sky/engine/platform/graphics/ImageFrameGenerator.cpp - external/github.com/flutter/engine - Git at Google

 /*
  * Copyright (C) 2012 Google Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE COMPUTER, INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE COMPUTER, INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */


 #include "sky/engine/platform/graphics/ImageFrameGenerator.h"

 #include "platform/image-decoders/ImageDecoder.h"
 #include "sky/engine/platform/SharedBuffer.h"
 #include "sky/engine/platform/TraceEvent.h"
 #include "sky/engine/platform/graphics/ImageDecodingStore.h"

 #include "skia/ext/image_operations.h"
 #include "third_party/skia/include/core/SkMallocPixelRef.h"

 namespace blink {

 // Creates a SkPixelRef such that the memory for pixels is given by an external body.
 // This is used to write directly to the memory given by Skia during decoding.
 class ImageFrameGenerator::ExternalMemoryAllocator : public SkBitmap::Allocator {
 public:
     ExternalMemoryAllocator(const SkImageInfo& info, void* pixels, size_t rowBytes)
         : m_info(info)
         , m_pixels(pixels)
         , m_rowBytes(rowBytes)
     {
     }

     virtual bool allocPixelRef(SkBitmap* dst, SkColorTable* ctable) override
     {
         const SkImageInfo& info = dst->info();
         if (kUnknown_SkColorType == info.colorType())
             return false;

         if (info != m_info || m_rowBytes != dst->rowBytes())
             return false;

         if (!dst->installPixels(m_info, m_pixels, m_rowBytes))
             return false;
         dst->lockPixels();
         return true;
     }

 private:
     SkImageInfo m_info;
     void* m_pixels;
     size_t m_rowBytes;
 };

 ImageFrameGenerator::ImageFrameGenerator(const SkISize& fullSize, PassRefPtr<SharedBuffer> data, bool allDataReceived, bool isMultiFrame)
     : m_fullSize(fullSize)
     , m_isMultiFrame(isMultiFrame)
     , m_decodeFailedAndEmpty(false)
     , m_decodeCount(0)
 {
     setData(data.get(), allDataReceived);
 }

 ImageFrameGenerator::~ImageFrameGenerator()
 {
     ImageDecodingStore::instance()->removeCacheIndexedByGenerator(this);
 }

 void ImageFrameGenerator::setData(PassRefPtr<SharedBuffer> data, bool allDataReceived)
 {
     m_data.setData(data.get(), allDataReceived);
 }

 void ImageFrameGenerator::copyData(RefPtr<SharedBuffer>* data, bool* allDataReceived)
 {
     SharedBuffer* buffer = 0;
     m_data.data(&buffer, allDataReceived);
     if (buffer)
         *data = buffer->copy();
 }

 bool ImageFrameGenerator::decodeAndScale(const SkImageInfo& info, size_t index, void* pixels, size_t rowBytes)
 {
     // This method is called to populate a discardable memory owned by Skia.

     // Prevents concurrent decode or scale operations on the same image data.
     MutexLocker lock(m_decodeMutex);

     // This implementation does not support scaling so check the requested size.
     SkISize scaledSize = SkISize::Make(info.fWidth, info.fHeight);
     ASSERT(m_fullSize == scaledSize);

     if (m_decodeFailedAndEmpty)
         return false;

     TRACE_EVENT2("blink", "ImageFrameGenerator::decodeAndScale", "generator", this, "decodeCount", m_decodeCount);

     m_externalAllocator = adoptPtr(new ExternalMemoryAllocator(info, pixels, rowBytes));

     SkBitmap bitmap = tryToResumeDecode(scaledSize, index);
     if (bitmap.isNull())
         return false;

     // Don't keep the allocator because it contains a pointer to memory
     // that we do not own.
     m_externalAllocator.clear();

     ASSERT(bitmap.width() == scaledSize.width());
     ASSERT(bitmap.height() == scaledSize.height());

     bool result = true;
     // Check to see if decoder has written directly to the memory provided
     // by Skia. If not make a copy.
     if (bitmap.getPixels() != pixels)
         result = bitmap.copyPixelsTo(pixels, rowBytes * info.fHeight, rowBytes);
     return result;
 }

 bool ImageFrameGenerator::decodeToYUV(void* planes[3], size_t rowBytes[3])
 {
     // This method is called to populate a discardable memory owned by Skia.

     // Prevents concurrent decode or scale operations on the same image data.
     MutexLocker lock(m_decodeMutex);

     if (m_decodeFailedAndEmpty)
         return false;

     TRACE_EVENT2("blink", "ImageFrameGenerator::decodeToYUV", "generator", this, "decodeCount", static_cast<int>(m_decodeCount));

     if (!planes || !planes[0] || !planes[1] || !planes[2]
         || !rowBytes || !rowBytes[0] || !rowBytes[1] || !rowBytes[2]) {
         return false;
     }

     SharedBuffer* data = 0;
     bool allDataReceived = false;
     m_data.data(&data, &allDataReceived);

     // FIXME: YUV decoding does not currently support progressive decoding.
     if (!allDataReceived)
         return false;

     OwnPtr<ImageDecoder> decoder = ImageDecoder::create(*data, ImageSource::AlphaPremultiplied, ImageSource::GammaAndColorProfileApplied);
     if (!decoder)
         return false;

     decoder->setData(data, allDataReceived);

     OwnPtr<ImagePlanes> imagePlanes = adoptPtr(new ImagePlanes(planes, rowBytes));
     decoder->setImagePlanes(imagePlanes.release());
     bool yuvDecoded = decoder->decodeToYUV();
     if (yuvDecoded)
         setHasAlpha(0, false); // YUV is always opaque
     return yuvDecoded;
 }

 SkBitmap ImageFrameGenerator::tryToResumeDecode(const SkISize& scaledSize, size_t index)
 {
     TRACE_EVENT1("blink", "ImageFrameGenerator::tryToResumeDecodeAndScale", "index", static_cast<int>(index));

     ImageDecoder* decoder = 0;
     const bool resumeDecoding = ImageDecodingStore::instance()->lockDecoder(this, m_fullSize, &decoder);
     ASSERT(!resumeDecoding || decoder);

     SkBitmap fullSizeImage;
     bool complete = decode(index, &decoder, &fullSizeImage);

     if (!decoder)
         return SkBitmap();

     // If we are not resuming decoding that means the decoder is freshly
     // created and we have ownership. If we are resuming decoding then
     // the decoder is owned by ImageDecodingStore.
     OwnPtr<ImageDecoder> decoderContainer;
     if (!resumeDecoding)
         decoderContainer = adoptPtr(decoder);

     if (fullSizeImage.isNull()) {
         // If decode has failed and resulted an empty image we can save work
         // in the future by returning early.
         m_decodeFailedAndEmpty = !m_isMultiFrame && decoder->failed();

         if (resumeDecoding)
             ImageDecodingStore::instance()->unlockDecoder(this, decoder);
         return SkBitmap();
     }

     // If the image generated is complete then there is no need to keep
     // the decoder. The exception is multi-frame decoder which can generate
     // multiple complete frames.
     const bool removeDecoder = complete && !m_isMultiFrame;

     if (resumeDecoding) {
         if (removeDecoder)
             ImageDecodingStore::instance()->removeDecoder(this, decoder);
         else
             ImageDecodingStore::instance()->unlockDecoder(this, decoder);
     } else if (!removeDecoder) {
         ImageDecodingStore::instance()->insertDecoder(this, decoderContainer.release());
     }
     return fullSizeImage;
 }

 void ImageFrameGenerator::setHasAlpha(size_t index, bool hasAlpha)
 {
     MutexLocker lock(m_alphaMutex);
     if (index >= m_hasAlpha.size()) {
         const size_t oldSize = m_hasAlpha.size();
         m_hasAlpha.resize(index + 1);
         for (size_t i = oldSize; i < m_hasAlpha.size(); ++i)
             m_hasAlpha[i] = true;
     }
     m_hasAlpha[index] = hasAlpha;
 }

 bool ImageFrameGenerator::decode(size_t index, ImageDecoder** decoder, SkBitmap* bitmap)
 {
     TRACE_EVENT2("blink", "ImageFrameGenerator::decode", "width", m_fullSize.width(), "height", m_fullSize.height());

     ASSERT(decoder);
     SharedBuffer* data = 0;
     bool allDataReceived = false;
     bool newDecoder = false;
     m_data.data(&data, &allDataReceived);

     // Try to create an ImageDecoder if we are not given one.
     if (!*decoder) {
         newDecoder = true;
         if (m_imageDecoderFactory)
             *decoder = m_imageDecoderFactory->create().leakPtr();

         if (!*decoder)
             *decoder = ImageDecoder::create(*data, ImageSource::AlphaPremultiplied, ImageSource::GammaAndColorProfileApplied).leakPtr();

         if (!*decoder)
             return false;
     }

     if (!m_isMultiFrame && newDecoder && allDataReceived) {
         // If we're using an external memory allocator that means we're decoding
         // directly into the output memory and we can save one memcpy.
         ASSERT(m_externalAllocator.get());
         (*decoder)->setMemoryAllocator(m_externalAllocator.get());
     }
     (*decoder)->setData(data, allDataReceived);

     ImageFrame* frame = (*decoder)->frameBufferAtIndex(index);
     (*decoder)->setData(0, false); // Unref SharedBuffer from ImageDecoder.
     (*decoder)->clearCacheExceptFrame(index);
     (*decoder)->setMemoryAllocator(0);

     if (!frame || frame->status() == ImageFrame::FrameEmpty)
         return false;

     // A cache object is considered complete if we can decode a complete frame.
     // Or we have received all data. The image might not be fully decoded in
     // the latter case.
     const bool isDecodeComplete = frame->status() == ImageFrame::FrameComplete || allDataReceived;
     SkBitmap fullSizeBitmap = frame->getSkBitmap();
     if (!fullSizeBitmap.isNull())
     {
         ASSERT(fullSizeBitmap.width() == m_fullSize.width() && fullSizeBitmap.height() == m_fullSize.height());
         setHasAlpha(index, !fullSizeBitmap.isOpaque());
     }
     *bitmap = fullSizeBitmap;
     return isDecodeComplete;
 }

 bool ImageFrameGenerator::hasAlpha(size_t index)
 {
     MutexLocker lock(m_alphaMutex);
     if (index < m_hasAlpha.size())
         return m_hasAlpha[index];
     return true;
 }

 bool ImageFrameGenerator::getYUVComponentSizes(SkISize componentSizes[3])
 {
     ASSERT(componentSizes);

     TRACE_EVENT2("webkit", "ImageFrameGenerator::getYUVComponentSizes", "width", m_fullSize.width(), "height", m_fullSize.height());

     SharedBuffer* data = 0;
     bool allDataReceived = false;
     m_data.data(&data, &allDataReceived);

     // FIXME: YUV decoding does not currently support progressive decoding.
     ASSERT(allDataReceived);

     OwnPtr<ImageDecoder> decoder = ImageDecoder::create(*data, ImageSource::AlphaPremultiplied, ImageSource::GammaAndColorProfileApplied);
     if (!decoder)
         return false;

     // Setting a dummy ImagePlanes object signals to the decoder that we want to do YUV decoding.
     decoder->setData(data, allDataReceived);
     OwnPtr<ImagePlanes> dummyImagePlanes = adoptPtr(new ImagePlanes);
     decoder->setImagePlanes(dummyImagePlanes.release());

     // canDecodeToYUV() has to be called AFTER isSizeAvailable(),
     // otherwise the output color space may not be set in the decoder.
     if (!decoder->isSizeAvailable() || !decoder->canDecodeToYUV())
         return false;

     IntSize size = decoder->decodedYUVSize(0);
     componentSizes[0].set(size.width(), size.height());
     size = decoder->decodedYUVSize(1);
     componentSizes[1].set(size.width(), size.height());
     size = decoder->decodedYUVSize(2);
     componentSizes[2].set(size.width(), size.height());
     return true;
 }

 } // namespace blink
	/*
	* Copyright (C) 2012 Google Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE COMPUTER, INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE COMPUTER, INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/


	#include "sky/engine/platform/graphics/ImageFrameGenerator.h"

	#include "platform/image-decoders/ImageDecoder.h"
	#include "sky/engine/platform/SharedBuffer.h"
	#include "sky/engine/platform/TraceEvent.h"
	#include "sky/engine/platform/graphics/ImageDecodingStore.h"

	#include "skia/ext/image_operations.h"
	#include "third_party/skia/include/core/SkMallocPixelRef.h"

	namespace blink {

	// Creates a SkPixelRef such that the memory for pixels is given by an external body.
	// This is used to write directly to the memory given by Skia during decoding.
	class ImageFrameGenerator::ExternalMemoryAllocator : public SkBitmap::Allocator {
	public:
	ExternalMemoryAllocator(const SkImageInfo& info, void* pixels, size_t rowBytes)
	: m_info(info)
	, m_pixels(pixels)
	, m_rowBytes(rowBytes)
	{
	}

	virtual bool allocPixelRef(SkBitmap* dst, SkColorTable* ctable) override
	{
	const SkImageInfo& info = dst->info();
	if (kUnknown_SkColorType == info.colorType())
	return false;

	if (info != m_info \|\| m_rowBytes != dst->rowBytes())
	return false;

	if (!dst->installPixels(m_info, m_pixels, m_rowBytes))
	return false;
	dst->lockPixels();
	return true;
	}

	private:
	SkImageInfo m_info;
	void* m_pixels;
	size_t m_rowBytes;
	};

	ImageFrameGenerator::ImageFrameGenerator(const SkISize& fullSize, PassRefPtr<SharedBuffer> data, bool allDataReceived, bool isMultiFrame)
	: m_fullSize(fullSize)
	, m_isMultiFrame(isMultiFrame)
	, m_decodeFailedAndEmpty(false)
	, m_decodeCount(0)
	{
	setData(data.get(), allDataReceived);
	}

	ImageFrameGenerator::~ImageFrameGenerator()
	{
	ImageDecodingStore::instance()->removeCacheIndexedByGenerator(this);
	}

	void ImageFrameGenerator::setData(PassRefPtr<SharedBuffer> data, bool allDataReceived)
	{
	m_data.setData(data.get(), allDataReceived);
	}

	void ImageFrameGenerator::copyData(RefPtr<SharedBuffer>* data, bool* allDataReceived)
	{
	SharedBuffer* buffer = 0;
	m_data.data(&buffer, allDataReceived);
	if (buffer)
	*data = buffer->copy();
	}

	bool ImageFrameGenerator::decodeAndScale(const SkImageInfo& info, size_t index, void* pixels, size_t rowBytes)
	{
	// This method is called to populate a discardable memory owned by Skia.

	// Prevents concurrent decode or scale operations on the same image data.
	MutexLocker lock(m_decodeMutex);

	// This implementation does not support scaling so check the requested size.
	SkISize scaledSize = SkISize::Make(info.fWidth, info.fHeight);
	ASSERT(m_fullSize == scaledSize);

	if (m_decodeFailedAndEmpty)
	return false;

	TRACE_EVENT2("blink", "ImageFrameGenerator::decodeAndScale", "generator", this, "decodeCount", m_decodeCount);

	m_externalAllocator = adoptPtr(new ExternalMemoryAllocator(info, pixels, rowBytes));

	SkBitmap bitmap = tryToResumeDecode(scaledSize, index);
	if (bitmap.isNull())
	return false;

	// Don't keep the allocator because it contains a pointer to memory
	// that we do not own.
	m_externalAllocator.clear();

	ASSERT(bitmap.width() == scaledSize.width());
	ASSERT(bitmap.height() == scaledSize.height());

	bool result = true;
	// Check to see if decoder has written directly to the memory provided
	// by Skia. If not make a copy.
	if (bitmap.getPixels() != pixels)
	result = bitmap.copyPixelsTo(pixels, rowBytes * info.fHeight, rowBytes);
	return result;
	}

	bool ImageFrameGenerator::decodeToYUV(void* planes[3], size_t rowBytes[3])
	{
	// This method is called to populate a discardable memory owned by Skia.

	// Prevents concurrent decode or scale operations on the same image data.
	MutexLocker lock(m_decodeMutex);

	if (m_decodeFailedAndEmpty)
	return false;

	TRACE_EVENT2("blink", "ImageFrameGenerator::decodeToYUV", "generator", this, "decodeCount", static_cast<int>(m_decodeCount));

	if (!planes \|\| !planes[0] \|\| !planes[1] \|\| !planes[2]
	\|\| !rowBytes \|\| !rowBytes[0] \|\| !rowBytes[1] \|\| !rowBytes[2]) {
	return false;
	}

	SharedBuffer* data = 0;
	bool allDataReceived = false;
	m_data.data(&data, &allDataReceived);

	// FIXME: YUV decoding does not currently support progressive decoding.
	if (!allDataReceived)
	return false;

	OwnPtr<ImageDecoder> decoder = ImageDecoder::create(*data, ImageSource::AlphaPremultiplied, ImageSource::GammaAndColorProfileApplied);
	if (!decoder)
	return false;

	decoder->setData(data, allDataReceived);

	OwnPtr<ImagePlanes> imagePlanes = adoptPtr(new ImagePlanes(planes, rowBytes));
	decoder->setImagePlanes(imagePlanes.release());
	bool yuvDecoded = decoder->decodeToYUV();
	if (yuvDecoded)
	setHasAlpha(0, false); // YUV is always opaque
	return yuvDecoded;
	}

	SkBitmap ImageFrameGenerator::tryToResumeDecode(const SkISize& scaledSize, size_t index)
	{
	TRACE_EVENT1("blink", "ImageFrameGenerator::tryToResumeDecodeAndScale", "index", static_cast<int>(index));

	ImageDecoder* decoder = 0;
	const bool resumeDecoding = ImageDecodingStore::instance()->lockDecoder(this, m_fullSize, &decoder);
	ASSERT(!resumeDecoding \|\| decoder);

	SkBitmap fullSizeImage;
	bool complete = decode(index, &decoder, &fullSizeImage);

	if (!decoder)
	return SkBitmap();

	// If we are not resuming decoding that means the decoder is freshly
	// created and we have ownership. If we are resuming decoding then
	// the decoder is owned by ImageDecodingStore.
	OwnPtr<ImageDecoder> decoderContainer;
	if (!resumeDecoding)
	decoderContainer = adoptPtr(decoder);

	if (fullSizeImage.isNull()) {
	// If decode has failed and resulted an empty image we can save work
	// in the future by returning early.
	m_decodeFailedAndEmpty = !m_isMultiFrame && decoder->failed();

	if (resumeDecoding)
	ImageDecodingStore::instance()->unlockDecoder(this, decoder);
	return SkBitmap();
	}

	// If the image generated is complete then there is no need to keep
	// the decoder. The exception is multi-frame decoder which can generate
	// multiple complete frames.
	const bool removeDecoder = complete && !m_isMultiFrame;

	if (resumeDecoding) {
	if (removeDecoder)
	ImageDecodingStore::instance()->removeDecoder(this, decoder);
	else
	ImageDecodingStore::instance()->unlockDecoder(this, decoder);
	} else if (!removeDecoder) {
	ImageDecodingStore::instance()->insertDecoder(this, decoderContainer.release());
	}
	return fullSizeImage;
	}

	void ImageFrameGenerator::setHasAlpha(size_t index, bool hasAlpha)
	{
	MutexLocker lock(m_alphaMutex);
	if (index >= m_hasAlpha.size()) {
	const size_t oldSize = m_hasAlpha.size();
	m_hasAlpha.resize(index + 1);
	for (size_t i = oldSize; i < m_hasAlpha.size(); ++i)
	m_hasAlpha[i] = true;
	}
	m_hasAlpha[index] = hasAlpha;
	}

	bool ImageFrameGenerator::decode(size_t index, ImageDecoder** decoder, SkBitmap* bitmap)
	{
	TRACE_EVENT2("blink", "ImageFrameGenerator::decode", "width", m_fullSize.width(), "height", m_fullSize.height());

	ASSERT(decoder);
	SharedBuffer* data = 0;
	bool allDataReceived = false;
	bool newDecoder = false;
	m_data.data(&data, &allDataReceived);

	// Try to create an ImageDecoder if we are not given one.
	if (!*decoder) {
	newDecoder = true;
	if (m_imageDecoderFactory)
	*decoder = m_imageDecoderFactory->create().leakPtr();

	if (!*decoder)
	decoder = ImageDecoder::create(data, ImageSource::AlphaPremultiplied, ImageSource::GammaAndColorProfileApplied).leakPtr();

	if (!*decoder)
	return false;
	}

	if (!m_isMultiFrame && newDecoder && allDataReceived) {
	// If we're using an external memory allocator that means we're decoding
	// directly into the output memory and we can save one memcpy.
	ASSERT(m_externalAllocator.get());
	(*decoder)->setMemoryAllocator(m_externalAllocator.get());
	}
	(*decoder)->setData(data, allDataReceived);

	ImageFrame* frame = (*decoder)->frameBufferAtIndex(index);
	(*decoder)->setData(0, false); // Unref SharedBuffer from ImageDecoder.
	(*decoder)->clearCacheExceptFrame(index);
	(*decoder)->setMemoryAllocator(0);

	if (!frame \|\| frame->status() == ImageFrame::FrameEmpty)
	return false;

	// A cache object is considered complete if we can decode a complete frame.
	// Or we have received all data. The image might not be fully decoded in
	// the latter case.
	const bool isDecodeComplete = frame->status() == ImageFrame::FrameComplete \|\| allDataReceived;
	SkBitmap fullSizeBitmap = frame->getSkBitmap();
	if (!fullSizeBitmap.isNull())
	{
	ASSERT(fullSizeBitmap.width() == m_fullSize.width() && fullSizeBitmap.height() == m_fullSize.height());
	setHasAlpha(index, !fullSizeBitmap.isOpaque());
	}
	*bitmap = fullSizeBitmap;
	return isDecodeComplete;
	}

	bool ImageFrameGenerator::hasAlpha(size_t index)
	{
	MutexLocker lock(m_alphaMutex);
	if (index < m_hasAlpha.size())
	return m_hasAlpha[index];
	return true;
	}

	bool ImageFrameGenerator::getYUVComponentSizes(SkISize componentSizes[3])
	{
	ASSERT(componentSizes);

	TRACE_EVENT2("webkit", "ImageFrameGenerator::getYUVComponentSizes", "width", m_fullSize.width(), "height", m_fullSize.height());

	SharedBuffer* data = 0;
	bool allDataReceived = false;
	m_data.data(&data, &allDataReceived);

	// FIXME: YUV decoding does not currently support progressive decoding.
	ASSERT(allDataReceived);

	OwnPtr<ImageDecoder> decoder = ImageDecoder::create(*data, ImageSource::AlphaPremultiplied, ImageSource::GammaAndColorProfileApplied);
	if (!decoder)
	return false;

	// Setting a dummy ImagePlanes object signals to the decoder that we want to do YUV decoding.
	decoder->setData(data, allDataReceived);
	OwnPtr<ImagePlanes> dummyImagePlanes = adoptPtr(new ImagePlanes);
	decoder->setImagePlanes(dummyImagePlanes.release());

	// canDecodeToYUV() has to be called AFTER isSizeAvailable(),
	// otherwise the output color space may not be set in the decoder.
	if (!decoder->isSizeAvailable() \|\| !decoder->canDecodeToYUV())
	return false;

	IntSize size = decoder->decodedYUVSize(0);
	componentSizes[0].set(size.width(), size.height());
	size = decoder->decodedYUVSize(1);
	componentSizes[1].set(size.width(), size.height());
	size = decoder->decodedYUVSize(2);
	componentSizes[2].set(size.width(), size.height());
	return true;
	}

	} // namespace blink