/* -*- 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 "ImageContainer.h"
#include "MediaDecoderReader.h"
#include "MediaInfo.h"
#include "mozilla/CheckedInt.h"
#include "mozilla/mozalloc.h" // for operator new, and new (fallible)
#include "mozilla/RefPtr.h"
#include "mozilla/TaskQueue.h"
#include "mp4_demuxer/AnnexB.h"
#include "mp4_demuxer/H264.h"
#include "MP4Decoder.h"
#include "nsAutoPtr.h"
#include "nsRect.h"
#include "PlatformDecoderModule.h"
#include "ReorderQueue.h"
#include "TimeUnits.h"
#include "VideoUtils.h"
namespace mozilla {
// Decoder that uses a passed in object's Create function to create blank
// MediaData objects.
template<class BlankMediaDataCreator>
class BlankMediaDataDecoder : public MediaDataDecoder {
public:
BlankMediaDataDecoder(BlankMediaDataCreator* aCreator,
const CreateDecoderParams& aParams)
: mCreator(aCreator)
, mCallback(aParams.mCallback)
, mMaxRefFrames(aParams.mConfig.GetType() == TrackInfo::kVideoTrack &&
MP4Decoder::IsH264(aParams.mConfig.mMimeType)
? mp4_demuxer::AnnexB::HasSPS(aParams.VideoConfig().mExtraData)
? mp4_demuxer::H264::ComputeMaxRefFrames(aParams.VideoConfig().mExtraData)
: 16
: 0)
, mType(aParams.mConfig.GetType())
{
}
RefPtr<InitPromise> Init() override {
return InitPromise::CreateAndResolve(mType, __func__);
}
void Shutdown() override {}
void Input(MediaRawData* aSample) override
{
RefPtr<MediaData> data =
mCreator->Create(media::TimeUnit::FromMicroseconds(aSample->mTime),
media::TimeUnit::FromMicroseconds(aSample->mDuration),
aSample->mOffset);
OutputFrame(data);
}
void Flush() override
{
mReorderQueue.Clear();
}
void Drain() override
{
while (!mReorderQueue.IsEmpty()) {
mCallback->Output(mReorderQueue.Pop().get());
}
mCallback->DrainComplete();
}
const char* GetDescriptionName() const override
{
return "blank media data decoder";
}
private:
void OutputFrame(MediaData* aData)
{
if (!aData) {
mCallback->Error(MediaResult(NS_ERROR_OUT_OF_MEMORY, __func__));
return;
}
// Frames come out in DTS order but we need to output them in PTS order.
mReorderQueue.Push(aData);
while (mReorderQueue.Length() > mMaxRefFrames) {
mCallback->Output(mReorderQueue.Pop().get());
}
mCallback->InputExhausted();
}
private:
nsAutoPtr<BlankMediaDataCreator> mCreator;
MediaDataDecoderCallback* mCallback;
const uint32_t mMaxRefFrames;
ReorderQueue mReorderQueue;
TrackInfo::TrackType mType;
};
class BlankVideoDataCreator {
public:
BlankVideoDataCreator(uint32_t aFrameWidth,
uint32_t aFrameHeight,
layers::ImageContainer* aImageContainer)
: mFrameWidth(aFrameWidth)
, mFrameHeight(aFrameHeight)
, mImageContainer(aImageContainer)
{
mInfo.mDisplay = nsIntSize(mFrameWidth, mFrameHeight);
mPicture = gfx::IntRect(0, 0, mFrameWidth, mFrameHeight);
}
already_AddRefed<MediaData>
Create(const media::TimeUnit& aDTS, const media::TimeUnit& aDuration, int64_t aOffsetInStream)
{
// Create a fake YUV buffer in a 420 format. That is, an 8bpp Y plane,
// with a U and V plane that are half the size of the Y plane, i.e 8 bit,
// 2x2 subsampled.
const int sizeY = mFrameWidth * mFrameHeight;
const int sizeCbCr = ((mFrameWidth + 1) / 2) * ((mFrameHeight + 1) / 2);
auto frame = MakeUnique<uint8_t[]>(sizeY + sizeCbCr);
VideoData::YCbCrBuffer buffer;
// Y plane.
buffer.mPlanes[0].mData = frame.get();
buffer.mPlanes[0].mStride = mFrameWidth;
buffer.mPlanes[0].mHeight = mFrameHeight;
buffer.mPlanes[0].mWidth = mFrameWidth;
buffer.mPlanes[0].mOffset = 0;
buffer.mPlanes[0].mSkip = 0;
// Cb plane.
buffer.mPlanes[1].mData = frame.get() + sizeY;
buffer.mPlanes[1].mStride = mFrameWidth / 2;
buffer.mPlanes[1].mHeight = mFrameHeight / 2;
buffer.mPlanes[1].mWidth = mFrameWidth / 2;
buffer.mPlanes[1].mOffset = 0;
buffer.mPlanes[1].mSkip = 0;
// Cr plane.
buffer.mPlanes[2].mData = frame.get() + sizeY;
buffer.mPlanes[2].mStride = mFrameWidth / 2;
buffer.mPlanes[2].mHeight = mFrameHeight / 2;
buffer.mPlanes[2].mWidth = mFrameWidth / 2;
buffer.mPlanes[2].mOffset = 0;
buffer.mPlanes[2].mSkip = 0;
// Set to color white.
memset(buffer.mPlanes[0].mData, 255, sizeY);
memset(buffer.mPlanes[1].mData, 128, sizeCbCr);
return VideoData::CreateAndCopyData(mInfo,
mImageContainer,
aOffsetInStream,
aDTS.ToMicroseconds(),
aDuration.ToMicroseconds(),
buffer,
true,
aDTS.ToMicroseconds(),
mPicture);
}
private:
VideoInfo mInfo;
gfx::IntRect mPicture;
uint32_t mFrameWidth;
uint32_t mFrameHeight;
RefPtr<layers::ImageContainer> mImageContainer;
};
class BlankAudioDataCreator {
public:
BlankAudioDataCreator(uint32_t aChannelCount, uint32_t aSampleRate)
: mFrameSum(0), mChannelCount(aChannelCount), mSampleRate(aSampleRate)
{
}
MediaData* Create(const media::TimeUnit& aDTS,
const media::TimeUnit& aDuration,
int64_t aOffsetInStream)
{
// Convert duration to frames. We add 1 to duration to account for
// rounding errors, so we get a consistent tone.
CheckedInt64 frames =
UsecsToFrames(aDuration.ToMicroseconds()+1, mSampleRate);
if (!frames.isValid() ||
!mChannelCount ||
!mSampleRate ||
frames.value() > (UINT32_MAX / mChannelCount)) {
return nullptr;
}
AlignedAudioBuffer samples(frames.value() * mChannelCount);
if (!samples) {
return nullptr;
}
// Fill the sound buffer with an A4 tone.
static const float pi = 3.14159265f;
static const float noteHz = 440.0f;
for (int i = 0; i < frames.value(); i++) {
float f = sin(2 * pi * noteHz * mFrameSum / mSampleRate);
for (unsigned c = 0; c < mChannelCount; c++) {
samples[i * mChannelCount + c] = AudioDataValue(f);
}
mFrameSum++;
}
return new AudioData(aOffsetInStream,
aDTS.ToMicroseconds(),
aDuration.ToMicroseconds(),
uint32_t(frames.value()),
Move(samples),
mChannelCount,
mSampleRate);
}
private:
int64_t mFrameSum;
uint32_t mChannelCount;
uint32_t mSampleRate;
};
class BlankDecoderModule : public PlatformDecoderModule {
public:
// Decode thread.
already_AddRefed<MediaDataDecoder>
CreateVideoDecoder(const CreateDecoderParams& aParams) override {
const VideoInfo& config = aParams.VideoConfig();
BlankVideoDataCreator* creator = new BlankVideoDataCreator(
config.mDisplay.width, config.mDisplay.height, aParams.mImageContainer);
RefPtr<MediaDataDecoder> decoder =
new BlankMediaDataDecoder<BlankVideoDataCreator>(creator, aParams);
return decoder.forget();
}
// Decode thread.
already_AddRefed<MediaDataDecoder>
CreateAudioDecoder(const CreateDecoderParams& aParams) override {
const AudioInfo& config = aParams.AudioConfig();
BlankAudioDataCreator* creator = new BlankAudioDataCreator(
config.mChannels, config.mRate);
RefPtr<MediaDataDecoder> decoder =
new BlankMediaDataDecoder<BlankAudioDataCreator>(creator, aParams);
return decoder.forget();
}
bool
SupportsMimeType(const nsACString& aMimeType,
DecoderDoctorDiagnostics* aDiagnostics) const override
{
return true;
}
ConversionRequired
DecoderNeedsConversion(const TrackInfo& aConfig) const override
{
if (aConfig.IsVideo() && MP4Decoder::IsH264(aConfig.mMimeType)) {
return ConversionRequired::kNeedAVCC;
} else {
return ConversionRequired::kNeedNone;
}
}
};
already_AddRefed<PlatformDecoderModule> CreateBlankDecoderModule()
{
RefPtr<PlatformDecoderModule> pdm = new BlankDecoderModule();
return pdm.forget();
}
} // namespace mozilla