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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
#ifdef MOZ_AV1
# include "AOMDecoder.h"
#endif
#include "DXVA2Manager.h"
#include <d3d11.h>
#include "DriverCrashGuard.h"
#include "GfxDriverInfo.h"
#include "ImageContainer.h"
#include "MFTDecoder.h"
#include "MediaTelemetryConstants.h"
#include "PerformanceRecorder.h"
#include "VideoUtils.h"
#include "VPXDecoder.h"
#include "WMFUtils.h"
#include "gfxCrashReporterUtils.h"
#include "gfxWindowsPlatform.h"
#include "mfapi.h"
#include "mozilla/AppShutdown.h"
#include "mozilla/ClearOnShutdown.h"
#include "mozilla/StaticMutex.h"
#include "mozilla/StaticPrefs_media.h"
#include "mozilla/Telemetry.h"
#include "mozilla/gfx/DeviceManagerDx.h"
#include "mozilla/layers/D3D11ShareHandleImage.h"
#include "mozilla/layers/D3D11TextureIMFSampleImage.h"
#include "mozilla/layers/HelpersD3D11.h"
#include "mozilla/layers/ImageBridgeChild.h"
#include "mozilla/layers/TextureD3D11.h"
#include "mozilla/layers/TextureForwarder.h"
#include "mozilla/mscom/EnsureMTA.h"
#include "nsPrintfCString.h"
#include "nsThreadUtils.h"
const GUID MF_XVP_PLAYBACK_MODE = {
0x3c5d293f,
0xad67,
0x4e29,
{0xaf, 0x12, 0xcf, 0x3e, 0x23, 0x8a, 0xcc, 0xe9}};
DEFINE_GUID(MF_LOW_LATENCY, 0x9c27891a, 0xed7a, 0x40e1, 0x88, 0xe8, 0xb2, 0x27,
0x27, 0xa0, 0x24, 0xee);
// R600, R700, Evergreen and Cayman AMD cards. These support DXVA via UVD3 or
// earlier, and don't handle 1080p60 well.
static const DWORD sAMDPreUVD4[] = {
// clang-format off
0x9400, 0x9401, 0x9402, 0x9403, 0x9405, 0x940a, 0x940b, 0x940f, 0x94c0, 0x94c1, 0x94c3, 0x94c4, 0x94c5,
0x94c6, 0x94c7, 0x94c8, 0x94c9, 0x94cb, 0x94cc, 0x94cd, 0x9580, 0x9581, 0x9583, 0x9586, 0x9587, 0x9588,
0x9589, 0x958a, 0x958b, 0x958c, 0x958d, 0x958e, 0x958f, 0x9500, 0x9501, 0x9504, 0x9505, 0x9506, 0x9507,
0x9508, 0x9509, 0x950f, 0x9511, 0x9515, 0x9517, 0x9519, 0x95c0, 0x95c2, 0x95c4, 0x95c5, 0x95c6, 0x95c7,
0x95c9, 0x95cc, 0x95cd, 0x95ce, 0x95cf, 0x9590, 0x9591, 0x9593, 0x9595, 0x9596, 0x9597, 0x9598, 0x9599,
0x959b, 0x9610, 0x9611, 0x9612, 0x9613, 0x9614, 0x9615, 0x9616, 0x9710, 0x9711, 0x9712, 0x9713, 0x9714,
0x9715, 0x9440, 0x9441, 0x9442, 0x9443, 0x9444, 0x9446, 0x944a, 0x944b, 0x944c, 0x944e, 0x9450, 0x9452,
0x9456, 0x945a, 0x945b, 0x945e, 0x9460, 0x9462, 0x946a, 0x946b, 0x947a, 0x947b, 0x9480, 0x9487, 0x9488,
0x9489, 0x948a, 0x948f, 0x9490, 0x9491, 0x9495, 0x9498, 0x949c, 0x949e, 0x949f, 0x9540, 0x9541, 0x9542,
0x954e, 0x954f, 0x9552, 0x9553, 0x9555, 0x9557, 0x955f, 0x94a0, 0x94a1, 0x94a3, 0x94b1, 0x94b3, 0x94b4,
0x94b5, 0x94b9, 0x68e0, 0x68e1, 0x68e4, 0x68e5, 0x68e8, 0x68e9, 0x68f1, 0x68f2, 0x68f8, 0x68f9, 0x68fa,
0x68fe, 0x68c0, 0x68c1, 0x68c7, 0x68c8, 0x68c9, 0x68d8, 0x68d9, 0x68da, 0x68de, 0x68a0, 0x68a1, 0x68a8,
0x68a9, 0x68b0, 0x68b8, 0x68b9, 0x68ba, 0x68be, 0x68bf, 0x6880, 0x6888, 0x6889, 0x688a, 0x688c, 0x688d,
0x6898, 0x6899, 0x689b, 0x689e, 0x689c, 0x689d, 0x9802, 0x9803, 0x9804, 0x9805, 0x9806, 0x9807, 0x9808,
0x9809, 0x980a, 0x9640, 0x9641, 0x9647, 0x9648, 0x964a, 0x964b, 0x964c, 0x964e, 0x964f, 0x9642, 0x9643,
0x9644, 0x9645, 0x9649, 0x6720, 0x6721, 0x6722, 0x6723, 0x6724, 0x6725, 0x6726, 0x6727, 0x6728, 0x6729,
0x6738, 0x6739, 0x673e, 0x6740, 0x6741, 0x6742, 0x6743, 0x6744, 0x6745, 0x6746, 0x6747, 0x6748, 0x6749,
0x674a, 0x6750, 0x6751, 0x6758, 0x6759, 0x675b, 0x675d, 0x675f, 0x6840, 0x6841, 0x6842, 0x6843, 0x6849,
0x6850, 0x6858, 0x6859, 0x6760, 0x6761, 0x6762, 0x6763, 0x6764, 0x6765, 0x6766, 0x6767, 0x6768, 0x6770,
0x6771, 0x6772, 0x6778, 0x6779, 0x677b, 0x6700, 0x6701, 0x6702, 0x6703, 0x6704, 0x6705, 0x6706, 0x6707,
0x6708, 0x6709, 0x6718, 0x6719, 0x671c, 0x671d, 0x671f, 0x9900, 0x9901, 0x9903, 0x9904, 0x9905, 0x9906,
0x9907, 0x9908, 0x9909, 0x990a, 0x990b, 0x990c, 0x990d, 0x990e, 0x990f, 0x9910, 0x9913, 0x9917, 0x9918,
0x9919, 0x9990, 0x9991, 0x9992, 0x9993, 0x9994, 0x9995, 0x9996, 0x9997, 0x9998, 0x9999, 0x999a, 0x999b,
0x999c, 0x999d, 0x99a0, 0x99a2, 0x99a4
// clang-format on
};
// List of NVidia Telsa GPU known to have broken NV12 rendering.
static const DWORD sNVIDIABrokenNV12[] = {
// clang-format off
0x0191, 0x0193, 0x0194, 0x0197, 0x019d, 0x019e, // G80
0x0400, 0x0401, 0x0402, 0x0403, 0x0404, 0x0405, 0x0406, 0x0407, 0x0408, 0x0409, // G84
0x040a, 0x040b, 0x040c, 0x040d, 0x040e, 0x040f,
0x0420, 0x0421, 0x0422, 0x0423, 0x0424, 0x0425, 0x0426, 0x0427, 0x0428, 0x0429, // G86
0x042a, 0x042b, 0x042c, 0x042d, 0x042e, 0x042f,
0x0410, 0x0600, 0x0601, 0x0602, 0x0603, 0x0604, 0x0605, 0x0606, 0x0607, 0x0608, // G92
0x0609, 0x060a, 0x060b, 0x060c, 0x060f, 0x0610, 0x0611, 0x0612, 0x0613, 0x0614,
0x0615, 0x0617, 0x0618, 0x0619, 0x061a, 0x061b, 0x061c, 0x061d, 0x061e, 0x061f, // G94
0x0621, 0x0622, 0x0623, 0x0625, 0x0626, 0x0627, 0x0628, 0x062a, 0x062b, 0x062c,
0x062d, 0x062e, 0x0631, 0x0635, 0x0637, 0x0638, 0x063a,
0x0640, 0x0641, 0x0643, 0x0644, 0x0645, 0x0646, 0x0647, 0x0648, 0x0649, 0x064a, // G96
0x064b, 0x064c, 0x0651, 0x0652, 0x0653, 0x0654, 0x0655, 0x0656, 0x0658, 0x0659,
0x065a, 0x065b, 0x065c, 0x065f,
0x06e0, 0x06e1, 0x06e2, 0x06e3, 0x06e4, 0x06e6, 0x06e7, 0x06e8, 0x06e9, 0x06ea, // G98
0x06eb, 0x06ec, 0x06ef, 0x06f1, 0x06f8, 0x06f9, 0x06fa, 0x06fb, 0x06fd, 0x06ff,
0x05e0, 0x05e1, 0x05e2, 0x05e3, 0x05e6, 0x05e7, 0x05e9, 0x05ea, 0x05eb, 0x05ed, // G200
0x05ee, 0x05ef,
0x0840, 0x0844, 0x0845, 0x0846, 0x0847, 0x0848, 0x0849, 0x084a, 0x084b, 0x084c, // MCP77
0x084d, 0x084f,
0x0860, 0x0861, 0x0862, 0x0863, 0x0864, 0x0865, 0x0866, 0x0867, 0x0868, 0x0869, // MCP79
0x086a, 0x086c, 0x086d, 0x086e, 0x086f, 0x0870, 0x0871, 0x0872, 0x0873, 0x0874,
0x0876, 0x087a, 0x087d, 0x087e, 0x087f,
0x0ca0, 0x0ca2, 0x0ca3, 0x0ca2, 0x0ca4, 0x0ca5, 0x0ca7, 0x0ca9, 0x0cac, 0x0caf, // GT215
0x0cb0, 0x0cb1, 0x0cbc,
0x0a20, 0x0a22, 0x0a23, 0x0a26, 0x0a27, 0x0a28, 0x0a29, 0x0a2a, 0x0a2b, 0x0a2c, // GT216
0x0a2d, 0x0a32, 0x0a34, 0x0a35, 0x0a38, 0x0a3c,
0x0a60, 0x0a62, 0x0a63, 0x0a64, 0x0a65, 0x0a66, 0x0a67, 0x0a68, 0x0a69, 0x0a6a, // GT218
0x0a6c, 0x0a6e, 0x0a6f, 0x0a70, 0x0a71, 0x0a72, 0x0a73, 0x0a74, 0x0a75, 0x0a76,
0x0a78, 0x0a7a, 0x0a7c, 0x10c0, 0x10c3, 0x10c5, 0x10d8
// clang-format on
};
extern mozilla::LazyLogModule sPDMLog;
#define LOG(...) MOZ_LOG(sPDMLog, mozilla::LogLevel::Debug, (__VA_ARGS__))
namespace mozilla {
using layers::D3D11RecycleAllocator;
using layers::D3D11ShareHandleImage;
using layers::Image;
using layers::ImageContainer;
using namespace layers;
using namespace gfx;
StaticRefPtr<ID3D11Device> sDevice;
StaticMutex sDeviceMutex;
// We found an issue where the ID3D11VideoDecoder won't release its underlying
// resources properly if the decoder iscreated from a compositor device by
// ourselves. This problem has been observed with both VP9 and, reportedly, AV1
// decoders, it does not seem to affect the H264 decoder, but the underlying
// decoder created by MFT seems not having this issue.
// Therefore, when checking whether we can use hardware decoding, we should use
// a non-compositor device to create a decoder in order to prevent resource
// leaking that can significantly degrade the performance. For the actual
// decoding, we will still use the compositor device if it's avaiable in order
// to avoid video copying.
static ID3D11Device* GetDeviceForDecoderCheck() {
StaticMutexAutoLock lock(sDeviceMutex);
if (AppShutdown::IsInOrBeyond(ShutdownPhase::XPCOMShutdown)) {
return nullptr;
}
if (!sDevice) {
sDevice = gfx::DeviceManagerDx::Get()->CreateDecoderDevice(
{DeviceManagerDx::DeviceFlag::disableDeviceReuse});
auto clearOnShutdown = [] { ClearOnShutdown(&sDevice); };
if (!NS_IsMainThread()) {
Unused << NS_DispatchToMainThread(
NS_NewRunnableFunction(__func__, clearOnShutdown));
} else {
clearOnShutdown();
}
}
return sDevice.get();
}
void GetDXVA2ExtendedFormatFromMFMediaType(IMFMediaType* pType,
DXVA2_ExtendedFormat* pFormat) {
// Get the interlace mode.
MFVideoInterlaceMode interlace = MFVideoInterlaceMode(MFGetAttributeUINT32(
pType, MF_MT_INTERLACE_MODE, MFVideoInterlace_Unknown));
if (interlace == MFVideoInterlace_MixedInterlaceOrProgressive) {
pFormat->SampleFormat = DXVA2_SampleFieldInterleavedEvenFirst;
} else {
pFormat->SampleFormat = UINT(interlace);
}
pFormat->VideoChromaSubsampling = MFGetAttributeUINT32(
pType, MF_MT_VIDEO_CHROMA_SITING, MFVideoChromaSubsampling_Unknown);
pFormat->NominalRange = MFGetAttributeUINT32(pType, MF_MT_VIDEO_NOMINAL_RANGE,
MFNominalRange_Unknown);
pFormat->VideoTransferMatrix = MFGetAttributeUINT32(
pType, MF_MT_YUV_MATRIX, MFVideoTransferMatrix_Unknown);
pFormat->VideoLighting = MFGetAttributeUINT32(pType, MF_MT_VIDEO_LIGHTING,
MFVideoLighting_Unknown);
pFormat->VideoPrimaries = MFGetAttributeUINT32(pType, MF_MT_VIDEO_PRIMARIES,
MFVideoPrimaries_Unknown);
pFormat->VideoTransferFunction = MFGetAttributeUINT32(
pType, MF_MT_TRANSFER_FUNCTION, MFVideoTransFunc_Unknown);
}
HRESULT ConvertMFTypeToDXVAType(IMFMediaType* pType, DXVA2_VideoDesc* pDesc) {
ZeroMemory(pDesc, sizeof(*pDesc));
// The D3D format is the first DWORD of the subtype GUID.
GUID subtype = GUID_NULL;
HRESULT hr = pType->GetGUID(MF_MT_SUBTYPE, &subtype);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
pDesc->Format = (D3DFORMAT)subtype.Data1;
UINT32 width = 0;
UINT32 height = 0;
hr = MFGetAttributeSize(pType, 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);
pDesc->SampleWidth = width;
pDesc->SampleHeight = height;
UINT32 fpsNumerator = 0;
UINT32 fpsDenominator = 0;
if (SUCCEEDED(MFGetAttributeRatio(pType, MF_MT_FRAME_RATE, &fpsNumerator,
&fpsDenominator))) {
pDesc->InputSampleFreq.Numerator = fpsNumerator;
pDesc->InputSampleFreq.Denominator = fpsDenominator;
GetDXVA2ExtendedFormatFromMFMediaType(pType, &pDesc->SampleFormat);
pDesc->OutputFrameFreq = pDesc->InputSampleFreq;
if ((pDesc->SampleFormat.SampleFormat ==
DXVA2_SampleFieldInterleavedEvenFirst) ||
(pDesc->SampleFormat.SampleFormat ==
DXVA2_SampleFieldInterleavedOddFirst)) {
pDesc->OutputFrameFreq.Numerator *= 2;
}
}
return S_OK;
}
// All GUIDs other than Intel ClearVideo can be found here:
// VLD = Variable-length decoder, FGT = Film grain technology
static const GUID DXVA2_ModeH264_VLD_NoFGT = {
0x1b81be68,
0xa0c7,
0x11d3,
{0xb9, 0x84, 0x00, 0xc0, 0x4f, 0x2e, 0x73, 0xc5}};
// Also known as DXVADDI_Intel_ModeH264_E here:
// Named based on the fact that this is only supported on older ClearVideo
// Intel decoding hardware.
static const GUID DXVA2_Intel_ClearVideo_ModeH264_VLD_NoFGT = {
0x604F8E68,
0x4951,
0x4c54,
{0x88, 0xFE, 0xAB, 0xD2, 0x5C, 0x15, 0xB3, 0xD6}};
// VP8 profiles
static const GUID DXVA2_ModeVP8_VLD = {
0x90b899ea,
0x3a62,
0x4705,
{0x88, 0xb3, 0x8d, 0xf0, 0x4b, 0x27, 0x44, 0xe7}};
// VP9 profiles
static const GUID DXVA2_ModeVP9_VLD_Profile0 = {
0x463707f8,
0xa1d0,
0x4585,
{0x87, 0x6d, 0x83, 0xaa, 0x6d, 0x60, 0xb8, 0x9e}};
static const GUID DXVA2_ModeVP9_VLD_10bit_Profile2 = {
0xa4c749ef,
0x6ecf,
0x48aa,
{0x84, 0x48, 0x50, 0xa7, 0xa1, 0x16, 0x5f, 0xf7}};
// AV1 profiles
static const GUID DXVA2_ModeAV1_VLD_Profile0 = {
0xb8be4ccb,
0xcf53,
0x46ba,
{0x8d, 0x59, 0xd6, 0xb8, 0xa6, 0xda, 0x5d, 0x2a}};
static const GUID DXVA2_ModeAV1_VLD_Profile1 = {
0x6936ff0f,
0x45b1,
0x4163,
{0x9c, 0xc1, 0x64, 0x6e, 0xf6, 0x94, 0x61, 0x08}};
static const GUID DXVA2_ModeAV1_VLD_Profile2 = {
0x0c5f2aa1,
0xe541,
0x4089,
{0xbb, 0x7b, 0x98, 0x11, 0x0a, 0x19, 0xd7, 0xc8}};
static const GUID DXVA2_ModeAV1_VLD_12bit_Profile2 = {
0x17127009,
0xa00f,
0x4ce1,
{0x99, 0x4e, 0xbf, 0x40, 0x81, 0xf6, 0xf3, 0xf0}};
static const GUID DXVA2_ModeAV1_VLD_12bit_Profile2_420 = {
0x2d80bed6,
0x9cac,
0x4835,
{0x9e, 0x91, 0x32, 0x7b, 0xbc, 0x4f, 0x9e, 0xe8}};
// D3D12_VIDEO_DECODE_PROFILE_HEVC_MAIN
static const GUID DXVA2_ModeHEVC_VLD_MAIN = {
0x5b11d51b,
0x2f4c,
0x4452,
{0xbc, 0xc3, 0x09, 0xf2, 0xa1, 0x16, 0x0c, 0xc0}};
// D3D12_VIDEO_DECODE_PROFILE_HEVC_MAIN10
static const GUID DXVA2_ModeHEVC_VLD_MAIN10 = {
0x107af0e0,
0xef1a,
0x4d19,
{0xab, 0xa8, 0x67, 0xa1, 0x63, 0x07, 0x3d, 0x13}};
static const char* DecoderGUIDToStr(const GUID& aGuid) {
if (aGuid == DXVA2_ModeH264_VLD_NoFGT) {
return "H264";
}
if (aGuid == DXVA2_Intel_ClearVideo_ModeH264_VLD_NoFGT) {
return "Intel H264";
}
if (aGuid == DXVA2_ModeVP8_VLD) {
return "VP8";
}
if (aGuid == DXVA2_ModeVP9_VLD_Profile0) {
return "VP9 Profile0";
}
if (aGuid == DXVA2_ModeVP9_VLD_10bit_Profile2) {
return "VP9 10bits Profile2";
}
if (aGuid == DXVA2_ModeAV1_VLD_Profile0) {
return "AV1 Profile0";
}
if (aGuid == DXVA2_ModeAV1_VLD_Profile1) {
return "AV1 Profile1";
}
if (aGuid == DXVA2_ModeAV1_VLD_Profile2) {
return "AV1 Profile2";
}
if (aGuid == DXVA2_ModeAV1_VLD_12bit_Profile2) {
return "AV1 12bits Profile2";
}
if (aGuid == DXVA2_ModeAV1_VLD_12bit_Profile2_420) {
return "AV1 12bits Profile2 420";
}
if (aGuid == DXVA2_ModeHEVC_VLD_MAIN) {
return "HEVC main";
}
if (aGuid == DXVA2_ModeHEVC_VLD_MAIN10) {
return "HEVC main10";
}
return "none";
}
// Count of the number of DXVAManager's we've created. This is also the
// number of videos we're decoding with DXVA. Use on main thread only.
static Atomic<uint32_t> sDXVAVideosCount(0);
class D3D11DXVA2Manager : public DXVA2Manager {
public:
D3D11DXVA2Manager();
virtual ~D3D11DXVA2Manager();
HRESULT Init(layers::KnowsCompositor* aKnowsCompositor,
nsACString& aFailureReason, ID3D11Device* aDevice);
HRESULT InitInternal(layers::KnowsCompositor* aKnowsCompositor,
nsACString& aFailureReason, ID3D11Device* aDevice);
IUnknown* GetDXVADeviceManager() override;
// Copies a region (aRegion) of the video frame stored in aVideoSample
// into an image which is returned by aOutImage.
HRESULT CopyToImage(IMFSample* aVideoSample, const gfx::IntRect& aRegion,
Image** aOutImage) override;
HRESULT WrapTextureWithImage(IMFSample* aVideoSample,
const gfx::IntRect& aRegion,
layers::Image** aOutImage) override;
HRESULT CopyToBGRATexture(ID3D11Texture2D* aInTexture, uint32_t aArrayIndex,
ID3D11Texture2D** aOutTexture) override;
HRESULT ConfigureForSize(IMFMediaType* aInputType,
gfx::YUVColorSpace aColorSpace,
gfx::ColorRange aColorRange, uint32_t aWidth,
uint32_t aHeight) override;
bool IsD3D11() override { return true; }
bool SupportsConfig(const VideoInfo& aInfo, IMFMediaType* aInputType,
IMFMediaType* aOutputType) override;
void BeforeShutdownVideoMFTDecoder() override;
bool SupportsZeroCopyNV12Texture() override {
if (mIMFSampleUsageInfo->SupportsZeroCopyNV12Texture() &&
(mDevice != DeviceManagerDx::Get()->GetCompositorDevice())) {
mIMFSampleUsageInfo->DisableZeroCopyNV12Texture();
}
return mIMFSampleUsageInfo->SupportsZeroCopyNV12Texture();
}
private:
HRESULT CreateOutputSample(RefPtr<IMFSample>& aSample,
ID3D11Texture2D* aTexture);
// This is used for check whether hw decoding is possible before using MFT for
// decoding.
bool CanCreateDecoder(const D3D11_VIDEO_DECODER_DESC& aDesc) const;
void RefreshIMFSampleWrappers();
void ReleaseAllIMFSamples();
RefPtr<ID3D11Device> mDevice;
RefPtr<ID3D11DeviceContext> mContext;
RefPtr<IMFDXGIDeviceManager> mDXGIDeviceManager;
RefPtr<MFTDecoder> mTransform;
RefPtr<D3D11RecycleAllocator> mTextureClientAllocator;
RefPtr<layers::KnowsCompositor> mKnowsCompositor;
RefPtr<ID3D11VideoDecoder> mDecoder;
RefPtr<layers::SyncObjectClient> mSyncObject;
uint32_t mWidth = 0;
uint32_t mHeight = 0;
UINT mDeviceManagerToken = 0;
RefPtr<IMFMediaType> mInputType;
GUID mInputSubType;
gfx::YUVColorSpace mYUVColorSpace;
gfx::ColorRange mColorRange = gfx::ColorRange::LIMITED;
std::list<ThreadSafeWeakPtr<layers::IMFSampleWrapper>> mIMFSampleWrappers;
RefPtr<layers::IMFSampleUsageInfo> mIMFSampleUsageInfo;
uint32_t mVendorID = 0;
};
bool D3D11DXVA2Manager::SupportsConfig(const VideoInfo& aInfo,
IMFMediaType* aInputType,
IMFMediaType* aOutputType) {
D3D11_VIDEO_DECODER_DESC desc = {GUID_NULL, 0, 0, DXGI_FORMAT_UNKNOWN};
HRESULT hr = MFGetAttributeSize(aInputType, MF_MT_FRAME_SIZE,
&desc.SampleWidth, &desc.SampleHeight);
NS_ENSURE_TRUE(SUCCEEDED(hr), false);
NS_ENSURE_TRUE(desc.SampleWidth <= MAX_VIDEO_WIDTH, false);
NS_ENSURE_TRUE(desc.SampleHeight <= MAX_VIDEO_HEIGHT, false);
GUID subtype;
hr = aInputType->GetGUID(MF_MT_SUBTYPE, &subtype);
NS_ENSURE_TRUE(SUCCEEDED(hr), false);
if (subtype == MFVideoFormat_H264) {
// IsUnsupportedResolution is only used to work around an AMD H264 issue.
const float framerate = [&]() {
UINT32 numerator;
UINT32 denominator;
if (SUCCEEDED(MFGetAttributeRatio(aInputType, MF_MT_FRAME_RATE,
&numerator, &denominator))) {
return static_cast<float>(numerator) / denominator;
}
return 30.0f;
}();
NS_ENSURE_FALSE(
IsUnsupportedResolution(desc.SampleWidth, desc.SampleHeight, framerate),
false);
NS_ENSURE_TRUE(aInfo.mColorDepth == ColorDepth::COLOR_8, false);
RefPtr<ID3D11VideoDevice> videoDevice;
hr = mDevice->QueryInterface(
static_cast<ID3D11VideoDevice**>(getter_AddRefs(videoDevice)));
GUID guids[] = {DXVA2_ModeH264_VLD_NoFGT,
DXVA2_Intel_ClearVideo_ModeH264_VLD_NoFGT};
for (const GUID& guid : guids) {
BOOL supported = false;
hr = videoDevice->CheckVideoDecoderFormat(&guid, DXGI_FORMAT_NV12,
&supported);
if (SUCCEEDED(hr) && supported) {
desc.Guid = guid;
break;
}
}
} else if (subtype == MFVideoFormat_VP80) {
NS_ENSURE_TRUE(aInfo.mColorDepth == ColorDepth::COLOR_8, false);
desc.Guid = DXVA2_ModeVP8_VLD;
} else if (subtype == MFVideoFormat_VP90) {
NS_ENSURE_TRUE(aInfo.mColorDepth == ColorDepth::COLOR_8 ||
aInfo.mColorDepth == ColorDepth::COLOR_10,
false);
uint8_t profile;
if (aInfo.mExtraData && !aInfo.mExtraData->IsEmpty()) {
VPXDecoder::VPXStreamInfo vp9Info;
VPXDecoder::ReadVPCCBox(vp9Info, aInfo.mExtraData);
profile = vp9Info.mProfile;
} else {
// If no vpcC is present, we can't know the profile, which limits the
// subsampling mode, but 4:2:0 is most supported so default to profiles 0
// and 2:
// Profile 0 = 8bit, 4:2:0
// Profile 2 = 10/12bit, 4:2:0
profile = aInfo.mColorDepth == ColorDepth::COLOR_8 ? 0 : 2;
}
switch (profile) {
case 0:
desc.Guid = DXVA2_ModeVP9_VLD_Profile0;
break;
case 2:
desc.Guid = DXVA2_ModeVP9_VLD_10bit_Profile2;
break;
default:
break;
}
} else if (subtype == MFVideoFormat_AV1) {
uint8_t profile;
bool yuv420;
if (aInfo.mExtraData && !aInfo.mExtraData->IsEmpty()) {
AOMDecoder::AV1SequenceInfo av1Info;
bool hadSeqHdr;
AOMDecoder::ReadAV1CBox(aInfo.mExtraData, av1Info, hadSeqHdr);
profile = av1Info.mProfile;
yuv420 = av1Info.mSubsamplingX && av1Info.mSubsamplingY;
} else {
// If no av1C is present, we can't get profile or subsampling mode. 4:2:0
// subsampling is most likely to be supported in hardware, so set av1Info
// accordingly.
// 8bit/10bit = Main profile, 4:2:0
// 12bit = Professional, 4:2:0
profile = aInfo.mColorDepth == ColorDepth::COLOR_12 ? 2 : 0;
yuv420 = true;
}
switch (profile) {
case 0:
desc.Guid = DXVA2_ModeAV1_VLD_Profile0;
break;
case 1:
desc.Guid = DXVA2_ModeAV1_VLD_Profile1;
break;
case 2:
MOZ_ASSERT(aInfo.mColorDepth < ColorDepth::COLOR_16);
if (aInfo.mColorDepth == ColorDepth::COLOR_12) {
if (yuv420) {
desc.Guid = DXVA2_ModeAV1_VLD_12bit_Profile2_420;
} else {
desc.Guid = DXVA2_ModeAV1_VLD_12bit_Profile2;
}
} else {
desc.Guid = DXVA2_ModeAV1_VLD_Profile2;
}
break;
default:
break;
}
} else if (subtype == MFVideoFormat_HEVC) {
RefPtr<ID3D11VideoDevice> videoDevice;
hr = mDevice->QueryInterface(
static_cast<ID3D11VideoDevice**>(getter_AddRefs(videoDevice)));
GUID guids[] = {DXVA2_ModeHEVC_VLD_MAIN, DXVA2_ModeHEVC_VLD_MAIN10};
for (const GUID& guid : guids) {
BOOL supported = false;
hr = videoDevice->CheckVideoDecoderFormat(&guid, DXGI_FORMAT_NV12,
&supported);
if (SUCCEEDED(hr) && supported) {
desc.Guid = guid;
break;
}
}
}
LOG("Select %s GUID", DecoderGUIDToStr(desc.Guid));
hr = aOutputType->GetGUID(MF_MT_SUBTYPE, &subtype);
if (SUCCEEDED(hr)) {
if (subtype == MFVideoFormat_NV12) {
desc.OutputFormat = DXGI_FORMAT_NV12;
} else if (subtype == MFVideoFormat_P010) {
desc.OutputFormat = DXGI_FORMAT_P010;
} else if (subtype == MFVideoFormat_P016) {
desc.OutputFormat = DXGI_FORMAT_P016;
}
}
if (desc.Guid == GUID_NULL || desc.OutputFormat == DXGI_FORMAT_UNKNOWN) {
return false;
}
return CanCreateDecoder(desc);
}
D3D11DXVA2Manager::D3D11DXVA2Manager()
: mIMFSampleUsageInfo(new layers::IMFSampleUsageInfo) {}
D3D11DXVA2Manager::~D3D11DXVA2Manager() {}
IUnknown* D3D11DXVA2Manager::GetDXVADeviceManager() {
MutexAutoLock lock(mLock);
return mDXGIDeviceManager;
}
HRESULT
D3D11DXVA2Manager::Init(layers::KnowsCompositor* aKnowsCompositor,
nsACString& aFailureReason, ID3D11Device* aDevice) {
if (aDevice) {
return InitInternal(aKnowsCompositor, aFailureReason, aDevice);
}
HRESULT hr;
ScopedGfxFeatureReporter reporter("DXVA2D3D11");
hr = InitInternal(aKnowsCompositor, aFailureReason, aDevice);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
if (layers::ImageBridgeChild::GetSingleton() || !aKnowsCompositor) {
// There's no proper KnowsCompositor for ImageBridge currently (and it
// implements the interface), so just use that if it's available.
mTextureClientAllocator = new D3D11RecycleAllocator(
layers::ImageBridgeChild::GetSingleton().get(), mDevice,
gfx::SurfaceFormat::NV12);
if (ImageBridgeChild::GetSingleton() &&
StaticPrefs::media_wmf_use_sync_texture_AtStartup() &&
mDevice != DeviceManagerDx::Get()->GetCompositorDevice()) {
// We use a syncobject to avoid the cost of the mutex lock when
// compositing, and because it allows color conversion ocurring directly
// from this texture DXVA does not seem to accept IDXGIKeyedMutex textures
// as input.
mSyncObject = layers::SyncObjectClient::CreateSyncObjectClient(
layers::ImageBridgeChild::GetSingleton()
->GetTextureFactoryIdentifier()
.mSyncHandle,
mDevice);
}
} else {
mTextureClientAllocator = new D3D11RecycleAllocator(
aKnowsCompositor, mDevice, gfx::SurfaceFormat::NV12);
mKnowsCompositor = aKnowsCompositor;
if (StaticPrefs::media_wmf_use_sync_texture_AtStartup()) {
// We use a syncobject to avoid the cost of the mutex lock when
// compositing, and because it allows color conversion ocurring directly
// from this texture DXVA does not seem to accept IDXGIKeyedMutex textures
// as input.
mSyncObject = layers::SyncObjectClient::CreateSyncObjectClient(
aKnowsCompositor->GetTextureFactoryIdentifier().mSyncHandle, mDevice);
}
}
mTextureClientAllocator->SetMaxPoolSize(5);
Telemetry::Accumulate(Telemetry::MEDIA_DECODER_BACKEND_USED,
uint32_t(media::MediaDecoderBackend::WMFDXVA2D3D11));
reporter.SetSuccessful();
return S_OK;
}
HRESULT
D3D11DXVA2Manager::InitInternal(layers::KnowsCompositor* aKnowsCompositor,
nsACString& aFailureReason,
ID3D11Device* aDevice) {
HRESULT hr;
mDevice = aDevice;
if (!mDevice) {
DeviceManagerDx::DeviceFlagSet flags;
if (aKnowsCompositor && aKnowsCompositor->UsingHardwareWebRender()) {
flags += DeviceManagerDx::DeviceFlag::isHardwareWebRenderInUse;
}
mDevice = gfx::DeviceManagerDx::Get()->CreateDecoderDevice(flags);
if (!mDevice) {
aFailureReason.AssignLiteral("Failed to create D3D11 device for decoder");
return E_FAIL;
}
}
RefPtr<ID3D10Multithread> mt;
hr = mDevice->QueryInterface((ID3D10Multithread**)getter_AddRefs(mt));
NS_ENSURE_TRUE(SUCCEEDED(hr) && mt, hr);
mt->SetMultithreadProtected(TRUE);
mDevice->GetImmediateContext(getter_AddRefs(mContext));
hr = wmf::MFCreateDXGIDeviceManager(&mDeviceManagerToken,
getter_AddRefs(mDXGIDeviceManager));
if (!SUCCEEDED(hr)) {
aFailureReason =
nsPrintfCString("MFCreateDXGIDeviceManager failed with code %lX", hr);
return hr;
}
hr = mDXGIDeviceManager->ResetDevice(mDevice, mDeviceManagerToken);
if (!SUCCEEDED(hr)) {
aFailureReason = nsPrintfCString(
"IMFDXGIDeviceManager::ResetDevice failed with code %lX", hr);
return hr;
}
// The IMFTransform interface used by MFTDecoder is documented to require to
// run on an MTA thread.
// The main thread (where this function is called) is STA, not MTA.
RefPtr<MFTDecoder> mft;
mozilla::mscom::EnsureMTA([&]() -> void {
mft = new MFTDecoder();
hr = mft->Create(MFT_CATEGORY_VIDEO_PROCESSOR, MFVideoFormat_NV12,
MFVideoFormat_ARGB32);
if (!SUCCEEDED(hr)) {
aFailureReason = nsPrintfCString(
"MFTDecoder::Create of Video Processor MFT for color conversion "
"failed with code %lX",
hr);
return;
}
hr = mft->SendMFTMessage(MFT_MESSAGE_SET_D3D_MANAGER,
ULONG_PTR(mDXGIDeviceManager.get()));
if (!SUCCEEDED(hr)) {
aFailureReason = nsPrintfCString(
"MFTDecoder::SendMFTMessage(MFT_MESSAGE_"
"SET_D3D_MANAGER) failed with code %lX",
hr);
return;
}
});
if (!SUCCEEDED(hr)) {
return hr;
}
mTransform = mft;
RefPtr<IDXGIDevice> dxgiDevice;
hr = mDevice->QueryInterface(
static_cast<IDXGIDevice**>(getter_AddRefs(dxgiDevice)));
if (!SUCCEEDED(hr)) {
aFailureReason =
nsPrintfCString("QI to IDXGIDevice failed with code %lX", hr);
return hr;
}
RefPtr<IDXGIAdapter> adapter;
hr = dxgiDevice->GetAdapter(adapter.StartAssignment());
if (!SUCCEEDED(hr)) {
aFailureReason =
nsPrintfCString("IDXGIDevice::GetAdapter failed with code %lX", hr);
return hr;
}
DXGI_ADAPTER_DESC adapterDesc;
hr = adapter->GetDesc(&adapterDesc);
if (!SUCCEEDED(hr)) {
aFailureReason =
nsPrintfCString("IDXGIAdapter::GetDesc failed with code %lX", hr);
return hr;
}
mVendorID = adapterDesc.VendorId;
if ((adapterDesc.VendorId == 0x1022 || adapterDesc.VendorId == 0x1002) &&
!StaticPrefs::media_wmf_skip_blacklist()) {
for (const auto& model : sAMDPreUVD4) {
if (adapterDesc.DeviceId == model) {
mIsAMDPreUVD4 = true;
break;
}
}
}
if (!IsD3D11() || !XRE_IsGPUProcess() ||
(mDevice != DeviceManagerDx::Get()->GetCompositorDevice())) {
mIMFSampleUsageInfo->DisableZeroCopyNV12Texture();
}
return S_OK;
}
HRESULT
D3D11DXVA2Manager::CreateOutputSample(RefPtr<IMFSample>& aSample,
ID3D11Texture2D* aTexture) {
RefPtr<IMFSample> sample;
HRESULT hr = wmf::MFCreateSample(getter_AddRefs(sample));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<IMFMediaBuffer> buffer;
hr = wmf::MFCreateDXGISurfaceBuffer(__uuidof(ID3D11Texture2D), aTexture, 0,
FALSE, getter_AddRefs(buffer));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = sample->AddBuffer(buffer);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
aSample = sample;
return S_OK;
}
HRESULT
D3D11DXVA2Manager::CopyToImage(IMFSample* aVideoSample,
const gfx::IntRect& aRegion, Image** aOutImage) {
NS_ENSURE_TRUE(aVideoSample, E_POINTER);
NS_ENSURE_TRUE(aOutImage, E_POINTER);
MOZ_ASSERT(mTextureClientAllocator);
RefPtr<D3D11ShareHandleImage> image =
new D3D11ShareHandleImage(gfx::IntSize(mWidth, mHeight), aRegion,
ToColorSpace2(mYUVColorSpace), mColorRange);
// Retrieve the DXGI_FORMAT for the current video sample.
RefPtr<IMFMediaBuffer> buffer;
HRESULT hr = aVideoSample->GetBufferByIndex(0, getter_AddRefs(buffer));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<IMFDXGIBuffer> dxgiBuf;
hr = buffer->QueryInterface((IMFDXGIBuffer**)getter_AddRefs(dxgiBuf));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<ID3D11Texture2D> tex;
hr = dxgiBuf->GetResource(__uuidof(ID3D11Texture2D), getter_AddRefs(tex));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
D3D11_TEXTURE2D_DESC inDesc;
tex->GetDesc(&inDesc);
bool ok = image->AllocateTexture(mTextureClientAllocator, mDevice);
NS_ENSURE_TRUE(ok, E_FAIL);
RefPtr<TextureClient> client =
image->GetTextureClient(ImageBridgeChild::GetSingleton().get());
NS_ENSURE_TRUE(client, E_FAIL);
RefPtr<ID3D11Texture2D> texture = image->GetTexture();
D3D11_TEXTURE2D_DESC outDesc;
texture->GetDesc(&outDesc);
RefPtr<IDXGIKeyedMutex> mutex;
texture->QueryInterface((IDXGIKeyedMutex**)getter_AddRefs(mutex));
{
AutoTextureLock(mutex, hr, 2000);
if (mutex && (FAILED(hr) || hr == WAIT_TIMEOUT || hr == WAIT_ABANDONED)) {
return hr;
}
if (!mutex && mDevice != DeviceManagerDx::Get()->GetCompositorDevice()) {
NS_ENSURE_TRUE(mSyncObject, E_FAIL);
}
UINT height = std::min(inDesc.Height, outDesc.Height);
PerformanceRecorder<PlaybackStage> perfRecorder(
MediaStage::CopyDecodedVideo, height);
// The D3D11TextureClientAllocator may return a different texture format
// than preferred. In which case the destination texture will be BGRA32.
if (outDesc.Format == inDesc.Format) {
// Our video frame is stored in a non-sharable ID3D11Texture2D. We need
// to create a copy of that frame as a sharable resource, save its share
// handle, and put that handle into the rendering pipeline.
UINT width = std::min(inDesc.Width, outDesc.Width);
D3D11_BOX srcBox = {0, 0, 0, width, height, 1};
UINT index;
dxgiBuf->GetSubresourceIndex(&index);
mContext->CopySubresourceRegion(texture, 0, 0, 0, 0, tex, index, &srcBox);
} else {
// Use MFT to do color conversion.
hr = E_FAIL;
mozilla::mscom::EnsureMTA(
[&]() -> void { hr = mTransform->Input(aVideoSample); });
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<IMFSample> sample;
hr = CreateOutputSample(sample, texture);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = E_FAIL;
mozilla::mscom::EnsureMTA(
[&]() -> void { hr = mTransform->Output(&sample); });
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
}
perfRecorder.Record();
}
if (!mutex && mDevice != DeviceManagerDx::Get()->GetCompositorDevice() &&
mSyncObject) {
static StaticMutex sMutex MOZ_UNANNOTATED;
// Ensure that we only ever attempt to synchronise via the sync object
// serially as when using the same D3D11 device for multiple video decoders
// it can lead to deadlocks.
StaticMutexAutoLock lock(sMutex);
// It appears some race-condition may allow us to arrive here even when
// mSyncObject is null. It's better to avoid that crash.
client->SyncWithObject(mSyncObject);
if (!mSyncObject->Synchronize(true)) {
return DXGI_ERROR_DEVICE_RESET;
}
} else if (mDevice == DeviceManagerDx::Get()->GetCompositorDevice() &&
mVendorID != 0x8086) {
MOZ_ASSERT(XRE_IsGPUProcess());
MOZ_ASSERT(mVendorID);
// Normally when D3D11Texture2D is copied by
// ID3D11DeviceContext::CopySubresourceRegion() with compositor device,
// WebRender does not need to wait copy complete, since WebRender also uses
// compositor device. But with some non-Intel GPUs, the copy complete need
// to be wait explicitly even with compositor device such as when using
// video overlays.
RefPtr<ID3D11DeviceContext> context;
mDevice->GetImmediateContext(getter_AddRefs(context));
RefPtr<ID3D11Query> query;
CD3D11_QUERY_DESC desc(D3D11_QUERY_EVENT);
HRESULT hr = mDevice->CreateQuery(&desc, getter_AddRefs(query));
if (SUCCEEDED(hr) && query) {
context->End(query);
auto* data = client->GetInternalData()->AsD3D11TextureData();
MOZ_ASSERT(data);
if (data) {
// Wait query happens only just before blitting for video overlay.
data->RegisterQuery(query);
} else {
gfxCriticalNoteOnce << "D3D11TextureData does not exist";
}
} else {
gfxCriticalNoteOnce << "Could not create D3D11_QUERY_EVENT: "
<< gfx::hexa(hr);
}
}
image.forget(aOutImage);
return S_OK;
}
HRESULT D3D11DXVA2Manager::WrapTextureWithImage(IMFSample* aVideoSample,
const gfx::IntRect& aRegion,
layers::Image** aOutImage) {
NS_ENSURE_TRUE(aVideoSample, E_POINTER);
NS_ENSURE_TRUE(aOutImage, E_POINTER);
RefPtr<IMFMediaBuffer> buffer;
HRESULT hr = aVideoSample->GetBufferByIndex(0, getter_AddRefs(buffer));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<IMFDXGIBuffer> dxgiBuf;
hr = buffer->QueryInterface((IMFDXGIBuffer**)getter_AddRefs(dxgiBuf));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<ID3D11Texture2D> texture;
hr = dxgiBuf->GetResource(__uuidof(ID3D11Texture2D), getter_AddRefs(texture));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
D3D11_TEXTURE2D_DESC desc;
texture->GetDesc(&desc);
UINT arrayIndex;
dxgiBuf->GetSubresourceIndex(&arrayIndex);
RefreshIMFSampleWrappers();
RefPtr<D3D11TextureIMFSampleImage> image = new D3D11TextureIMFSampleImage(
aVideoSample, texture, arrayIndex, gfx::IntSize(mWidth, mHeight), aRegion,
ToColorSpace2(mYUVColorSpace), mColorRange);
image->AllocateTextureClient(mKnowsCompositor, mIMFSampleUsageInfo);
RefPtr<IMFSampleWrapper> wrapper = image->GetIMFSampleWrapper();
ThreadSafeWeakPtr<IMFSampleWrapper> weak(wrapper);
mIMFSampleWrappers.push_back(weak);
image.forget(aOutImage);
return S_OK;
}
void D3D11DXVA2Manager::RefreshIMFSampleWrappers() {
for (auto it = mIMFSampleWrappers.begin(); it != mIMFSampleWrappers.end();) {
auto wrapper = RefPtr<IMFSampleWrapper>(*it);
if (!wrapper) {
// wrapper is already destroyed.
it = mIMFSampleWrappers.erase(it);
continue;
}
it++;
}
}
void D3D11DXVA2Manager::ReleaseAllIMFSamples() {
for (auto it = mIMFSampleWrappers.begin(); it != mIMFSampleWrappers.end();
it++) {
RefPtr<IMFSampleWrapper> wrapper = RefPtr<IMFSampleWrapper>(*it);
if (wrapper) {
wrapper->ClearVideoSample();
}
}
}
void D3D11DXVA2Manager::BeforeShutdownVideoMFTDecoder() {
ReleaseAllIMFSamples();
}
HRESULT
D3D11DXVA2Manager::CopyToBGRATexture(ID3D11Texture2D* aInTexture,
uint32_t aArrayIndex,
ID3D11Texture2D** aOutTexture) {
NS_ENSURE_TRUE(aInTexture, E_POINTER);
NS_ENSURE_TRUE(aOutTexture, E_POINTER);
HRESULT hr;
RefPtr<ID3D11Texture2D> texture, inTexture;
inTexture = aInTexture;
CD3D11_TEXTURE2D_DESC desc;
aInTexture->GetDesc(&desc);
if (!mInputType || desc.Width != mWidth || desc.Height != mHeight) {
RefPtr<IMFMediaType> inputType;
hr = wmf::MFCreateMediaType(getter_AddRefs(inputType));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = inputType->SetGUID(MF_MT_MAJOR_TYPE, MFMediaType_Video);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
const GUID subType = [&]() {
switch (desc.Format) {
case DXGI_FORMAT_NV12:
return MFVideoFormat_NV12;
case DXGI_FORMAT_P010:
return MFVideoFormat_P010;
case DXGI_FORMAT_P016:
return MFVideoFormat_P016;
default:
MOZ_ASSERT_UNREACHABLE("Unexpected texture type");
return MFVideoFormat_NV12;
}
}();
hr = inputType->SetGUID(MF_MT_SUBTYPE, subType);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = inputType->SetUINT32(MF_MT_INTERLACE_MODE,
MFVideoInterlace_Progressive);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = inputType->SetUINT32(MF_MT_ALL_SAMPLES_INDEPENDENT, TRUE);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = ConfigureForSize(inputType, mYUVColorSpace, mColorRange, desc.Width,
desc.Height);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
}
RefPtr<IDXGIKeyedMutex> mutex;
inTexture->QueryInterface((IDXGIKeyedMutex**)getter_AddRefs(mutex));
// The rest of this function will not work if inTexture implements
// IDXGIKeyedMutex! In that case case we would have to copy to a
// non-mutex using texture.
if (mutex) {
RefPtr<ID3D11Texture2D> newTexture;
desc.MiscFlags = 0;
hr = mDevice->CreateTexture2D(&desc, nullptr, getter_AddRefs(newTexture));
NS_ENSURE_TRUE(SUCCEEDED(hr) && newTexture, E_FAIL);
hr = mutex->AcquireSync(0, 2000);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
mContext->CopyResource(newTexture, inTexture);
mutex->ReleaseSync(0);
inTexture = newTexture;
}
desc.Format = DXGI_FORMAT_B8G8R8A8_UNORM;
desc.BindFlags = D3D11_BIND_RENDER_TARGET | D3D11_BIND_SHADER_RESOURCE;
hr = mDevice->CreateTexture2D(&desc, nullptr, getter_AddRefs(texture));
NS_ENSURE_TRUE(SUCCEEDED(hr) && texture, E_FAIL);
RefPtr<IMFSample> inputSample;
wmf::MFCreateSample(getter_AddRefs(inputSample));
// If these aren't set the decoder fails.
inputSample->SetSampleTime(10);
inputSample->SetSampleDuration(10000);
RefPtr<IMFMediaBuffer> inputBuffer;
hr = wmf::MFCreateDXGISurfaceBuffer(__uuidof(ID3D11Texture2D), inTexture,
aArrayIndex, FALSE,
getter_AddRefs(inputBuffer));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
inputSample->AddBuffer(inputBuffer);
hr = E_FAIL;
mozilla::mscom::EnsureMTA(
[&]() -> void { hr = mTransform->Input(inputSample); });
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<IMFSample> outputSample;
hr = CreateOutputSample(outputSample, texture);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = E_FAIL;
mozilla::mscom::EnsureMTA(
[&]() -> void { hr = mTransform->Output(&outputSample); });
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
texture.forget(aOutTexture);
return S_OK;
}
HRESULT
D3D11DXVA2Manager::ConfigureForSize(IMFMediaType* aInputType,
gfx::YUVColorSpace aColorSpace,
gfx::ColorRange aColorRange,
uint32_t aWidth, uint32_t aHeight) {
GUID subType = {0};
HRESULT hr = aInputType->GetGUID(MF_MT_SUBTYPE, &subType);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
if (subType == mInputSubType && aWidth == mWidth && aHeight == mHeight &&
mYUVColorSpace == aColorSpace && mColorRange == aColorRange) {
// If the media type hasn't changed, don't reconfigure.
return S_OK;
}
// Create a copy of our input type.
RefPtr<IMFMediaType> inputType;
hr = wmf::MFCreateMediaType(getter_AddRefs(inputType));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = aInputType->CopyAllItems(inputType);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = MFSetAttributeSize(inputType, MF_MT_FRAME_SIZE, aWidth, aHeight);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<IMFAttributes> attr;
mozilla::mscom::EnsureMTA(
[&]() -> void { attr = mTransform->GetAttributes(); });
NS_ENSURE_TRUE(attr != nullptr, E_FAIL);
hr = attr->SetUINT32(MF_XVP_PLAYBACK_MODE, TRUE);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = attr->SetUINT32(MF_LOW_LATENCY, FALSE);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
RefPtr<IMFMediaType> outputType;
hr = wmf::MFCreateMediaType(getter_AddRefs(outputType));
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = outputType->SetGUID(MF_MT_MAJOR_TYPE, MFMediaType_Video);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = outputType->SetGUID(MF_MT_SUBTYPE, MFVideoFormat_ARGB32);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = E_FAIL;
mozilla::mscom::EnsureMTA([&]() -> void {
hr = mTransform->SetMediaTypes(
inputType, outputType, [aWidth, aHeight](IMFMediaType* aOutput) {
HRESULT hr = aOutput->SetUINT32(MF_MT_INTERLACE_MODE,
MFVideoInterlace_Progressive);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = aOutput->SetUINT32(MF_MT_ALL_SAMPLES_INDEPENDENT, TRUE);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
hr = MFSetAttributeSize(aOutput, MF_MT_FRAME_SIZE, aWidth, aHeight);
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
return S_OK;
});
});
NS_ENSURE_TRUE(SUCCEEDED(hr), hr);
mWidth = aWidth;
mHeight = aHeight;
mInputType = inputType;
mInputSubType = subType;
mYUVColorSpace = aColorSpace;
mColorRange = aColorRange;
if (mTextureClientAllocator) {
gfx::SurfaceFormat format = [&]() {
if (subType == MFVideoFormat_NV12) {
return gfx::SurfaceFormat::NV12;
} else if (subType == MFVideoFormat_P010) {
return gfx::SurfaceFormat::P010;
} else if (subType == MFVideoFormat_P016) {
return gfx::SurfaceFormat::P016;
} else {
MOZ_ASSERT_UNREACHABLE("Unexpected texture type");
return gfx::SurfaceFormat::NV12;
}
}();
mTextureClientAllocator->SetPreferredSurfaceFormat(format);
}
return S_OK;
}
bool D3D11DXVA2Manager::CanCreateDecoder(
const D3D11_VIDEO_DECODER_DESC& aDesc) const {
RefPtr<ID3D11Device> device = GetDeviceForDecoderCheck();
if (!device) {
LOG("Can't create decoder due to lacking of ID3D11Device!");
return false;
}
RefPtr<ID3D11VideoDevice> videoDevice;
HRESULT hr = device->QueryInterface(
static_cast<ID3D11VideoDevice**>(getter_AddRefs(videoDevice)));
if (FAILED(hr)) {
LOG("Failed to query ID3D11VideoDevice!");
return false;
}
UINT configCount = 0;
hr = videoDevice->GetVideoDecoderConfigCount(&aDesc, &configCount);
if (FAILED(hr)) {
LOG("Failed to get decoder config count!");
return false;
}
for (UINT i = 0; i < configCount; i++) {
D3D11_VIDEO_DECODER_CONFIG config;
hr = videoDevice->GetVideoDecoderConfig(&aDesc, i, &config);
if (SUCCEEDED(hr)) {
RefPtr<ID3D11VideoDecoder> decoder;
hr = videoDevice->CreateVideoDecoder(&aDesc, &config,
decoder.StartAssignment());
return decoder != nullptr;
}
}
return false;
}
/* static */
DXVA2Manager* DXVA2Manager::CreateD3D11DXVA(
layers::KnowsCompositor* aKnowsCompositor, nsACString& aFailureReason,
ID3D11Device* aDevice) {
// DXVA processing takes up a lot of GPU resources, so limit the number of
// videos we use DXVA with at any one time.
uint32_t dxvaLimit = StaticPrefs::media_wmf_dxva_max_videos();
if (sDXVAVideosCount == dxvaLimit) {
aFailureReason.AssignLiteral("Too many DXVA videos playing");
return nullptr;
}
UniquePtr<D3D11DXVA2Manager> manager(new D3D11DXVA2Manager());
HRESULT hr = manager->Init(aKnowsCompositor, aFailureReason, aDevice);
NS_ENSURE_TRUE(SUCCEEDED(hr), nullptr);
return manager.release();
}
DXVA2Manager::DXVA2Manager() : mLock("DXVA2Manager") { ++sDXVAVideosCount; }
DXVA2Manager::~DXVA2Manager() { --sDXVAVideosCount; }
bool DXVA2Manager::IsUnsupportedResolution(const uint32_t& aWidth,
const uint32_t& aHeight,
const float& aFramerate) const {
// AMD cards with UVD3 or earlier perform poorly trying to decode 1080p60 in
// hardware, so use software instead. Pick 45 as an arbitrary upper bound for
// the framerate we can handle.
return !StaticPrefs::media_wmf_amd_highres_enabled() && mIsAMDPreUVD4 &&
(aWidth >= 1920 || aHeight >= 1088) && aFramerate > 45;
}
/* static */
bool DXVA2Manager::IsNV12Supported(uint32_t aVendorID, uint32_t aDeviceID,
const nsAString& aDriverVersionString) {
if (aVendorID == 0x1022 || aVendorID == 0x1002) {
// AMD
// Block old cards regardless of driver version.
for (const auto& model : sAMDPreUVD4) {
if (aDeviceID == model) {
return false;
}
}
// AMD driver earlier than 21.19.411.0 have bugs in their handling of NV12
// surfaces.
uint64_t driverVersion;
if (!widget::ParseDriverVersion(aDriverVersionString, &driverVersion) ||
driverVersion < widget::V(21, 19, 411, 0)) {
return false;
}
} else if (aVendorID == 0x10DE) {
// NVidia
for (const auto& model : sNVIDIABrokenNV12) {
if (aDeviceID == model) {
return false;
}
}
}
return true;
}
} // namespace mozilla
#undef LOG