloc);
UINT32 utf8CharCount = 0;
// Reuse or copy the underlying blob depending on null-termination
if (codePage == CP_UTF8) {
utf8CharCount = blobLen;
if (IsBufferNullTerminated(pBlob->GetBufferPointer(), blobLen, CP_UTF8)) {
// Already null-terminated, reference other blob's memory
InternalDxcBlobUtf8* internalEncoding;
hr = InternalDxcBlobUtf8::CreateFromBlob(pBlob, pMalloc, true, CP_UTF8, &internalEncoding);
if (SUCCEEDED(hr)) {
*pBlobEncoding = internalEncoding;
}
return hr;
} else {
// Copy to new buffer and null-terminate
if(!utf8NewCopy.Allocate(utf8CharCount + 1))
return E_OUTOFMEMORY;
memcpy(utf8NewCopy.m_pData, pBlob->GetBufferPointer(), blobLen);
utf8NewCopy.m_pData[utf8CharCount++] = 0;
}
} else {
// Convert and create a blob that owns the encoding.
if (FAILED(
hr = CodePageBufferToUtf8(codePage, pBlob->GetBufferPointer(), blobLen,
pMalloc, utf8NewCopy, &utf8CharCount))) {
return hr;
}
DXASSERT(!utf8CharCount ||
IsBufferNullTerminated(utf8NewCopy.m_pData, utf8CharCount, CP_UTF8),
"otherwise, CodePageBufferToUtf8 failed to null-terminate buffer.");
}
// At this point, we have new utf8NewCopy to wrap in a blob
InternalDxcBlobUtf8* internalEncoding;
hr = InternalDxcBlobUtf8::CreateFromMalloc(
utf8NewCopy.m_pData, pMalloc,
utf8CharCount, true, CP_UTF8, &internalEncoding);
if (SUCCEEDED(hr)) {
*pBlobEncoding = internalEncoding;
utf8NewCopy.Detach();
}
return hr;
}
// This is kept for compatibility.
HRESULT
DxcGetBlobAsUtf8NullTerm(_In_ IDxcBlob *pBlob,
_COM_Outptr_ IDxcBlobEncoding **ppBlobEncoding) throw() {
IFRBOOL(pBlob, E_POINTER);
IFRBOOL(ppBlobEncoding, E_POINTER);
*ppBlobEncoding = nullptr;
CComPtr<IDxcBlobUtf8> pConverted;
IFR(DxcGetBlobAsUtf8(pBlob, DxcGetThreadMallocNoRef(), &pConverted));
pConverted->QueryInterface(ppBlobEncoding);
return S_OK;
}
_Use_decl_annotations_
HRESULT DxcGetBlobAsUtf16(IDxcBlob *pBlob, IMalloc *pMalloc, IDxcBlobUtf16 **pBlobEncoding) throw() {
IFRBOOL(pBlob, E_POINTER);
IFRBOOL(pBlobEncoding, E_POINTER);
*pBlobEncoding = nullptr;
if (SUCCEEDED(pBlob->QueryInterface(pBlobEncoding)))
return S_OK;
HRESULT hr;
CComPtr<IDxcBlobEncoding> pSourceBlob;
UINT32 codePage = CP_ACP;
BOOL known = FALSE;
if (SUCCEEDED(pBlob->QueryInterface(&pSourceBlob))) {
if (FAILED(hr = pSourceBlob->GetEncoding(&known, &codePage)))
return hr;
}
SIZE_T blobLen = pBlob->GetBufferSize();
if (!known) {
codePage = DxcCodePageFromBytes((char *)pBlob->GetBufferPointer(), blobLen);
}
if (!pMalloc)
pMalloc = DxcGetThreadMallocNoRef();
CDxcMallocHeapPtr<WCHAR> utf16NewCopy(pMalloc);
UINT32 utf16CharCount = 0;
// Reuse or copy the underlying blob depending on null-termination
if (codePage == CP_UTF16) {
DXASSERT(IsSizeWcharAligned(blobLen),
"otherwise, UTF-16 blob size not evenly divisible by 2");
utf16CharCount = blobLen / sizeof(wchar_t);
if (IsBufferNullTerminated(pBlob->GetBufferPointer(), blobLen, CP_UTF16)) {
// Already null-terminated, reference other blob's memory
InternalDxcBlobUtf16* internalEncoding;
hr = InternalDxcBlobUtf16::CreateFromBlob(pBlob, pMalloc, true, CP_UTF16, &internalEncoding);
if (SUCCEEDED(hr)) {
*pBlobEncoding = internalEncoding;
}
return hr;
} else {
// Copy to new buffer and null-terminate
if(!utf16NewCopy.Allocate(utf16CharCount + 1))
return E_OUTOFMEMORY;
memcpy(utf16NewCopy.m_pData, pBlob->GetBufferPointer(), blobLen);
utf16NewCopy.m_pData[utf16CharCount++] = 0;
}
} else {
// Convert and create a blob that owns the encoding.
if (FAILED(
hr = CodePageBufferToUtf16(codePage, pBlob->GetBufferPointer(), blobLen,
utf16NewCopy, &utf16CharCount))) {
return hr;
}
}
// At this point, we have new utf16NewCopy to wrap in a blob
DXASSERT(!utf16CharCount ||
IsBufferNullTerminated(utf16NewCopy.m_pData, utf16CharCount * sizeof(wchar_t), CP_UTF16),
"otherwise, failed to null-terminate buffer.");
InternalDxcBlobUtf16* internalEncoding;
hr = InternalDxcBlobUtf16::CreateFromMalloc(
utf16NewCopy.m_pData, pMalloc,
utf16CharCount * sizeof(WCHAR), true, CP_UTF16, &internalEncoding);
if (SUCCEEDED(hr)) {
*pBlobEncoding = internalEncoding;
utf16NewCopy.Detach();
}
return hr;
}
bool IsBlobNullOrEmpty(_In_opt_ IDxcBlob *pBlob) throw() {
return pBlob == nullptr || pBlob->GetBufferSize() == 0;
}
///////////////////////////////////////////////////////////////////////////////
// Stream implementations.
class MemoryStream : public AbstractMemoryStream, public IDxcBlob {
private:
DXC_MICROCOM_TM_REF_FIELDS()
LPBYTE m_pMemory = nullptr;
ULONG m_offset = 0;
ULONG m_size = 0;
ULONG m_allocSize = 0;
public:
DXC_MICROCOM_ADDREF_IMPL(m_dwRef)
ULONG STDMETHODCALLTYPE Release() override {
// Because memory streams are also used by tests and utilities,
// we avoid using TLS.
ULONG result = (ULONG)--m_dwRef;
if (result == 0) {
CComPtr<IMalloc> pTmp(m_pMalloc);
this->~MemoryStream();
pTmp->Free(this);
}
return result;
}
DXC_MICROCOM_TM_CTOR(MemoryStream)
HRESULT STDMETHODCALLTYPE QueryInterface(REFIID iid, void **ppvObject) override {
return DoBasicQueryInterface<IStream, ISequentialStream, IDxcBlob>(this, iid, ppvObject);
}
~MemoryStream() {
Reset();
}
HRESULT Grow(ULONG targetSize) {
if (targetSize < m_allocSize * 2) {
targetSize = m_allocSize * 2;
}
return Reserve(targetSize);
}
void Reset() {
if (m_pMemory != nullptr) {
m_pMalloc->Free(m_pMemory);
}
m_pMemory = nullptr;
m_offset = 0;
m_size = 0;
m_allocSize = 0;
}
// AbstractMemoryStream implementation.
LPBYTE GetPtr() throw() override {
return m_pMemory;
}
ULONG GetPtrSize() throw() override {
return m_size;
}
LPBYTE Detach() throw() override {
LPBYTE result = m_pMemory;
m_pMemory = nullptr;
Reset();
return result;
}
UINT64 GetPosition() throw() override {
return m_offset;
}
HRESULT Reserve(ULONG targetSize) throw() override {
if (m_pMemory == nullptr) {
m_pMemory = (LPBYTE)m_pMalloc->Alloc(targetSize);
if (m_pMemory == nullptr) {
return E_OUTOFMEMORY;
}
}
else {
void* newPtr = m_pMalloc->Realloc(m_pMemory, targetSize);
if (newPtr == nullptr) {
return E_OUTOFMEMORY;
}
m_pMemory = (LPBYTE)newPtr;
}
m_allocSize = targetSize;
return S_OK;
}
// IDxcBlob implementation. Requires no further writes.
LPVOID STDMETHODCALLTYPE GetBufferPointer(void) override {
return m_pMemory;
}
SIZE_T STDMETHODCALLTYPE GetBufferSize(void) override {
return m_size;
}
// ISequentialStream implementation.
HRESULT STDMETHODCALLTYPE Read(void* pv, ULONG cb, ULONG* pcbRead) override {
if (!pv || !pcbRead) return E_POINTER;
// If we seeked past the end, read nothing.
if (m_offset > m_size) {
*pcbRead = 0;
return S_FALSE;
}
ULONG cbLeft = m_size - m_offset;
*pcbRead = std::min(cb, cbLeft);
memcpy(pv, m_pMemory + m_offset, *pcbRead);
m_offset += *pcbRead;
return (*pcbRead == cb) ? S_OK : S_FALSE;
}
HRESULT STDMETHODCALLTYPE Write(void const* pv, ULONG cb, ULONG* pcbWritten) override {
if (!pv || !pcbWritten) return E_POINTER;
if (cb + m_offset > m_allocSize) {
HRESULT hr = Grow(cb + m_offset);
if (FAILED(hr)) return hr;
// Implicitly extend as needed with zeroes.
if (m_offset > m_size) {
memset(m_pMemory + m_size, 0, m_offset - m_size);
}
}
*pcbWritten = cb;
memcpy(m_pMemory + m_offset, pv, cb);
m_offset += cb;
m_size = std::max(m_size, m_offset);
return S_OK;
}
// IStream implementation.
HRESULT STDMETHODCALLTYPE SetSize(ULARGE_INTEGER val) override {
if (val.u.HighPart != 0) {
return E_OUTOFMEMORY;
}
if (val.u.LowPart > m_allocSize) {
return Grow(m_allocSize);
}
if (val.u.LowPart < m_size) {
m_size = val.u.LowPart;
m_offset = std::min(m_offset, m_size);
}
else if (val.u.LowPart > m_size) {
memset(m_pMemory + m_size, 0, val.u.LowPart - m_size);
m_size = val.u.LowPart;
}
return S_OK;
}
HRESULT STDMETHODCALLTYPE CopyTo(IStream *, ULARGE_INTEGER,
ULARGE_INTEGER *,
ULARGE_INTEGER *) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE Commit(DWORD) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE Revert(void) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE LockRegion(ULARGE_INTEGER,
ULARGE_INTEGER, DWORD) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE UnlockRegion(ULARGE_INTEGER,
ULARGE_INTEGER, DWORD) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE Clone(IStream **) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE Seek(LARGE_INTEGER liDistanceToMove,
DWORD dwOrigin,
ULARGE_INTEGER *lpNewFilePointer) override {
if (lpNewFilePointer != nullptr) {
lpNewFilePointer->QuadPart = 0;
}
if (liDistanceToMove.u.HighPart != 0) {
return E_FAIL;
}
ULONG targetOffset;
switch (dwOrigin) {
case STREAM_SEEK_SET:
targetOffset = liDistanceToMove.u.LowPart;
break;
case STREAM_SEEK_CUR:
targetOffset = liDistanceToMove.u.LowPart + m_offset;
break;
case STREAM_SEEK_END:
targetOffset = liDistanceToMove.u.LowPart + m_size;
break;
default:
return STG_E_INVALIDFUNCTION;
}
m_offset = targetOffset;
if (lpNewFilePointer != nullptr) {
lpNewFilePointer->u.LowPart = targetOffset;
}
return S_OK;
}
HRESULT STDMETHODCALLTYPE Stat(STATSTG *pStatstg,
DWORD grfStatFlag) override {
if (pStatstg == nullptr) {
return E_POINTER;
}
ZeroMemory(pStatstg, sizeof(*pStatstg));
pStatstg->type = STGTY_STREAM;
pStatstg->cbSize.u.LowPart = m_size;
return S_OK;
}
};
class ReadOnlyBlobStream : public IStream {
private:
DXC_MICROCOM_TM_REF_FIELDS()
CComPtr<IDxcBlob> m_pSource;
LPBYTE m_pMemory;
ULONG m_offset;
ULONG m_size;
public:
DXC_MICROCOM_TM_ADDREF_RELEASE_IMPL()
DXC_MICROCOM_TM_CTOR(ReadOnlyBlobStream)
HRESULT STDMETHODCALLTYPE QueryInterface(REFIID iid, void **ppvObject) override {
return DoBasicQueryInterface<IStream, ISequentialStream>(this, iid, ppvObject);
}
void Init(IDxcBlob *pSource) {
m_pSource = pSource;
m_offset = 0;
m_size = m_pSource->GetBufferSize();
m_pMemory = (LPBYTE)m_pSource->GetBufferPointer();
// If Utf8Blob, exclude terminating null character
CComPtr<IDxcBlobUtf8> utf8Source;
if (m_size && SUCCEEDED(pSource->QueryInterface(&utf8Source)))
m_size = utf8Source->GetStringLength();
}
// ISequentialStream implementation.
HRESULT STDMETHODCALLTYPE Read(void *pv, ULONG cb,
ULONG *pcbRead) override {
if (!pv || !pcbRead)
return E_POINTER;
ULONG cbLeft = m_size - m_offset;
*pcbRead = std::min(cb, cbLeft);
memcpy(pv, m_pMemory + m_offset, *pcbRead);
m_offset += *pcbRead;
return (*pcbRead == cb) ? S_OK : S_FALSE;
}
HRESULT STDMETHODCALLTYPE Write(void const *, ULONG, ULONG *) override {
return STG_E_ACCESSDENIED;
}
// IStream implementation.
HRESULT STDMETHODCALLTYPE SetSize(ULARGE_INTEGER val) override {
return STG_E_ACCESSDENIED;
}
HRESULT STDMETHODCALLTYPE CopyTo(IStream *, ULARGE_INTEGER,
ULARGE_INTEGER *,
ULARGE_INTEGER *) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE Commit(DWORD) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE Revert(void) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE LockRegion(ULARGE_INTEGER,
ULARGE_INTEGER, DWORD) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE UnlockRegion(ULARGE_INTEGER,
ULARGE_INTEGER, DWORD) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE Clone(IStream **) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE Seek(LARGE_INTEGER liDistanceToMove,
DWORD dwOrigin,
ULARGE_INTEGER *lpNewFilePointer) override {
if (lpNewFilePointer != nullptr) {
lpNewFilePointer->QuadPart = 0;
}
if (liDistanceToMove.u.HighPart != 0) {
return E_FAIL;
}
ULONG targetOffset;
switch (dwOrigin) {
case STREAM_SEEK_SET:
targetOffset = liDistanceToMove.u.LowPart;
break;
case STREAM_SEEK_CUR:
targetOffset = liDistanceToMove.u.LowPart + m_offset;
break;
case STREAM_SEEK_END:
targetOffset = liDistanceToMove.u.LowPart + m_size;
break;
default:
return STG_E_INVALIDFUNCTION;
}
// Do not implicility extend.
if (targetOffset > m_size) {
return E_FAIL;
}
m_offset = targetOffset;
if (lpNewFilePointer != nullptr) {
lpNewFilePointer->u.LowPart = targetOffset;
}
return S_OK;
}
HRESULT STDMETHODCALLTYPE Stat(STATSTG *pStatstg,
DWORD grfStatFlag) override {
if (pStatstg == nullptr) {
return E_POINTER;
}
ZeroMemory(pStatstg, sizeof(*pStatstg));
pStatstg->type = STGTY_STREAM;
pStatstg->cbSize.u.LowPart = m_size;
return S_OK;
}
};
class FixedSizeMemoryStream : public AbstractMemoryStream {
private:
DXC_MICROCOM_TM_REF_FIELDS()
LPBYTE m_pBuffer;
ULONG m_offset;
ULONG m_size;
public:
DXC_MICROCOM_TM_ADDREF_RELEASE_IMPL()
DXC_MICROCOM_TM_CTOR(FixedSizeMemoryStream)
HRESULT STDMETHODCALLTYPE QueryInterface(REFIID iid, void **ppvObject) override {
return DoBasicQueryInterface<IStream, ISequentialStream>(this, iid, ppvObject);
}
void Init(LPBYTE pBuffer, size_t size) {
m_pBuffer = pBuffer;
m_offset = 0;
m_size = size;
}
// ISequentialStream implementation.
HRESULT STDMETHODCALLTYPE Read(void *pv, ULONG cb, ULONG *pcbRead) override {
if (!pv || !pcbRead)
return E_POINTER;
ULONG cbLeft = m_size - m_offset;
*pcbRead = std::min(cb, cbLeft);
memcpy(pv, m_pBuffer + m_offset, *pcbRead);
m_offset += *pcbRead;
return (*pcbRead == cb) ? S_OK : S_FALSE;
}
HRESULT STDMETHODCALLTYPE Write(void const *pv, ULONG cb, ULONG *pcbWritten) override {
if (!pv || !pcbWritten)
return E_POINTER;
ULONG cbLeft = m_size - m_offset;
*pcbWritten = std::min(cb, cbLeft);
memcpy(m_pBuffer + m_offset, pv, *pcbWritten);
m_offset += *pcbWritten;
return (*pcbWritten == cb) ? S_OK : S_FALSE;
}
// IStream implementation.
HRESULT STDMETHODCALLTYPE SetSize(ULARGE_INTEGER val) override {
return STG_E_ACCESSDENIED;
}
HRESULT STDMETHODCALLTYPE CopyTo(IStream *, ULARGE_INTEGER,
ULARGE_INTEGER *, ULARGE_INTEGER *) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE Commit(DWORD) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE Revert(void) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE LockRegion(ULARGE_INTEGER,
ULARGE_INTEGER, DWORD) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE UnlockRegion(ULARGE_INTEGER,
ULARGE_INTEGER, DWORD) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE Clone(IStream **) override { return E_NOTIMPL; }
HRESULT STDMETHODCALLTYPE Seek(LARGE_INTEGER, DWORD, ULARGE_INTEGER *) override {
return E_NOTIMPL;
}
HRESULT STDMETHODCALLTYPE Stat(STATSTG *pStatstg,
DWORD grfStatFlag) override {
if (pStatstg == nullptr) {
return E_POINTER;
}
ZeroMemory(pStatstg, sizeof(*pStatstg));
pStatstg->type = STGTY_STREAM;
pStatstg->cbSize.u.LowPart = m_size;
return S_OK;
}
// AbstractMemoryStream implementation
LPBYTE GetPtr() throw() override {
return m_pBuffer;
}
ULONG GetPtrSize() throw() override {
return m_size;
}
LPBYTE Detach() throw() override {
LPBYTE result = m_pBuffer;
m_pBuffer = nullptr;
m_size = 0;
m_offset = 0;
return result;
}
UINT64 GetPosition() throw() override {
return m_offset;
}
HRESULT Reserve(ULONG targetSize) throw() override {
return targetSize <= m_size ? S_OK : E_BOUNDS;
}
};
HRESULT CreateMemoryStream(_In_ IMalloc *pMalloc, _COM_Outptr_ AbstractMemoryStream** ppResult) throw() {
if (pMalloc == nullptr || ppResult == nullptr) {
return E_POINTER;
}
CComPtr<MemoryStream> stream = MemoryStream::Alloc(pMalloc);
*ppResult = stream.Detach();
return (*ppResult == nullptr) ? E_OUTOFMEMORY : S_OK;
}
HRESULT CreateReadOnlyBlobStream(_In_ IDxcBlob *pSource, _COM_Outptr_ IStream** ppResult) throw() {
if (pSource == nullptr || ppResult == nullptr) {
return E_POINTER;
}
CComPtr<ReadOnlyBlobStream> stream = ReadOnlyBlobStream::Alloc(DxcGetThreadMallocNoRef());
if (stream.p) {
stream->Init(pSource);
}
*ppResult = stream.Detach();
return (*ppResult == nullptr) ? E_OUTOFMEMORY : S_OK;
}
HRESULT CreateFixedSizeMemoryStream(_In_ LPBYTE pBuffer, size_t size, _COM_Outptr_ AbstractMemoryStream** ppResult) throw() {
if (pBuffer == nullptr || ppResult == nullptr) {
return E_POINTER;
}
CComPtr<FixedSizeMemoryStream> stream = FixedSizeMemoryStream::Alloc(DxcGetThreadMallocNoRef());
if (stream.p) {
stream->Init(pBuffer, size);
}
*ppResult = stream.Detach();
return (*ppResult == nullptr) ? E_OUTOFMEMORY : S_OK;
}
} // namespace hlsl