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/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim:set ts=2 sw=2 sts=2 et cindent: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "WMFUtils.h"
#include <mfidl.h>
#include <shlobj.h>
#include <shlwapi.h>
#include <initguid.h>
#include <stdint.h>
#ifdef MOZ_AV1
# include "AOMDecoder.h"
#endif
#include "MP4Decoder.h"
#include "VideoUtils.h"
#include "VPXDecoder.h"
#include "mozilla/ArrayUtils.h"
#include "mozilla/CheckedInt.h"
#include "mozilla/Logging.h"
#include "mozilla/RefPtr.h"
#include "nsTArray.h"
#include "nsThreadUtils.h"
#include "nsWindowsHelpers.h"
#include "prenv.h"
#include "mozilla/mscom/EnsureMTA.h"
#ifndef WAVE_FORMAT_OPUS
# define WAVE_FORMAT_OPUS 0x704F
#endif
DEFINE_GUID(MEDIASUBTYPE_OPUS, WAVE_FORMAT_OPUS, 0x000, 0x0010, 0x80, 0x00,
0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71);
namespace mozilla {
using media::TimeUnit;
bool StreamTypeIsVideo(const WMFStreamType& aType) {
switch (aType) {
case WMFStreamType::H264:
case WMFStreamType::VP8:
case WMFStreamType::VP9:
case WMFStreamType::AV1:
case WMFStreamType::HEVC:
return true;
default:
return false;
}
}
bool StreamTypeIsAudio(const WMFStreamType& aType) {
switch (aType) {
case WMFStreamType::MP3:
case WMFStreamType::AAC:
case WMFStreamType::OPUS:
case WMFStreamType::VORBIS:
return true;
default:
return false;
}
}
WMFStreamType GetStreamTypeFromMimeType(const nsCString& aMimeType) {
if (MP4Decoder::IsH264(aMimeType)) {
return WMFStreamType::H264;
}
if (VPXDecoder::IsVP8(aMimeType)) {
return WMFStreamType::VP8;
}
if (VPXDecoder::IsVP9(aMimeType)) {
return WMFStreamType::VP9;
}
#ifdef MOZ_AV1
if (AOMDecoder::IsAV1(aMimeType)) {
return WMFStreamType::AV1;
}
#endif
if (MP4Decoder::IsHEVC(aMimeType)) {
return WMFStreamType::HEVC;
}
if (aMimeType.EqualsLiteral("audio/mp4a-latm") ||
aMimeType.EqualsLiteral("audio/mp4")) {
return WMFStreamType::AAC;
}
if (aMimeType.EqualsLiteral("audio/mpeg")) {
return WMFStreamType::MP3;
}
if (aMimeType.EqualsLiteral("audio/opus")) {
return WMFStreamType::OPUS;
}
if (aMimeType.EqualsLiteral("audio/vorbis")) {
return WMFStreamType::VORBIS;
}
return WMFStreamType::Unknown;
}
GUID GetOutputSubType(const gfx::ColorDepth& aColorDepth,
bool aIsHardwareDecoding) {
switch (aColorDepth) {
case gfx::ColorDepth::COLOR_8:
return aIsHardwareDecoding ? MFVideoFormat_NV12 : MFVideoFormat_YV12;
case gfx::ColorDepth::COLOR_10:
return MFVideoFormat_P010;
case gfx::ColorDepth::COLOR_12:
case gfx::ColorDepth::COLOR_16:
return MFVideoFormat_P016;
default:
MOZ_ASSERT_UNREACHABLE("Unexpected color depth");
return GUID_NULL;
}
}
#define ENUM_TO_STR(enumVal) \
if (aSubtype == enumVal) { \
return nsPrintfCString{#enumVal}; \
}
// Audio :
// Video :
nsCString GetSubTypeStr(const GUID& aSubtype) {
// output format
ENUM_TO_STR(MFAudioFormat_PCM)
ENUM_TO_STR(MFAudioFormat_Float)
ENUM_TO_STR(MFVideoFormat_NV12)
ENUM_TO_STR(MFVideoFormat_YV12)
ENUM_TO_STR(MFVideoFormat_IYUV)
ENUM_TO_STR(MFVideoFormat_P010)
ENUM_TO_STR(MFVideoFormat_P016)
ENUM_TO_STR(MFVideoFormat_ARGB32)
ENUM_TO_STR(MFVideoFormat_RGB32)
// codec
ENUM_TO_STR(MFAudioFormat_MP3)
ENUM_TO_STR(MFAudioFormat_AAC)
ENUM_TO_STR(MFAudioFormat_Vorbis)
ENUM_TO_STR(MFAudioFormat_Opus)
ENUM_TO_STR(MFVideoFormat_H264)
ENUM_TO_STR(MFVideoFormat_VP80)
ENUM_TO_STR(MFVideoFormat_VP90)
ENUM_TO_STR(MFVideoFormat_AV1)
ENUM_TO_STR(MFVideoFormat_HEVC)
LPOLESTR subtypeStr;
StringFromCLSID(aSubtype, &subtypeStr);
nsPrintfCString errorMsg("Unknown output subtype: %S", subtypeStr);
CoTaskMemFree(subtypeStr);
return errorMsg;
}
#undef ENUM_TO_STR
HRESULT
HNsToFrames(int64_t aHNs, uint32_t aRate, int64_t* aOutFrames) {
MOZ_ASSERT(aOutFrames);
const int64_t HNS_PER_S = USECS_PER_S * 10;
CheckedInt<int64_t> i = aHNs;
i *= aRate;
i /= HNS_PER_S;
NS_ENSURE_TRUE(i.isValid(), E_FAIL);
*aOutFrames = i.value();
return S_OK;
}
HRESULT
GetDefaultStride(IMFMediaType* aType, uint32_t aWidth, uint32_t* aOutStride) {
// Try to get the default stride from the media type.
HRESULT hr = aType->GetUINT32(MF_MT_DEFAULT_STRIDE, aOutStride);
if (SUCCEEDED(hr)) {
return S_OK;
}
// Stride attribute not set, calculate it.
GUID subtype = GUID_NULL;
hr = aType->GetGUID(MF_MT_SUBTYPE, &subtype);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = wmf::MFGetStrideForBitmapInfoHeader(subtype.Data1, aWidth,
(LONG*)(aOutStride));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
return hr;
}
Maybe<gfx::YUVColorSpace> GetYUVColorSpace(IMFMediaType* aType) {
UINT32 yuvColorMatrix;
HRESULT hr = aType->GetUINT32(MF_MT_YUV_MATRIX, &yuvColorMatrix);
NS_ENSURE_TRUE(SUCCEEDED(hr), {});
switch (yuvColorMatrix) {
case MFVideoTransferMatrix_BT2020_10:
case MFVideoTransferMatrix_BT2020_12:
return Some(gfx::YUVColorSpace::BT2020);
case MFVideoTransferMatrix_BT709:
return Some(gfx::YUVColorSpace::BT709);
case MFVideoTransferMatrix_BT601:
return Some(gfx::YUVColorSpace::BT601);
default:
MOZ_ASSERT_UNREACHABLE("Unhandled MFVideoTransferMatrix_?");
return {};
}
}
int32_t MFOffsetToInt32(const MFOffset& aOffset) {
return AssertedCast<int32_t>(AssertedCast<float>(aOffset.value) +
(AssertedCast<float>(aOffset.fract) / 65536.0f));
}
TimeUnit GetSampleDuration(IMFSample* aSample) {
NS_ENSURE_TRUE(aSample, TimeUnit::Invalid());
int64_t duration = 0;
HRESULT hr = aSample->GetSampleDuration(&duration);
NS_ENSURE_TRUE(SUCCEEDED(hr), TimeUnit::Invalid());
return TimeUnit::FromMicroseconds(HNsToUsecs(duration));
}
TimeUnit GetSampleTime(IMFSample* aSample) {
NS_ENSURE_TRUE(aSample, TimeUnit::Invalid());
LONGLONG timestampHns = 0;
HRESULT hr = aSample->GetSampleTime(&timestampHns);
NS_ENSURE_TRUE(SUCCEEDED(hr), TimeUnit::Invalid());
return TimeUnit::FromMicroseconds(HNsToUsecs(timestampHns));
}
// Gets the sub-region of the video frame that should be displayed.
// See:
HRESULT
GetPictureRegion(IMFMediaType* aMediaType, gfx::IntRect& aOutPictureRegion) {
// Determine if "pan and scan" is enabled for this media. If it is, we
// only display a region of the video frame, not the entire frame.
BOOL panScan =
!!MFGetAttributeUINT32(aMediaType, MF_MT_PAN_SCAN_ENABLED, FALSE);
// If pan and scan mode is enabled. Try to get the display region.
HRESULT hr = E_FAIL;
MFVideoArea videoArea;
memset(&videoArea, 0, sizeof(MFVideoArea));
if (panScan) {
hr = aMediaType->GetBlob(MF_MT_PAN_SCAN_APERTURE, (UINT8*)&videoArea,
sizeof(MFVideoArea), nullptr);
}
// If we're not in pan-and-scan mode, or the pan-and-scan region is not set,
// check for a minimimum display aperture.
if (!panScan || hr == MF_E_ATTRIBUTENOTFOUND) {
hr = aMediaType->GetBlob(MF_MT_MINIMUM_DISPLAY_APERTURE, (UINT8*)&videoArea,
sizeof(MFVideoArea), nullptr);
}
if (hr == MF_E_ATTRIBUTENOTFOUND) {
// Minimum display aperture is not set, for "backward compatibility with
// some components", check for a geometric aperture.
hr = aMediaType->GetBlob(MF_MT_GEOMETRIC_APERTURE, (UINT8*)&videoArea,
sizeof(MFVideoArea), nullptr);
}
if (SUCCEEDED(hr)) {
// The media specified a picture region, return it.
aOutPictureRegion = gfx::IntRect(MFOffsetToInt32(videoArea.OffsetX),
MFOffsetToInt32(videoArea.OffsetY),
videoArea.Area.cx, videoArea.Area.cy);
return S_OK;
}
// No picture region defined, fall back to using the entire video area.
UINT32 width = 0, height = 0;
hr = MFGetAttributeSize(aMediaType, MF_MT_FRAME_SIZE, &width, &height);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
NS_ENSURE_TRUE(width <= MAX_VIDEO_WIDTH, E_FAIL);
NS_ENSURE_TRUE(height <= MAX_VIDEO_HEIGHT, E_FAIL);
aOutPictureRegion = gfx::IntRect(0, 0, width, height);
return S_OK;
}
nsString GetProgramW6432Path() {
char* programPath = PR_GetEnvSecure("ProgramW6432");
if (!programPath) {
programPath = PR_GetEnvSecure("ProgramFiles");
}
if (!programPath) {
return u"C:\\Program Files"_ns;
}
return NS_ConvertUTF8toUTF16(programPath);
}
const char* MFTMessageTypeToStr(MFT_MESSAGE_TYPE aMsg) {
switch (aMsg) {
case MFT_MESSAGE_COMMAND_FLUSH:
return "MFT_MESSAGE_COMMAND_FLUSH";
case MFT_MESSAGE_COMMAND_DRAIN:
return "MFT_MESSAGE_COMMAND_DRAIN";
case MFT_MESSAGE_COMMAND_MARKER:
return "MFT_MESSAGE_COMMAND_MARKER";
case MFT_MESSAGE_SET_D3D_MANAGER:
return "MFT_MESSAGE_SET_D3D_MANAGER";
case MFT_MESSAGE_NOTIFY_BEGIN_STREAMING:
return "MFT_MESSAGE_NOTIFY_BEGIN_STREAMING";
case MFT_MESSAGE_NOTIFY_END_STREAMING:
return "MFT_MESSAGE_NOTIFY_END_STREAMING";
case MFT_MESSAGE_NOTIFY_END_OF_STREAM:
return "MFT_MESSAGE_NOTIFY_END_OF_STREAM";
case MFT_MESSAGE_NOTIFY_START_OF_STREAM:
return "MFT_MESSAGE_NOTIFY_START_OF_STREAM";
case MFT_MESSAGE_DROP_SAMPLES:
return "MFT_MESSAGE_DROP_SAMPLES";
case MFT_MESSAGE_COMMAND_TICK:
return "MFT_MESSAGE_COMMAND_TICK";
case MFT_MESSAGE_NOTIFY_RELEASE_RESOURCES:
return "MFT_MESSAGE_NOTIFY_RELEASE_RESOURCES";
case MFT_MESSAGE_NOTIFY_REACQUIRE_RESOURCES:
return "MFT_MESSAGE_NOTIFY_REACQUIRE_RESOURCES";
case MFT_MESSAGE_NOTIFY_EVENT:
return "MFT_MESSAGE_NOTIFY_EVENT";
case MFT_MESSAGE_COMMAND_SET_OUTPUT_STREAM_STATE:
return "MFT_MESSAGE_COMMAND_SET_OUTPUT_STREAM_STATE";
case MFT_MESSAGE_COMMAND_FLUSH_OUTPUT_STREAM:
return "MFT_MESSAGE_COMMAND_FLUSH_OUTPUT_STREAM";
default:
return "Invalid message?";
}
}
GUID AudioMimeTypeToMediaFoundationSubtype(const nsACString& aMimeType) {
if (aMimeType.EqualsLiteral("audio/mpeg")) {
return MFAudioFormat_MP3;
}
if (MP4Decoder::IsAAC(aMimeType)) {
return MFAudioFormat_AAC;
}
if (aMimeType.EqualsLiteral("audio/vorbis")) {
return MFAudioFormat_Vorbis;
}
if (aMimeType.EqualsLiteral("audio/opus")) {
return MFAudioFormat_Opus;
}
NS_WARNING("Unsupport audio mimetype");
return GUID_NULL;
}
GUID VideoMimeTypeToMediaFoundationSubtype(const nsACString& aMimeType) {
if (MP4Decoder::IsH264(aMimeType)) {
return MFVideoFormat_H264;
}
if (VPXDecoder::IsVP8(aMimeType)) {
return MFVideoFormat_VP80;
}
if (VPXDecoder::IsVP9(aMimeType)) {
return MFVideoFormat_VP90;
}
#ifdef MOZ_AV1
if (AOMDecoder::IsAV1(aMimeType)) {
return MFVideoFormat_AV1;
}
#endif
if (MP4Decoder::IsHEVC(aMimeType)) {
return MFVideoFormat_HEVC;
}
NS_WARNING(nsAutoCString(nsDependentCString("Unsupported video mimetype ") +
aMimeType)
.get());
return GUID_NULL;
}
void AACAudioSpecificConfigToUserData(uint8_t aAACProfileLevelIndication,
const uint8_t* aAudioSpecConfig,
uint32_t aConfigLength,
nsTArray<BYTE>& aOutUserData) {
MOZ_ASSERT(aOutUserData.IsEmpty());
// The MF_MT_USER_DATA for AAC is defined here:
//
// For MFAudioFormat_AAC, MF_MT_USER_DATA contains the portion of
// the HEAACWAVEINFO structure that appears after the WAVEFORMATEX
// structure (that is, after the wfx member). This is followed by
// the AudioSpecificConfig() data, as defined by ISO/IEC 14496-3.
// [...]
// The length of the AudioSpecificConfig() data is 2 bytes for AAC-LC
// or HE-AAC with implicit signaling of SBR/PS. It is more than 2 bytes
// for HE-AAC with explicit signaling of SBR/PS.
//
// The value of audioObjectType as defined in AudioSpecificConfig()
// must be 2, indicating AAC-LC. The value of extensionAudioObjectType
// must be 5 for SBR or 29 for PS.
//
// HEAACWAVEINFO structure:
// typedef struct heaacwaveinfo_tag {
// WAVEFORMATEX wfx;
// WORD wPayloadType;
// WORD wAudioProfileLevelIndication;
// WORD wStructType;
// WORD wReserved1;
// DWORD dwReserved2;
// }
const UINT32 heeInfoLen = 4 * sizeof(WORD) + sizeof(DWORD);
// The HEAACWAVEINFO must have payload and profile set,
// the rest can be all 0x00.
BYTE heeInfo[heeInfoLen] = {0};
WORD* w = (WORD*)heeInfo;
// If extradata has been provided, assume raw AAC packets (0). Otherwise,
// assume ADTS (1)
w[0] = aConfigLength ? 0 : 1;
w[1] = aAACProfileLevelIndication;
aOutUserData.AppendElements(heeInfo, heeInfoLen);
if (aAACProfileLevelIndication == 2 && aConfigLength > 2) {
// The AudioSpecificConfig is TTTTTFFF|FCCCCGGG
// (T=ObjectType, F=Frequency, C=Channel, G=GASpecificConfig)
// If frequency = 0xf, then the frequency is explicitly defined on 24 bits.
uint8_t frequency =
(aAudioSpecConfig[0] & 0x7) << 1 | (aAudioSpecConfig[1] & 0x80) >> 7;
uint8_t channels = (aAudioSpecConfig[1] & 0x78) >> 3;
uint8_t gasc = aAudioSpecConfig[1] & 0x7;
if (frequency != 0xf && channels && !gasc) {
// We enter this condition if the AudioSpecificConfig should theorically
// be 2 bytes long but it's not.
// The WMF AAC decoder will error if unknown extensions are found,
// so remove them.
aConfigLength = 2;
}
}
aOutUserData.AppendElements(aAudioSpecConfig, aConfigLength);
}
namespace wmf {
static const wchar_t* sDLLs[] = {
L"mfplat.dll",
L"mf.dll",
L"dxva2.dll",
L"evr.dll",
};
HRESULT
LoadDLLs() {
static bool sDLLsLoaded = false;
static bool sFailedToLoadDlls = false;
if (sDLLsLoaded) {
return S_OK;
}
if (sFailedToLoadDlls) {
return E_FAIL;
}
// Try to load all the required DLLs. If we fail to load any dll,
// unload the dlls we succeeded in loading.
nsTArray<const wchar_t*> loadedDlls;
for (const wchar_t* dll : sDLLs) {
if (!LoadLibrarySystem32(dll)) {
NS_WARNING("Failed to load WMF DLLs");
for (const wchar_t* loadedDll : loadedDlls) {
FreeLibrary(GetModuleHandleW(loadedDll));
}
sFailedToLoadDlls = true;
return E_FAIL;
}
loadedDlls.AppendElement(dll);
}
sDLLsLoaded = true;
return S_OK;
}
#define ENSURE_FUNCTION_PTR_HELPER(FunctionType, FunctionName, DLL) \
static FunctionType FunctionName##Ptr = nullptr; \
if (!FunctionName##Ptr) { \
FunctionName##Ptr = (FunctionType)GetProcAddress( \
GetModuleHandleW(L## #DLL), #FunctionName); \
if (!FunctionName##Ptr) { \
NS_WARNING("Failed to get GetProcAddress of " #FunctionName \
" from " #DLL); \
return E_FAIL; \
} \
}
#define ENSURE_FUNCTION_PTR(FunctionName, DLL) \
ENSURE_FUNCTION_PTR_HELPER(decltype(::FunctionName)*, FunctionName, DLL)
#define ENSURE_FUNCTION_PTR_(FunctionName, DLL) \
ENSURE_FUNCTION_PTR_HELPER(FunctionName##Ptr_t, FunctionName, DLL)
#define DECL_FUNCTION_PTR(FunctionName, ...) \
typedef HRESULT(STDMETHODCALLTYPE* FunctionName##Ptr_t)(__VA_ARGS__)
HRESULT
MediaFoundationInitializer::MFStartup() {
HRESULT hr = LoadDLLs();
if (FAILED(hr)) {
return hr;
}
const int MF_WIN7_VERSION = (0x0002 << 16 | MF_API_VERSION);
// decltype is unusable for functions having default parameters
DECL_FUNCTION_PTR(MFStartup, ULONG, DWORD);
ENSURE_FUNCTION_PTR_(MFStartup, Mfplat.dll)
hr = E_FAIL;
mozilla::mscom::EnsureMTA(
[&]() -> void { hr = MFStartupPtr(MF_WIN7_VERSION, MFSTARTUP_FULL); });
return hr;
}
HRESULT
MediaFoundationInitializer::MFShutdown() {
ENSURE_FUNCTION_PTR(MFShutdown, Mfplat.dll)
HRESULT hr = E_FAIL;
mozilla::mscom::EnsureMTA([&]() -> void { hr = (MFShutdownPtr)(); });
return hr;
}
HRESULT
MFCreateMediaType(IMFMediaType** aOutMFType) {
ENSURE_FUNCTION_PTR(MFCreateMediaType, Mfplat.dll)
return (MFCreateMediaTypePtr)(aOutMFType);
}
HRESULT
MFGetStrideForBitmapInfoHeader(DWORD aFormat, DWORD aWidth, LONG* aOutStride) {
ENSURE_FUNCTION_PTR(MFGetStrideForBitmapInfoHeader, evr.dll)
return (MFGetStrideForBitmapInfoHeaderPtr)(aFormat, aWidth, aOutStride);
}
HRESULT MFGetService(IUnknown* punkObject, REFGUID guidService, REFIID riid,
LPVOID* ppvObject) {
ENSURE_FUNCTION_PTR(MFGetService, mf.dll)
return (MFGetServicePtr)(punkObject, guidService, riid, ppvObject);
}
HRESULT
DXVA2CreateDirect3DDeviceManager9(UINT* pResetToken,
IDirect3DDeviceManager9** ppDXVAManager) {
ENSURE_FUNCTION_PTR(DXVA2CreateDirect3DDeviceManager9, dxva2.dll)
return (DXVA2CreateDirect3DDeviceManager9Ptr)(pResetToken, ppDXVAManager);
}
HRESULT
MFCreateSample(IMFSample** ppIMFSample) {
ENSURE_FUNCTION_PTR(MFCreateSample, mfplat.dll)
return (MFCreateSamplePtr)(ppIMFSample);
}
HRESULT
MFCreateAlignedMemoryBuffer(DWORD cbMaxLength, DWORD fAlignmentFlags,
IMFMediaBuffer** ppBuffer) {
ENSURE_FUNCTION_PTR(MFCreateAlignedMemoryBuffer, mfplat.dll)
return (MFCreateAlignedMemoryBufferPtr)(cbMaxLength, fAlignmentFlags,
ppBuffer);
}
HRESULT
MFCreateDXGIDeviceManager(UINT* pResetToken,
IMFDXGIDeviceManager** ppDXVAManager) {
ENSURE_FUNCTION_PTR(MFCreateDXGIDeviceManager, mfplat.dll)
return (MFCreateDXGIDeviceManagerPtr)(pResetToken, ppDXVAManager);
}
HRESULT
MFCreateDXGISurfaceBuffer(REFIID riid, IUnknown* punkSurface,
UINT uSubresourceIndex, BOOL fButtomUpWhenLinear,
IMFMediaBuffer** ppBuffer) {
ENSURE_FUNCTION_PTR(MFCreateDXGISurfaceBuffer, mfplat.dll)
return (MFCreateDXGISurfaceBufferPtr)(riid, punkSurface, uSubresourceIndex,
fButtomUpWhenLinear, ppBuffer);
}
HRESULT
MFTEnumEx(GUID guidCategory, UINT32 Flags,
const MFT_REGISTER_TYPE_INFO* pInputType,
const MFT_REGISTER_TYPE_INFO* pOutputType,
IMFActivate*** pppMFTActivate, UINT32* pnumMFTActivate) {
ENSURE_FUNCTION_PTR(MFTEnumEx, mfplat.dll)
return (MFTEnumExPtr)(guidCategory, Flags, pInputType, pOutputType,
pppMFTActivate, pnumMFTActivate);
}
HRESULT MFTGetInfo(CLSID clsidMFT, LPWSTR* pszName,
MFT_REGISTER_TYPE_INFO** ppInputTypes, UINT32* pcInputTypes,
MFT_REGISTER_TYPE_INFO** ppOutputTypes,
UINT32* pcOutputTypes, IMFAttributes** ppAttributes) {
ENSURE_FUNCTION_PTR(MFTGetInfo, mfplat.dll)
return (MFTGetInfoPtr)(clsidMFT, pszName, ppInputTypes, pcInputTypes,
ppOutputTypes, pcOutputTypes, ppAttributes);
}
HRESULT
MFCreateAttributes(IMFAttributes** ppMFAttributes, UINT32 cInitialSize) {
ENSURE_FUNCTION_PTR(MFCreateAttributes, mfplat.dll)
return (MFCreateAttributesPtr)(ppMFAttributes, cInitialSize);
}
HRESULT MFCreateEventQueue(IMFMediaEventQueue** ppMediaEventQueue) {
ENSURE_FUNCTION_PTR(MFCreateEventQueue, mfplat.dll)
return (MFCreateEventQueuePtr)(ppMediaEventQueue);
}
HRESULT MFCreateStreamDescriptor(DWORD dwStreamIdentifier, DWORD cMediaTypes,
IMFMediaType** apMediaTypes,
IMFStreamDescriptor** ppDescriptor) {
ENSURE_FUNCTION_PTR(MFCreateStreamDescriptor, mfplat.dll)
return (MFCreateStreamDescriptorPtr)(dwStreamIdentifier, cMediaTypes,
apMediaTypes, ppDescriptor);
}
HRESULT MFCreateAsyncResult(IUnknown* punkObject, IMFAsyncCallback* pCallback,
IUnknown* punkState,
IMFAsyncResult** ppAsyncResult) {
ENSURE_FUNCTION_PTR(MFCreateAsyncResult, mfplat.dll)
return (MFCreateAsyncResultPtr)(punkObject, pCallback, punkState,
ppAsyncResult);
}
HRESULT MFCreatePresentationDescriptor(
DWORD cStreamDescriptors, IMFStreamDescriptor** apStreamDescriptors,
IMFPresentationDescriptor** ppPresentationDescriptor) {
ENSURE_FUNCTION_PTR(MFCreatePresentationDescriptor, mfplat.dll)
return (MFCreatePresentationDescriptorPtr)(cStreamDescriptors,
apStreamDescriptors,
ppPresentationDescriptor);
}
HRESULT MFCreateMemoryBuffer(DWORD cbMaxLength, IMFMediaBuffer** ppBuffer) {
ENSURE_FUNCTION_PTR(MFCreateMemoryBuffer, mfplat.dll);
return (MFCreateMemoryBufferPtr)(cbMaxLength, ppBuffer);
}
HRESULT MFLockDXGIDeviceManager(UINT* pResetToken,
IMFDXGIDeviceManager** ppManager) {
ENSURE_FUNCTION_PTR(MFLockDXGIDeviceManager, mfplat.dll);
return (MFLockDXGIDeviceManagerPtr)(pResetToken, ppManager);
}
HRESULT MFUnlockDXGIDeviceManager() {
ENSURE_FUNCTION_PTR(MFUnlockDXGIDeviceManager, mfplat.dll);
return (MFUnlockDXGIDeviceManagerPtr)();
}
HRESULT MFPutWorkItem(DWORD dwQueue, IMFAsyncCallback* pCallback,
IUnknown* pState) {
ENSURE_FUNCTION_PTR(MFPutWorkItem, mfplat.dll);
return (MFPutWorkItemPtr)(dwQueue, pCallback, pState);
}
HRESULT MFSerializeAttributesToStream(IMFAttributes* pAttr, DWORD dwOptions,
IStream* pStm) {
ENSURE_FUNCTION_PTR(MFSerializeAttributesToStream, mfplat.dll);
return (MFSerializeAttributesToStreamPtr)(pAttr, dwOptions, pStm);
}
HRESULT MFWrapMediaType(IMFMediaType* pOrig, REFGUID MajorType, REFGUID SubType,
IMFMediaType** ppWrap) {
ENSURE_FUNCTION_PTR(MFWrapMediaType, mfplat.dll);
return (MFWrapMediaTypePtr)(pOrig, MajorType, SubType, ppWrap);
}
} // end namespace wmf
} // end namespace mozilla