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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 "mozilla/dom/VideoDecoder.h"
#include "mozilla/dom/VideoDecoderBinding.h"
#include "DecoderTraits.h"
#include "GPUVideoImage.h"
#include "H264.h"
#include "ImageContainer.h"
#include "MediaContainerType.h"
#include "MediaData.h"
#include "VideoUtils.h"
#include "mozilla/Assertions.h"
#include "mozilla/Logging.h"
#include "mozilla/Maybe.h"
#include "mozilla/Try.h"
#include "mozilla/Unused.h"
#include "mozilla/dom/EncodedVideoChunk.h"
#include "mozilla/dom/EncodedVideoChunkBinding.h"
#include "mozilla/dom/ImageUtils.h"
#include "mozilla/dom/Promise.h"
#include "mozilla/dom/VideoColorSpaceBinding.h"
#include "mozilla/dom/VideoFrameBinding.h"
#include "mozilla/dom/WebCodecsUtils.h"
#include "nsPrintfCString.h"
#include "nsReadableUtils.h"
#ifdef XP_MACOSX
# include "MacIOSurfaceImage.h"
#elif MOZ_WAYLAND
# include "mozilla/layers/DMABUFSurfaceImage.h"
# include "mozilla/widget/DMABufSurface.h"
#endif
extern mozilla::LazyLogModule gWebCodecsLog;
namespace mozilla::dom {
#ifdef LOG_INTERNAL
# undef LOG_INTERNAL
#endif // LOG_INTERNAL
#define LOG_INTERNAL(level, msg, ...) \
MOZ_LOG(gWebCodecsLog, LogLevel::level, (msg, ##__VA_ARGS__))
#ifdef LOG
# undef LOG
#endif // LOG
#define LOG(msg, ...) LOG_INTERNAL(Debug, msg, ##__VA_ARGS__)
#ifdef LOGW
# undef LOGW
#endif // LOGW
#define LOGW(msg, ...) LOG_INTERNAL(Warning, msg, ##__VA_ARGS__)
#ifdef LOGE
# undef LOGE
#endif // LOGE
#define LOGE(msg, ...) LOG_INTERNAL(Error, msg, ##__VA_ARGS__)
#ifdef LOGV
# undef LOGV
#endif // LOGV
#define LOGV(msg, ...) LOG_INTERNAL(Verbose, msg, ##__VA_ARGS__)
NS_IMPL_CYCLE_COLLECTION_INHERITED(VideoDecoder, DOMEventTargetHelper,
mErrorCallback, mOutputCallback)
NS_IMPL_ADDREF_INHERITED(VideoDecoder, DOMEventTargetHelper)
NS_IMPL_RELEASE_INHERITED(VideoDecoder, DOMEventTargetHelper)
NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION(VideoDecoder)
NS_INTERFACE_MAP_END_INHERITING(DOMEventTargetHelper)
/*
* Below are helper classes
*/
VideoColorSpaceInternal::VideoColorSpaceInternal(
const VideoColorSpaceInit& aColorSpaceInit)
: mFullRange(NullableToMaybe(aColorSpaceInit.mFullRange)),
mMatrix(NullableToMaybe(aColorSpaceInit.mMatrix)),
mPrimaries(NullableToMaybe(aColorSpaceInit.mPrimaries)),
mTransfer(NullableToMaybe(aColorSpaceInit.mTransfer)) {}
VideoColorSpaceInit VideoColorSpaceInternal::ToColorSpaceInit() const {
VideoColorSpaceInit init;
init.mFullRange = MaybeToNullable(mFullRange);
init.mMatrix = MaybeToNullable(mMatrix);
init.mPrimaries = MaybeToNullable(mPrimaries);
init.mTransfer = MaybeToNullable(mTransfer);
return init;
};
VideoDecoderConfigInternal::VideoDecoderConfigInternal(
const nsAString& aCodec, Maybe<uint32_t>&& aCodedHeight,
Maybe<uint32_t>&& aCodedWidth, Maybe<VideoColorSpaceInternal>&& aColorSpace,
already_AddRefed<MediaByteBuffer> aDescription,
Maybe<uint32_t>&& aDisplayAspectHeight,
Maybe<uint32_t>&& aDisplayAspectWidth,
const HardwareAcceleration& aHardwareAcceleration,
Maybe<bool>&& aOptimizeForLatency)
: mCodec(aCodec),
mCodedHeight(std::move(aCodedHeight)),
mCodedWidth(std::move(aCodedWidth)),
mColorSpace(std::move(aColorSpace)),
mDescription(aDescription),
mDisplayAspectHeight(std::move(aDisplayAspectHeight)),
mDisplayAspectWidth(std::move(aDisplayAspectWidth)),
mHardwareAcceleration(aHardwareAcceleration),
mOptimizeForLatency(std::move(aOptimizeForLatency)) {};
/*static*/
RefPtr<VideoDecoderConfigInternal> VideoDecoderConfigInternal::Create(
const VideoDecoderConfig& aConfig) {
nsCString errorMessage;
if (!VideoDecoderTraits::Validate(aConfig, errorMessage)) {
LOGE("Failed to create VideoDecoderConfigInternal: %s", errorMessage.get());
return nullptr;
}
RefPtr<MediaByteBuffer> description;
if (aConfig.mDescription.WasPassed()) {
auto rv = GetExtraDataFromArrayBuffer(aConfig.mDescription.Value());
if (rv.isErr()) { // Invalid description data.
LOGE(
"Failed to create VideoDecoderConfigInternal due to invalid "
"description data. Error: 0x%08" PRIx32,
static_cast<uint32_t>(rv.unwrapErr()));
return nullptr;
}
description = rv.unwrap();
}
return MakeRefPtr<VideoDecoderConfigInternal>(
aConfig.mCodec, OptionalToMaybe(aConfig.mCodedHeight),
OptionalToMaybe(aConfig.mCodedWidth),
OptionalToMaybe(aConfig.mColorSpace), description.forget(),
OptionalToMaybe(aConfig.mDisplayAspectHeight),
OptionalToMaybe(aConfig.mDisplayAspectWidth),
aConfig.mHardwareAcceleration,
OptionalToMaybe(aConfig.mOptimizeForLatency));
}
nsCString VideoDecoderConfigInternal::ToString() const {
nsCString rv;
rv.Append(NS_ConvertUTF16toUTF8(mCodec));
if (mCodedWidth.isSome()) {
rv.AppendPrintf("coded: %dx%d", mCodedWidth.value(), mCodedHeight.value());
}
if (mDisplayAspectWidth.isSome()) {
rv.AppendPrintf("display %dx%d", mDisplayAspectWidth.value(),
mDisplayAspectHeight.value());
}
if (mColorSpace.isSome()) {
rv.AppendPrintf("colorspace %s", "todo");
}
if (mDescription) {
rv.AppendPrintf("extradata: %zu bytes", mDescription->Length());
}
rv.AppendPrintf("hw accel: %s", GetEnumString(mHardwareAcceleration).get());
if (mOptimizeForLatency.isSome()) {
rv.AppendPrintf("optimize for latency: %s",
mOptimizeForLatency.value() ? "true" : "false");
}
return rv;
}
/*
* The followings are helpers for VideoDecoder methods
*/
struct MIMECreateParam {
explicit MIMECreateParam(const VideoDecoderConfigInternal& aConfig)
: mParsedCodec(ParseCodecString(aConfig.mCodec).valueOr(EmptyString())),
mWidth(aConfig.mCodedWidth),
mHeight(aConfig.mCodedHeight) {}
explicit MIMECreateParam(const VideoDecoderConfig& aConfig)
: mParsedCodec(ParseCodecString(aConfig.mCodec).valueOr(EmptyString())),
mWidth(OptionalToMaybe(aConfig.mCodedWidth)),
mHeight(OptionalToMaybe(aConfig.mCodedHeight)) {}
const nsString mParsedCodec;
const Maybe<uint32_t> mWidth;
const Maybe<uint32_t> mHeight;
};
static nsTArray<nsCString> GuessMIMETypes(const MIMECreateParam& aParam) {
const auto codec = NS_ConvertUTF16toUTF8(aParam.mParsedCodec);
nsTArray<nsCString> types;
for (const nsCString& container : GuessContainers(aParam.mParsedCodec)) {
nsPrintfCString mime("video/%s; codecs=%s", container.get(), codec.get());
if (aParam.mWidth) {
mime.AppendPrintf("; width=%d", *aParam.mWidth);
}
if (aParam.mHeight) {
mime.AppendPrintf("; height=%d", *aParam.mHeight);
}
types.AppendElement(mime);
}
return types;
}
template <typename Config>
static bool CanDecode(const Config& aConfig) {
auto param = MIMECreateParam(aConfig);
// TODO: Enable WebCodecs on Android (Bug 1840508)
if (IsOnAndroid()) {
return false;
}
if (!IsSupportedVideoCodec(param.mParsedCodec)) {
return false;
}
// TODO (1880326): code below is wrongly using the logic of HTMLMediaElement
// for determining if a codec can be played, and incorrect codec string for
// h264 are accepted for HTMLMediaElement for compat reasons. Perform stricter
// check here until we fix it for real.
if (IsH264CodecString(param.mParsedCodec)) {
uint8_t profile, constraint;
H264_LEVEL level;
bool supported =
ExtractH264CodecDetails(aConfig.mCodec, profile, constraint, level,
H264CodecStringStrictness::Strict);
if (!supported) {
return false;
}
}
// TODO (1880326): Instead of calling CanHandleContainerType with the guessed
// the containers, DecoderTraits should provide an API to tell if a codec is
// decodable or not.
for (const nsCString& mime : GuessMIMETypes(param)) {
if (Maybe<MediaContainerType> containerType =
MakeMediaExtendedMIMEType(mime)) {
if (DecoderTraits::CanHandleContainerType(
*containerType, nullptr /* DecoderDoctorDiagnostics */) !=
CANPLAY_NO) {
return true;
}
}
}
return false;
}
static nsTArray<UniquePtr<TrackInfo>> GetTracksInfo(
const VideoDecoderConfigInternal& aConfig) {
// TODO: Instead of calling GetTracksInfo with the guessed containers,
// DecoderTraits should provide an API to create the TrackInfo directly.
for (const nsCString& mime : GuessMIMETypes(MIMECreateParam(aConfig))) {
if (Maybe<MediaContainerType> containerType =
MakeMediaExtendedMIMEType(mime)) {
if (nsTArray<UniquePtr<TrackInfo>> tracks =
DecoderTraits::GetTracksInfo(*containerType);
!tracks.IsEmpty()) {
return tracks;
}
}
}
return {};
}
static Result<Ok, nsresult> CloneConfiguration(
RootedDictionary<VideoDecoderConfig>& aDest, JSContext* aCx,
const VideoDecoderConfig& aConfig, ErrorResult& aRv) {
DebugOnly<nsCString> str;
MOZ_ASSERT(VideoDecoderTraits::Validate(aConfig, str));
aDest.mCodec = aConfig.mCodec;
if (aConfig.mCodedHeight.WasPassed()) {
aDest.mCodedHeight.Construct(aConfig.mCodedHeight.Value());
}
if (aConfig.mCodedWidth.WasPassed()) {
aDest.mCodedWidth.Construct(aConfig.mCodedWidth.Value());
}
if (aConfig.mColorSpace.WasPassed()) {
aDest.mColorSpace.Construct(aConfig.mColorSpace.Value());
}
if (aConfig.mDescription.WasPassed()) {
aDest.mDescription.Construct();
MOZ_TRY(CloneBuffer(aCx, aDest.mDescription.Value(),
aConfig.mDescription.Value(), aRv));
}
if (aConfig.mDisplayAspectHeight.WasPassed()) {
aDest.mDisplayAspectHeight.Construct(aConfig.mDisplayAspectHeight.Value());
}
if (aConfig.mDisplayAspectWidth.WasPassed()) {
aDest.mDisplayAspectWidth.Construct(aConfig.mDisplayAspectWidth.Value());
}
aDest.mHardwareAcceleration = aConfig.mHardwareAcceleration;
if (aConfig.mOptimizeForLatency.WasPassed()) {
aDest.mOptimizeForLatency.Construct(aConfig.mOptimizeForLatency.Value());
}
return Ok();
}
static Maybe<VideoPixelFormat> GuessPixelFormat(layers::Image* aImage) {
if (aImage) {
// TODO: Implement ImageUtils::Impl for MacIOSurfaceImage and
// DMABUFSurfaceImage?
if (aImage->AsPlanarYCbCrImage() || aImage->AsNVImage()) {
const ImageUtils imageUtils(aImage);
Maybe<dom::ImageBitmapFormat> format = imageUtils.GetFormat();
Maybe<VideoPixelFormat> f =
format.isSome() ? ImageBitmapFormatToVideoPixelFormat(format.value())
: Nothing();
// ImageBitmapFormat cannot distinguish YUV420 or YUV420A.
bool hasAlpha = aImage->AsPlanarYCbCrImage() &&
aImage->AsPlanarYCbCrImage()->GetData() &&
aImage->AsPlanarYCbCrImage()->GetData()->mAlpha;
if (f && *f == VideoPixelFormat::I420 && hasAlpha) {
return Some(VideoPixelFormat::I420A);
}
return f;
}
if (layers::GPUVideoImage* image = aImage->AsGPUVideoImage()) {
RefPtr<layers::ImageBridgeChild> imageBridge =
layers::ImageBridgeChild::GetSingleton();
layers::TextureClient* texture = image->GetTextureClient(imageBridge);
if (NS_WARN_IF(!texture)) {
return Nothing();
}
return SurfaceFormatToVideoPixelFormat(texture->GetFormat());
}
#ifdef XP_MACOSX
if (layers::MacIOSurfaceImage* image = aImage->AsMacIOSurfaceImage()) {
MOZ_ASSERT(image->GetSurface());
return SurfaceFormatToVideoPixelFormat(image->GetSurface()->GetFormat());
}
#endif
#ifdef MOZ_WAYLAND
if (layers::DMABUFSurfaceImage* image = aImage->AsDMABUFSurfaceImage()) {
MOZ_ASSERT(image->GetSurface());
return SurfaceFormatToVideoPixelFormat(image->GetSurface()->GetFormat());
}
#endif
}
LOGW("Failed to get pixel format from layers::Image");
return Nothing();
}
static VideoColorSpaceInternal GuessColorSpace(
const layers::PlanarYCbCrData* aData) {
if (!aData) {
LOGE("nullptr in GuessColorSpace");
return {};
}
VideoColorSpaceInternal colorSpace;
colorSpace.mFullRange = Some(ToFullRange(aData->mColorRange));
if (Maybe<VideoMatrixCoefficients> m =
ToMatrixCoefficients(aData->mYUVColorSpace)) {
colorSpace.mMatrix = ToMatrixCoefficients(aData->mYUVColorSpace);
colorSpace.mPrimaries = ToPrimaries(aData->mColorPrimaries);
}
if (!colorSpace.mPrimaries) {
LOG("Missing primaries, guessing from colorspace");
// Make an educated guess based on the coefficients.
colorSpace.mPrimaries = colorSpace.mMatrix.map([](const auto& aMatrix) {
switch (aMatrix) {
case VideoMatrixCoefficients::Bt2020_ncl:
return VideoColorPrimaries::Bt2020;
case VideoMatrixCoefficients::Rgb:
case VideoMatrixCoefficients::Bt470bg:
case VideoMatrixCoefficients::Smpte170m:
LOGW(
"Warning: Falling back to BT709 when attempting to determine the "
"primaries function of a YCbCr buffer");
[[fallthrough]];
case VideoMatrixCoefficients::Bt709:
return VideoColorPrimaries::Bt709;
}
MOZ_ASSERT_UNREACHABLE("Unexpected matrix coefficients");
LOGW(
"Warning: Falling back to BT709 due to unexpected matrix "
"coefficients "
"when attempting to determine the primaries function of a YCbCr "
"buffer");
return VideoColorPrimaries::Bt709;
});
}
if (Maybe<VideoTransferCharacteristics> c =
ToTransferCharacteristics(aData->mTransferFunction)) {
colorSpace.mTransfer = Some(*c);
}
if (!colorSpace.mTransfer) {
LOG("Missing transfer characteristics, guessing from colorspace");
colorSpace.mTransfer = Some(([&] {
switch (aData->mYUVColorSpace) {
case gfx::YUVColorSpace::Identity:
return VideoTransferCharacteristics::Iec61966_2_1;
case gfx::YUVColorSpace::BT2020:
return VideoTransferCharacteristics::Pq;
case gfx::YUVColorSpace::BT601:
LOGW(
"Warning: Falling back to BT709 when attempting to determine the "
"transfer function of a MacIOSurface");
[[fallthrough]];
case gfx::YUVColorSpace::BT709:
return VideoTransferCharacteristics::Bt709;
}
MOZ_ASSERT_UNREACHABLE("Unexpected color space");
LOGW(
"Warning: Falling back to BT709 due to unexpected color space "
"when attempting to determine the transfer function of a "
"MacIOSurface");
return VideoTransferCharacteristics::Bt709;
})());
}
return colorSpace;
}
#ifdef XP_MACOSX
static VideoColorSpaceInternal GuessColorSpace(const MacIOSurface* aSurface) {
if (!aSurface) {
return {};
}
VideoColorSpaceInternal colorSpace;
colorSpace.mFullRange = Some(aSurface->IsFullRange());
if (Maybe<dom::VideoMatrixCoefficients> m =
ToMatrixCoefficients(aSurface->GetYUVColorSpace())) {
colorSpace.mMatrix = Some(*m);
}
if (Maybe<VideoColorPrimaries> p = ToPrimaries(aSurface->mColorPrimaries)) {
colorSpace.mPrimaries = Some(*p);
}
// Make an educated guess based on the coefficients.
if (aSurface->GetYUVColorSpace() == gfx::YUVColorSpace::Identity) {
colorSpace.mTransfer = Some(VideoTransferCharacteristics::Iec61966_2_1);
} else if (aSurface->GetYUVColorSpace() == gfx::YUVColorSpace::BT709) {
colorSpace.mTransfer = Some(VideoTransferCharacteristics::Bt709);
} else if (aSurface->GetYUVColorSpace() == gfx::YUVColorSpace::BT2020) {
colorSpace.mTransfer = Some(VideoTransferCharacteristics::Pq);
} else {
LOGW(
"Warning: Falling back to BT709 when attempting to determine the "
"transfer function of a MacIOSurface");
colorSpace.mTransfer = Some(VideoTransferCharacteristics::Bt709);
}
return colorSpace;
}
#endif
#ifdef MOZ_WAYLAND
// TODO: Set DMABufSurface::IsFullRange() to const so aSurface can be const.
static VideoColorSpaceInternal GuessColorSpace(DMABufSurface* aSurface) {
if (!aSurface) {
return {};
}
VideoColorSpaceInternal colorSpace;
colorSpace.mFullRange = Some(aSurface->IsFullRange());
if (Maybe<dom::VideoMatrixCoefficients> m =
ToMatrixCoefficients(aSurface->GetYUVColorSpace())) {
colorSpace.mMatrix = Some(*m);
}
// No other color space information.
return colorSpace;
}
#endif
static VideoColorSpaceInternal GuessColorSpace(layers::Image* aImage) {
if (aImage) {
if (layers::PlanarYCbCrImage* image = aImage->AsPlanarYCbCrImage()) {
return GuessColorSpace(image->GetData());
}
if (layers::NVImage* image = aImage->AsNVImage()) {
return GuessColorSpace(image->GetData());
}
if (layers::GPUVideoImage* image = aImage->AsGPUVideoImage()) {
VideoColorSpaceInternal colorSpace;
colorSpace.mFullRange =
Some(image->GetColorRange() != gfx::ColorRange::LIMITED);
colorSpace.mMatrix = ToMatrixCoefficients(image->GetYUVColorSpace());
colorSpace.mPrimaries = ToPrimaries(image->GetColorPrimaries());
colorSpace.mTransfer =
ToTransferCharacteristics(image->GetTransferFunction());
// In some circumstances, e.g. on Linux software decoding when using
// VPXDecoder and RDD, the primaries aren't set correctly. Make a good
// guess based on the other params. Fixing this is tracked in
if (!colorSpace.mPrimaries) {
if (colorSpace.mMatrix.isSome()) {
switch (colorSpace.mMatrix.value()) {
case VideoMatrixCoefficients::Rgb:
case VideoMatrixCoefficients::Bt709:
colorSpace.mPrimaries = Some(VideoColorPrimaries::Bt709);
break;
case VideoMatrixCoefficients::Bt470bg:
case VideoMatrixCoefficients::Smpte170m:
colorSpace.mPrimaries = Some(VideoColorPrimaries::Bt470bg);
break;
case VideoMatrixCoefficients::Bt2020_ncl:
colorSpace.mPrimaries = Some(VideoColorPrimaries::Bt2020);
break;
};
}
}
return colorSpace;
}
#ifdef XP_MACOSX
// TODO: Make sure VideoFrame can interpret its internal data in different
// formats.
if (layers::MacIOSurfaceImage* image = aImage->AsMacIOSurfaceImage()) {
return GuessColorSpace(image->GetSurface());
}
#endif
#ifdef MOZ_WAYLAND
// TODO: Make sure VideoFrame can interpret its internal data in different
// formats.
if (layers::DMABUFSurfaceImage* image = aImage->AsDMABUFSurfaceImage()) {
return GuessColorSpace(image->GetSurface());
}
#endif
}
LOGW("Failed to get color space from layers::Image");
return {};
}
static Result<gfx::IntSize, nsresult> AdjustDisplaySize(
const uint32_t aDisplayAspectWidth, const uint32_t aDisplayAspectHeight,
const gfx::IntSize& aDisplaySize) {
if (aDisplayAspectHeight == 0) {
return Err(NS_ERROR_ILLEGAL_VALUE);
}
const double aspectRatio =
static_cast<double>(aDisplayAspectWidth) / aDisplayAspectHeight;
double w = aDisplaySize.width;
double h = aDisplaySize.height;
if (aspectRatio >= w / h) {
// Adjust w to match the aspect ratio
w = aspectRatio * h;
} else {
// Adjust h to match the aspect ratio
h = w / aspectRatio;
}
w = std::round(w);
h = std::round(h);
constexpr double MAX = static_cast<double>(
std::numeric_limits<decltype(gfx::IntSize::width)>::max());
if (w > MAX || h > MAX || w < 1.0 || h < 1.0) {
return Err(NS_ERROR_ILLEGAL_VALUE);
}
return gfx::IntSize(static_cast<decltype(gfx::IntSize::width)>(w),
static_cast<decltype(gfx::IntSize::height)>(h));
}
static RefPtr<VideoFrame> CreateVideoFrame(
nsIGlobalObject* aGlobalObject, const VideoData* aData, int64_t aTimestamp,
uint64_t aDuration, const Maybe<uint32_t> aDisplayAspectWidth,
const Maybe<uint32_t> aDisplayAspectHeight,
const VideoColorSpaceInternal& aColorSpace) {
MOZ_ASSERT(aGlobalObject);
MOZ_ASSERT(aData);
MOZ_ASSERT((!!aDisplayAspectWidth) == (!!aDisplayAspectHeight));
Maybe<VideoPixelFormat> format = GuessPixelFormat(aData->mImage.get());
gfx::IntSize displaySize = aData->mDisplay;
if (aDisplayAspectWidth && aDisplayAspectHeight) {
auto r = AdjustDisplaySize(*aDisplayAspectWidth, *aDisplayAspectHeight,
displaySize);
if (r.isOk()) {
displaySize = r.unwrap();
}
}
return MakeRefPtr<VideoFrame>(
aGlobalObject, aData->mImage, format, aData->mImage->GetSize(),
aData->mImage->GetPictureRect(), displaySize, Some(aDuration), aTimestamp,
aColorSpace.ToColorSpaceInit());
}
/* static */
bool VideoDecoderTraits::IsSupported(
const VideoDecoderConfigInternal& aConfig) {
return CanDecode(aConfig);
}
/* static */
Result<UniquePtr<TrackInfo>, nsresult> VideoDecoderTraits::CreateTrackInfo(
const VideoDecoderConfigInternal& aConfig) {
LOG("Create a VideoInfo from %s config", aConfig.ToString().get());
nsTArray<UniquePtr<TrackInfo>> tracks = GetTracksInfo(aConfig);
if (tracks.Length() != 1 || tracks[0]->GetType() != TrackInfo::kVideoTrack) {
LOGE("Failed to get TrackInfo");
return Err(NS_ERROR_INVALID_ARG);
}
UniquePtr<TrackInfo> track(std::move(tracks[0]));
VideoInfo* vi = track->GetAsVideoInfo();
if (!vi) {
LOGE("Failed to get VideoInfo");
return Err(NS_ERROR_INVALID_ARG);
}
constexpr uint32_t MAX = static_cast<uint32_t>(
std::numeric_limits<decltype(gfx::IntSize::width)>::max());
if (aConfig.mCodedHeight.isSome()) {
if (aConfig.mCodedHeight.value() > MAX) {
LOGE("codedHeight overflows");
return Err(NS_ERROR_INVALID_ARG);
}
vi->mImage.height = static_cast<decltype(gfx::IntSize::height)>(
aConfig.mCodedHeight.value());
}
if (aConfig.mCodedWidth.isSome()) {
if (aConfig.mCodedWidth.value() > MAX) {
LOGE("codedWidth overflows");
return Err(NS_ERROR_INVALID_ARG);
}
vi->mImage.width =
static_cast<decltype(gfx::IntSize::width)>(aConfig.mCodedWidth.value());
}
if (aConfig.mDisplayAspectHeight.isSome()) {
if (aConfig.mDisplayAspectHeight.value() > MAX) {
LOGE("displayAspectHeight overflows");
return Err(NS_ERROR_INVALID_ARG);
}
vi->mDisplay.height = static_cast<decltype(gfx::IntSize::height)>(
aConfig.mDisplayAspectHeight.value());
}
if (aConfig.mDisplayAspectWidth.isSome()) {
if (aConfig.mDisplayAspectWidth.value() > MAX) {
LOGE("displayAspectWidth overflows");
return Err(NS_ERROR_INVALID_ARG);
}
vi->mDisplay.width = static_cast<decltype(gfx::IntSize::width)>(
aConfig.mDisplayAspectWidth.value());
}
if (aConfig.mColorSpace.isSome()) {
const VideoColorSpaceInternal& colorSpace(aConfig.mColorSpace.value());
if (colorSpace.mFullRange.isSome()) {
vi->mColorRange = ToColorRange(colorSpace.mFullRange.value());
}
if (colorSpace.mMatrix.isSome()) {
vi->mColorSpace.emplace(ToColorSpace(colorSpace.mMatrix.value()));
}
// Some decoders get their primaries and transfer function from the codec
// string, and it's already set here. This is the case for VP9 decoders.
if (colorSpace.mPrimaries.isSome()) {
auto primaries = ToPrimaries(colorSpace.mPrimaries.value());
if (vi->mColorPrimaries.isSome()) {
if (vi->mColorPrimaries.value() != primaries) {
LOG("Conflict between decoder config and codec string, keeping codec "
"string primaries of %d",
static_cast<int>(primaries));
}
} else {
vi->mColorPrimaries.emplace(primaries);
}
}
if (colorSpace.mTransfer.isSome()) {
auto primaries = ToTransferFunction(colorSpace.mTransfer.value());
if (vi->mTransferFunction.isSome()) {
if (vi->mTransferFunction.value() != primaries) {
LOG("Conflict between decoder config and codec string, keeping codec "
"string transfer function of %d",
static_cast<int>(vi->mTransferFunction.value()));
}
} else {
vi->mTransferFunction.emplace(
ToTransferFunction(colorSpace.mTransfer.value()));
}
}
}
if (aConfig.mDescription) {
if (!aConfig.mDescription->IsEmpty()) {
LOG("The given config has %zu bytes of description data",
aConfig.mDescription->Length());
if (vi->mExtraData) {
LOGW("The default extra data is overwritten");
}
vi->mExtraData = aConfig.mDescription;
}
// TODO: Make this utility and replace the similar one in MP4Demuxer.cpp.
if (vi->mExtraData && !vi->mExtraData->IsEmpty() &&
IsH264CodecString(aConfig.mCodec)) {
SPSData spsdata;
if (H264::DecodeSPSFromExtraData(vi->mExtraData.get(), spsdata) &&
spsdata.pic_width > 0 && spsdata.pic_height > 0 &&
H264::EnsureSPSIsSane(spsdata)) {
LOG("H264 sps data - pic size: %d x %d, display size: %d x %d",
spsdata.pic_width, spsdata.pic_height, spsdata.display_width,
spsdata.display_height);
if (spsdata.pic_width > MAX || spsdata.pic_height > MAX ||
spsdata.display_width > MAX || spsdata.display_height > MAX) {
LOGE("H264 width or height in sps data overflows");
return Err(NS_ERROR_INVALID_ARG);
}
vi->mImage.width =
static_cast<decltype(gfx::IntSize::width)>(spsdata.pic_width);
vi->mImage.height =
static_cast<decltype(gfx::IntSize::height)>(spsdata.pic_height);
vi->mDisplay.width =
static_cast<decltype(gfx::IntSize::width)>(spsdata.display_width);
vi->mDisplay.height =
static_cast<decltype(gfx::IntSize::height)>(spsdata.display_height);
}
}
} else {
vi->mExtraData = new MediaByteBuffer();
}
LOG("Created a VideoInfo for decoder - %s",
NS_ConvertUTF16toUTF8(vi->ToString()).get());
return track;
}
/* static */
bool VideoDecoderTraits::Validate(const VideoDecoderConfig& aConfig,
nsCString& aErrorMessage) {
Maybe<nsString> codec = ParseCodecString(aConfig.mCodec);
if (!codec || codec->IsEmpty()) {
aErrorMessage.AssignLiteral("Invalid codec string");
LOGE("%s", aErrorMessage.get());
return false;
}
if (aConfig.mCodedWidth.WasPassed() != aConfig.mCodedHeight.WasPassed()) {
aErrorMessage.AppendPrintf(
"Missing coded %s",
aConfig.mCodedWidth.WasPassed() ? "height" : "width");
LOGE("%s", aErrorMessage.get());
return false;
}
if (aConfig.mCodedWidth.WasPassed() &&
(aConfig.mCodedWidth.Value() == 0 || aConfig.mCodedHeight.Value() == 0)) {
aErrorMessage.AssignLiteral("codedWidth and/or codedHeight can't be zero");
LOGE("%s", aErrorMessage.get());
return false;
}
if (aConfig.mDisplayAspectWidth.WasPassed() !=
aConfig.mDisplayAspectHeight.WasPassed()) {
aErrorMessage.AppendPrintf(
"Missing display aspect %s",
aConfig.mDisplayAspectWidth.WasPassed() ? "height" : "width");
LOGE("%s", aErrorMessage.get());
return false;
}
if (aConfig.mDisplayAspectWidth.WasPassed() &&
(aConfig.mDisplayAspectWidth.Value() == 0 ||
aConfig.mDisplayAspectHeight.Value() == 0)) {
aErrorMessage.AssignLiteral(
"display aspect width and height cannot be zero");
LOGE("%s", aErrorMessage.get());
return false;
}
bool detached =
aConfig.mDescription.WasPassed() &&
(aConfig.mDescription.Value().IsArrayBuffer()
? JS::ArrayBuffer::fromObject(
aConfig.mDescription.Value().GetAsArrayBuffer().Obj())
.isDetached()
: JS::ArrayBufferView::fromObject(
aConfig.mDescription.Value().GetAsArrayBufferView().Obj())
.isDetached());
if (detached) {
aErrorMessage.AssignLiteral("description is detached.");
LOGE("%s", aErrorMessage.get());
return false;
}
return true;
}
/* static */
RefPtr<VideoDecoderConfigInternal> VideoDecoderTraits::CreateConfigInternal(
const VideoDecoderConfig& aConfig) {
return VideoDecoderConfigInternal::Create(aConfig);
}
/* static */
bool VideoDecoderTraits::IsKeyChunk(const EncodedVideoChunk& aInput) {
return aInput.Type() == EncodedVideoChunkType::Key;
}
/* static */
UniquePtr<EncodedVideoChunkData> VideoDecoderTraits::CreateInputInternal(
const EncodedVideoChunk& aInput) {
return aInput.Clone();
}
/*
* Below are VideoDecoder implementation
*/
VideoDecoder::VideoDecoder(nsIGlobalObject* aParent,
RefPtr<WebCodecsErrorCallback>&& aErrorCallback,
RefPtr<VideoFrameOutputCallback>&& aOutputCallback)
: DecoderTemplate(aParent, std::move(aErrorCallback),
std::move(aOutputCallback)) {
MOZ_ASSERT(mErrorCallback);
MOZ_ASSERT(mOutputCallback);
LOG("VideoDecoder %p ctor", this);
}
VideoDecoder::~VideoDecoder() { LOG("VideoDecoder %p dtor", this); }
JSObject* VideoDecoder::WrapObject(JSContext* aCx,
JS::Handle<JSObject*> aGivenProto) {
AssertIsOnOwningThread();
return VideoDecoder_Binding::Wrap(aCx, this, aGivenProto);
}
/* static */
already_AddRefed<VideoDecoder> VideoDecoder::Constructor(
const GlobalObject& aGlobal, const VideoDecoderInit& aInit,
ErrorResult& aRv) {
nsCOMPtr<nsIGlobalObject> global = do_QueryInterface(aGlobal.GetAsSupports());
if (!global) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
return MakeAndAddRef<VideoDecoder>(
global.get(), RefPtr<WebCodecsErrorCallback>(aInit.mError),
RefPtr<VideoFrameOutputCallback>(aInit.mOutput));
}
/* static */
already_AddRefed<Promise> VideoDecoder::IsConfigSupported(
const GlobalObject& aGlobal, const VideoDecoderConfig& aConfig,
ErrorResult& aRv) {
LOG("VideoDecoder::IsConfigSupported, config: %s",
NS_ConvertUTF16toUTF8(aConfig.mCodec).get());
nsCOMPtr<nsIGlobalObject> global = do_QueryInterface(aGlobal.GetAsSupports());
if (!global) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
RefPtr<Promise> p = Promise::Create(global.get(), aRv);
if (NS_WARN_IF(aRv.Failed())) {
return p.forget();
}
nsCString errorMessage;
if (!VideoDecoderTraits::Validate(aConfig, errorMessage)) {
p->MaybeRejectWithTypeError(nsPrintfCString(
"IsConfigSupported: config is invalid: %s", errorMessage.get()));
return p.forget();
}
RootedDictionary<VideoDecoderConfig> config(aGlobal.Context());
auto r = CloneConfiguration(config, aGlobal.Context(), aConfig, aRv);
if (r.isErr()) {
// This can only be an OOM: all members to clone are known to be valid
// because this is check by ::Validate above.
MOZ_ASSERT(r.inspectErr() == NS_ERROR_OUT_OF_MEMORY &&
aRv.ErrorCodeIs(NS_ERROR_OUT_OF_MEMORY));
return p.forget();
}
bool canDecode = CanDecode(config);
RootedDictionary<VideoDecoderSupport> s(aGlobal.Context());
s.mConfig.Construct(std::move(config));
s.mSupported.Construct(canDecode);
p->MaybeResolve(s);
return p.forget();
}
already_AddRefed<MediaRawData> VideoDecoder::InputDataToMediaRawData(
UniquePtr<EncodedVideoChunkData>&& aData, TrackInfo& aInfo,
const VideoDecoderConfigInternal& aConfig) {
AssertIsOnOwningThread();
MOZ_ASSERT(aInfo.GetAsVideoInfo());
if (!aData) {
LOGE("No data for conversion");
return nullptr;
}
RefPtr<MediaRawData> sample = aData->TakeData();
if (!sample) {
LOGE("Take no data for conversion");
return nullptr;
}
// aExtraData is either provided by Configure() or a default one created for
// the decoder creation. If it's created for decoder creation only, we don't
// set it to sample.
if (aConfig.mDescription && aInfo.GetAsVideoInfo()->mExtraData) {
sample->mExtraData = aInfo.GetAsVideoInfo()->mExtraData;
}
LOGV(
"EncodedVideoChunkData %p converted to %zu-byte MediaRawData - time: "
"%" PRIi64 "us, timecode: %" PRIi64 "us, duration: %" PRIi64
"us, key-frame: %s, has extra data: %s",
aData.get(), sample->Size(), sample->mTime.ToMicroseconds(),
sample->mTimecode.ToMicroseconds(), sample->mDuration.ToMicroseconds(),
sample->mKeyframe ? "yes" : "no", sample->mExtraData ? "yes" : "no");
return sample.forget();
}
nsTArray<RefPtr<VideoFrame>> VideoDecoder::DecodedDataToOutputType(
nsIGlobalObject* aGlobalObject, const nsTArray<RefPtr<MediaData>>&& aData,
const VideoDecoderConfigInternal& aConfig) {
AssertIsOnOwningThread();
nsTArray<RefPtr<VideoFrame>> frames;
for (const RefPtr<MediaData>& data : aData) {
MOZ_RELEASE_ASSERT(data->mType == MediaData::Type::VIDEO_DATA);
RefPtr<const VideoData> d(data->As<const VideoData>());
VideoColorSpaceInternal colorSpace;
// Determine which color space to use: prefer the color space as configured
// at the decoder level, if it has one, otherwise look at the underlying
// image and make a guess.
if (aConfig.mColorSpace.isSome() &&
aConfig.mColorSpace->mPrimaries.isSome() &&
aConfig.mColorSpace->mTransfer.isSome() &&
aConfig.mColorSpace->mMatrix.isSome()) {
colorSpace = aConfig.mColorSpace.value();
} else {
colorSpace = GuessColorSpace(d->mImage.get());
}
frames.AppendElement(CreateVideoFrame(
aGlobalObject, d.get(), d->mTime.ToMicroseconds(),
static_cast<uint64_t>(d->mDuration.ToMicroseconds()),
aConfig.mDisplayAspectWidth, aConfig.mDisplayAspectHeight, colorSpace));
}
return frames;
}
#undef LOG
#undef LOGW
#undef LOGE
#undef LOGV
#undef LOG_INTERNAL
} // namespace mozilla::dom