gecko-dev/dom/media/gtest/TestVideoTrackEncoder.cpp
Chia-hung Tai e759836a63 Bug 1201363 - MediaStreamVideoSink for MediaRecorder case. r=jesup
Add MediaStreamVideoRecorderSink into MediaEncorder. In this patch, I still keep use duration to pass to TrackEncoders. Don't want to make this bug too big and out of control. We can file a new bug to change TrackEncoders use TimeStamp only.

MozReview-Commit-ID: KGftzulZynj

--HG--
extra : transplant_source : %E9%22B%90%D6%CF%08%12X%D1%E2%17%90%99%B2%91%24B%EA%1D
2016-06-15 16:48:44 +01:00

303 lines
8.2 KiB
C++

/* 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 "gtest/gtest.h"
#include <algorithm>
#include "mozilla/ArrayUtils.h"
#include "VP8TrackEncoder.h"
#include "ImageContainer.h"
#include "MediaStreamGraph.h"
#include "MediaStreamListener.h"
#include "WebMWriter.h" // TODO: it's weird to include muxer header to get the class definition of VP8 METADATA
using ::testing::TestWithParam;
using ::testing::Values;
using namespace mozilla::layers;
using namespace mozilla;
// A helper object to generate of different YUV planes.
class YUVBufferGenerator {
public:
YUVBufferGenerator() {}
void Init(const mozilla::gfx::IntSize &aSize)
{
mImageSize = aSize;
int yPlaneLen = aSize.width * aSize.height;
int cbcrPlaneLen = (yPlaneLen + 1) / 2;
int frameLen = yPlaneLen + cbcrPlaneLen;
// Generate source buffer.
mSourceBuffer.SetLength(frameLen);
// Fill Y plane.
memset(mSourceBuffer.Elements(), 0x10, yPlaneLen);
// Fill Cb/Cr planes.
memset(mSourceBuffer.Elements() + yPlaneLen, 0x80, cbcrPlaneLen);
}
mozilla::gfx::IntSize GetSize() const
{
return mImageSize;
}
void Generate(nsTArray<RefPtr<Image> > &aImages)
{
aImages.AppendElement(CreateI420Image());
aImages.AppendElement(CreateNV12Image());
aImages.AppendElement(CreateNV21Image());
}
private:
Image *CreateI420Image()
{
PlanarYCbCrImage *image = new RecyclingPlanarYCbCrImage(new BufferRecycleBin());
PlanarYCbCrData data;
data.mPicSize = mImageSize;
const uint32_t yPlaneSize = mImageSize.width * mImageSize.height;
const uint32_t halfWidth = (mImageSize.width + 1) / 2;
const uint32_t halfHeight = (mImageSize.height + 1) / 2;
const uint32_t uvPlaneSize = halfWidth * halfHeight;
// Y plane.
uint8_t *y = mSourceBuffer.Elements();
data.mYChannel = y;
data.mYSize.width = mImageSize.width;
data.mYSize.height = mImageSize.height;
data.mYStride = mImageSize.width;
data.mYSkip = 0;
// Cr plane.
uint8_t *cr = y + yPlaneSize + uvPlaneSize;
data.mCrChannel = cr;
data.mCrSkip = 0;
// Cb plane
uint8_t *cb = y + yPlaneSize;
data.mCbChannel = cb;
data.mCbSkip = 0;
// CrCb plane vectors.
data.mCbCrStride = halfWidth;
data.mCbCrSize.width = halfWidth;
data.mCbCrSize.height = halfHeight;
image->CopyData(data);
return image;
}
Image *CreateNV12Image()
{
PlanarYCbCrImage *image = new RecyclingPlanarYCbCrImage(new BufferRecycleBin());
PlanarYCbCrData data;
data.mPicSize = mImageSize;
const uint32_t yPlaneSize = mImageSize.width * mImageSize.height;
const uint32_t halfWidth = (mImageSize.width + 1) / 2;
const uint32_t halfHeight = (mImageSize.height + 1) / 2;
// Y plane.
uint8_t *y = mSourceBuffer.Elements();
data.mYChannel = y;
data.mYSize.width = mImageSize.width;
data.mYSize.height = mImageSize.height;
data.mYStride = mImageSize.width;
data.mYSkip = 0;
// Cr plane.
uint8_t *cr = y + yPlaneSize;
data.mCrChannel = cr;
data.mCrSkip = 1;
// Cb plane
uint8_t *cb = y + yPlaneSize + 1;
data.mCbChannel = cb;
data.mCbSkip = 1;
// 4:2:0.
data.mCbCrStride = mImageSize.width;
data.mCbCrSize.width = halfWidth;
data.mCbCrSize.height = halfHeight;
image->CopyData(data);
return image;
}
Image *CreateNV21Image()
{
PlanarYCbCrImage *image = new RecyclingPlanarYCbCrImage(new BufferRecycleBin());
PlanarYCbCrData data;
data.mPicSize = mImageSize;
const uint32_t yPlaneSize = mImageSize.width * mImageSize.height;
const uint32_t halfWidth = (mImageSize.width + 1) / 2;
const uint32_t halfHeight = (mImageSize.height + 1) / 2;
// Y plane.
uint8_t *y = mSourceBuffer.Elements();
data.mYChannel = y;
data.mYSize.width = mImageSize.width;
data.mYSize.height = mImageSize.height;
data.mYStride = mImageSize.width;
data.mYSkip = 0;
// Cr plane.
uint8_t *cr = y + yPlaneSize + 1;
data.mCrChannel = cr;
data.mCrSkip = 1;
// Cb plane
uint8_t *cb = y + yPlaneSize;
data.mCbChannel = cb;
data.mCbSkip = 1;
// 4:2:0.
data.mCbCrStride = mImageSize.width;
data.mCbCrSize.width = halfWidth;
data.mCbCrSize.height = halfHeight;
image->CopyData(data);
return image;
}
private:
mozilla::gfx::IntSize mImageSize;
nsTArray<uint8_t> mSourceBuffer;
};
struct InitParam {
bool mShouldSucceed; // This parameter should cause success or fail result
int mWidth; // frame width
int mHeight; // frame height
};
class TestVP8TrackEncoder: public VP8TrackEncoder
{
public:
explicit TestVP8TrackEncoder(TrackRate aTrackRate = 90000)
: VP8TrackEncoder(aTrackRate) {}
::testing::AssertionResult TestInit(const InitParam &aParam)
{
nsresult result = Init(aParam.mWidth, aParam.mHeight, aParam.mWidth, aParam.mHeight);
if (((NS_FAILED(result) && aParam.mShouldSucceed)) || (NS_SUCCEEDED(result) && !aParam.mShouldSucceed))
{
return ::testing::AssertionFailure()
<< " width = " << aParam.mWidth
<< " height = " << aParam.mHeight;
}
else
{
return ::testing::AssertionSuccess();
}
}
};
// Init test
TEST(VP8VideoTrackEncoder, Initialization)
{
InitParam params[] = {
// Failure cases.
{ false, 0, 0}, // Height/ width should be larger than 1.
{ false, 0, 1}, // Height/ width should be larger than 1.
{ false, 1, 0}, // Height/ width should be larger than 1.
// Success cases
{ true, 640, 480}, // Standard VGA
{ true, 800, 480}, // Standard WVGA
{ true, 960, 540}, // Standard qHD
{ true, 1280, 720} // Standard HD
};
for (size_t i = 0; i < ArrayLength(params); i++)
{
TestVP8TrackEncoder encoder;
EXPECT_TRUE(encoder.TestInit(params[i]));
}
}
// Get MetaData test
TEST(VP8VideoTrackEncoder, FetchMetaData)
{
InitParam params[] = {
// Success cases
{ true, 640, 480}, // Standard VGA
{ true, 800, 480}, // Standard WVGA
{ true, 960, 540}, // Standard qHD
{ true, 1280, 720} // Standard HD
};
for (size_t i = 0; i < ArrayLength(params); i++)
{
TestVP8TrackEncoder encoder;
EXPECT_TRUE(encoder.TestInit(params[i]));
RefPtr<TrackMetadataBase> meta = encoder.GetMetadata();
RefPtr<VP8Metadata> vp8Meta(static_cast<VP8Metadata*>(meta.get()));
// METADATA should be depend on how to initiate encoder.
EXPECT_TRUE(vp8Meta->mWidth == params[i].mWidth);
EXPECT_TRUE(vp8Meta->mHeight == params[i].mHeight);
}
}
// Encode test
TEST(VP8VideoTrackEncoder, FrameEncode)
{
// Initiate VP8 encoder
TestVP8TrackEncoder encoder;
InitParam param = {true, 640, 480};
encoder.TestInit(param);
// Create YUV images as source.
nsTArray<RefPtr<Image>> images;
YUVBufferGenerator generator;
generator.Init(mozilla::gfx::IntSize(640, 480));
generator.Generate(images);
// Put generated YUV frame into video segment.
// Duration of each frame is 1 second.
VideoSegment segment;
for (nsTArray<RefPtr<Image>>::size_type i = 0; i < images.Length(); i++)
{
RefPtr<Image> image = images[i];
segment.AppendFrame(image.forget(),
mozilla::StreamTime(90000),
generator.GetSize(),
PRINCIPAL_HANDLE_NONE);
}
// track change notification.
encoder.SetCurrentFrames(segment);
// Pull Encoded Data back from encoder.
EncodedFrameContainer container;
EXPECT_TRUE(NS_SUCCEEDED(encoder.GetEncodedTrack(container)));
}
// EOS test
TEST(VP8VideoTrackEncoder, EncodeComplete)
{
// Initiate VP8 encoder
TestVP8TrackEncoder encoder;
InitParam param = {true, 640, 480};
encoder.TestInit(param);
// track end notification.
VideoSegment segment;
encoder.NotifyQueuedTrackChanges(nullptr, 0, 0, TrackEventCommand::TRACK_EVENT_ENDED, segment);
// Pull Encoded Data back from encoder. Since we have sent
// EOS to encoder, encoder.GetEncodedTrack should return
// NS_OK immidiately.
EncodedFrameContainer container;
EXPECT_TRUE(NS_SUCCEEDED(encoder.GetEncodedTrack(container)));
}