cc/raster/gpu_raster_buffer_provider.cc - chromium/src - Git at Google

 // Copyright 2014 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "cc/raster/gpu_raster_buffer_provider.h"

 #include <stdint.h>

 #include <algorithm>

 #include "base/macros.h"
 #include "base/memory/ptr_util.h"
 #include "base/metrics/histogram_macros.h"
 #include "base/trace_event/trace_event.h"
 #include "cc/base/histograms.h"
 #include "cc/playback/image_hijack_canvas.h"
 #include "cc/playback/raster_source.h"
 #include "cc/raster/scoped_gpu_raster.h"
 #include "cc/resources/resource.h"
 #include "gpu/command_buffer/client/gles2_interface.h"
 #include "third_party/skia/include/core/SkMultiPictureDraw.h"
 #include "third_party/skia/include/core/SkPictureRecorder.h"
 #include "third_party/skia/include/core/SkSurface.h"
 #include "third_party/skia/include/gpu/GrContext.h"

 namespace cc {
 namespace {

 static sk_sp<SkPicture> PlaybackToPicture(
     const RasterSource* raster_source,
     bool resource_has_previous_content,
     const gfx::Size& resource_size,
     const gfx::Rect& raster_full_rect,
     const gfx::Rect& raster_dirty_rect,
     float scale,
     const RasterSource::PlaybackSettings& playback_settings) {
   // GPU raster doesn't do low res tiles, so should always include images.
   DCHECK(!playback_settings.skip_images);

   gfx::Rect playback_rect = raster_full_rect;
   if (resource_has_previous_content) {
     playback_rect.Intersect(raster_dirty_rect);
   }
   DCHECK(!playback_rect.IsEmpty())
       << "Why are we rastering a tile that's not dirty?";

   // Log a histogram of the percentage of pixels that were saved due to
   // partial raster.
   const char* client_name = GetClientNameForMetrics();
   float full_rect_size = raster_full_rect.size().GetArea();
   if (full_rect_size > 0 && client_name) {
     float fraction_partial_rastered =
         static_cast<float>(playback_rect.size().GetArea()) / full_rect_size;
     float fraction_saved = 1.0f - fraction_partial_rastered;
     UMA_HISTOGRAM_PERCENTAGE(
         base::StringPrintf("Renderer4.%s.PartialRasterPercentageSaved.Gpu",
                            client_name),
         100.0f * fraction_saved);
   }

   // Play back raster_source into temp SkPicture.
   SkPictureRecorder recorder;
   sk_sp<SkCanvas> canvas = sk_ref_sp(
       recorder.beginRecording(resource_size.width(), resource_size.height()));
   canvas->save();

   // The GPU image decode controller assumes that Skia is done with an image
   // when playback is complete. However, in this case, where we play back to a
   // picture, we don't actually finish with the images until the picture is
   // rasterized later. This can cause lifetime issues in the GPU image decode
   // controller. To avoid this, we disable the image hijack canvas (and image
   // decode controller) for this playback step, instead enabling it for the
   // later picture rasterization.
   RasterSource::PlaybackSettings settings = playback_settings;
   settings.use_image_hijack_canvas = false;
   raster_source->PlaybackToCanvas(canvas.get(), raster_full_rect, playback_rect,
                                   scale, settings);
   canvas->restore();
   return recorder.finishRecordingAsPicture();
 }

 static void RasterizePicture(SkPicture* picture,
                              ContextProvider* context_provider,
                              ResourceProvider::ScopedWriteLockGL* resource_lock,
                              bool async_worker_context_enabled,
                              bool use_distance_field_text,
                              bool can_use_lcd_text,
                              int msaa_sample_count,
                              ImageDecodeController* image_decode_controller,
                              bool use_image_hijack_canvas) {
   ScopedGpuRaster gpu_raster(context_provider);

   ResourceProvider::ScopedSkSurfaceProvider scoped_surface(
       context_provider, resource_lock, async_worker_context_enabled,
       use_distance_field_text, can_use_lcd_text, msaa_sample_count);
   SkSurface* sk_surface = scoped_surface.sk_surface();
   // Allocating an SkSurface will fail after a lost context.  Pretend we
   // rasterized, as the contents of the resource don't matter anymore.
   if (!sk_surface)
     return;

   // As we did not use the image hijack canvas during the initial playback to
   // |picture| (see PlaybackToPicture), we must enable it here if requested.
   SkCanvas* canvas = sk_surface->getCanvas();
   std::unique_ptr<ImageHijackCanvas> hijack_canvas;
   if (use_image_hijack_canvas) {
     DCHECK(image_decode_controller);
     const SkImageInfo& info = canvas->imageInfo();
     hijack_canvas.reset(new ImageHijackCanvas(info.width(), info.height(),
                                               image_decode_controller));
     SkIRect raster_bounds;
     canvas->getClipDeviceBounds(&raster_bounds);
     hijack_canvas->clipRect(SkRect::MakeFromIRect(raster_bounds));
     hijack_canvas->setMatrix(canvas->getTotalMatrix());
     hijack_canvas->addCanvas(canvas);

     // Replace canvas with our ImageHijackCanvas which is wrapping it.
     canvas = hijack_canvas.get();
   }

   SkMultiPictureDraw multi_picture_draw;
   multi_picture_draw.add(canvas, picture);
   multi_picture_draw.draw(false);
 }

 }  // namespace

 GpuRasterBufferProvider::RasterBufferImpl::RasterBufferImpl(
     GpuRasterBufferProvider* client,
     ResourceProvider* resource_provider,
     ResourceId resource_id,
     bool async_worker_context_enabled,
     bool resource_has_previous_content)
     : client_(client),
       lock_(resource_provider, resource_id, async_worker_context_enabled),
       resource_has_previous_content_(resource_has_previous_content) {
   client_->pending_raster_buffers_.insert(this);
 }

 GpuRasterBufferProvider::RasterBufferImpl::~RasterBufferImpl() {
   client_->pending_raster_buffers_.erase(this);
 }

 void GpuRasterBufferProvider::RasterBufferImpl::Playback(
     const RasterSource* raster_source,
     const gfx::Rect& raster_full_rect,
     const gfx::Rect& raster_dirty_rect,
     uint64_t new_content_id,
     float scale,
     const RasterSource::PlaybackSettings& playback_settings) {
   TRACE_EVENT0("cc", "GpuRasterBuffer::Playback");
   client_->PlaybackOnWorkerThread(&lock_, sync_token_,
                                   resource_has_previous_content_, raster_source,
                                   raster_full_rect, raster_dirty_rect,
                                   new_content_id, scale, playback_settings);
 }

 GpuRasterBufferProvider::GpuRasterBufferProvider(
     ContextProvider* compositor_context_provider,
     ContextProvider* worker_context_provider,
     ResourceProvider* resource_provider,
     bool use_distance_field_text,
     int gpu_rasterization_msaa_sample_count,
     bool async_worker_context_enabled)
     : compositor_context_provider_(compositor_context_provider),
       worker_context_provider_(worker_context_provider),
       resource_provider_(resource_provider),
       use_distance_field_text_(use_distance_field_text),
       msaa_sample_count_(gpu_rasterization_msaa_sample_count),
       async_worker_context_enabled_(async_worker_context_enabled) {
   DCHECK(compositor_context_provider);
   DCHECK(worker_context_provider);
 }

 GpuRasterBufferProvider::~GpuRasterBufferProvider() {
   DCHECK(pending_raster_buffers_.empty());
 }

 std::unique_ptr<RasterBuffer> GpuRasterBufferProvider::AcquireBufferForRaster(
     const Resource* resource,
     uint64_t resource_content_id,
     uint64_t previous_content_id) {
   bool resource_has_previous_content =
       resource_content_id && resource_content_id == previous_content_id;
   return base::WrapUnique(new RasterBufferImpl(
       this, resource_provider_, resource->id(), async_worker_context_enabled_,
       resource_has_previous_content));
 }

 void GpuRasterBufferProvider::ReleaseBufferForRaster(
     std::unique_ptr<RasterBuffer> buffer) {
   // Nothing to do here. RasterBufferImpl destructor cleans up after itself.
 }

 void GpuRasterBufferProvider::OrderingBarrier() {
   TRACE_EVENT0("cc", "GpuRasterBufferProvider::OrderingBarrier");

   gpu::gles2::GLES2Interface* gl = compositor_context_provider_->ContextGL();
   if (async_worker_context_enabled_) {
     GLuint64 fence = gl->InsertFenceSyncCHROMIUM();
     gl->OrderingBarrierCHROMIUM();

     gpu::SyncToken sync_token;
     gl->GenUnverifiedSyncTokenCHROMIUM(fence, sync_token.GetData());

     DCHECK(sync_token.HasData() ||
            gl->GetGraphicsResetStatusKHR() != GL_NO_ERROR);

     for (RasterBufferImpl* buffer : pending_raster_buffers_)
       buffer->set_sync_token(sync_token);
   } else {
     gl->OrderingBarrierCHROMIUM();
   }
   pending_raster_buffers_.clear();
 }

 ResourceFormat GpuRasterBufferProvider::GetResourceFormat(
     bool must_support_alpha) const {
   return resource_provider_->best_render_buffer_format();
 }

 bool GpuRasterBufferProvider::IsResourceSwizzleRequired(
     bool must_support_alpha) const {
   // This doesn't require a swizzle because we rasterize to the correct format.
   return false;
 }

 bool GpuRasterBufferProvider::CanPartialRasterIntoProvidedResource() const {
   // Partial raster doesn't support MSAA, as the MSAA resolve is unaware of clip
   // rects.
   // TODO(crbug.com/629683): See if we can work around this limitation.
   return msaa_sample_count_ == 0;
 }

 void GpuRasterBufferProvider::Shutdown() {
   pending_raster_buffers_.clear();
 }

 void GpuRasterBufferProvider::PlaybackOnWorkerThread(
     ResourceProvider::ScopedWriteLockGL* resource_lock,
     const gpu::SyncToken& sync_token,
     bool resource_has_previous_content,
     const RasterSource* raster_source,
     const gfx::Rect& raster_full_rect,
     const gfx::Rect& raster_dirty_rect,
     uint64_t new_content_id,
     float scale,
     const RasterSource::PlaybackSettings& playback_settings) {
   ContextProvider::ScopedContextLock scoped_context(worker_context_provider_);
   gpu::gles2::GLES2Interface* gl = scoped_context.ContextGL();
   DCHECK(gl);

   if (async_worker_context_enabled_) {
     // Early out if sync token is invalid. This happens if the compositor
     // context was lost before ScheduleTasks was called.
     if (!sync_token.HasData())
       return;
     // Synchronize with compositor.
     gl->WaitSyncTokenCHROMIUM(sync_token.GetConstData());
   }

   sk_sp<SkPicture> picture = PlaybackToPicture(
       raster_source, resource_has_previous_content, resource_lock->size(),
       raster_full_rect, raster_dirty_rect, scale, playback_settings);

   // Turn on distance fields for layers that have ever animated.
   bool use_distance_field_text =
       use_distance_field_text_ ||
       raster_source->ShouldAttemptToUseDistanceFieldText();

   RasterizePicture(picture.get(), worker_context_provider_, resource_lock,
                    async_worker_context_enabled_, use_distance_field_text,
                    raster_source->CanUseLCDText(), msaa_sample_count_,
                    raster_source->image_decode_controller(),
                    playback_settings.use_image_hijack_canvas);

   const uint64_t fence_sync = gl->InsertFenceSyncCHROMIUM();

   // Barrier to sync worker context output to cc context.
   gl->OrderingBarrierCHROMIUM();

   // Generate sync token after the barrier for cross context synchronization.
   gpu::SyncToken resource_sync_token;
   gl->GenUnverifiedSyncTokenCHROMIUM(fence_sync, resource_sync_token.GetData());
   resource_lock->set_sync_token(resource_sync_token);
   resource_lock->set_synchronized(!async_worker_context_enabled_);
 }

 }  // namespace cc
	// Copyright 2014 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "cc/raster/gpu_raster_buffer_provider.h"

	#include <stdint.h>

	#include <algorithm>

	#include "base/macros.h"
	#include "base/memory/ptr_util.h"
	#include "base/metrics/histogram_macros.h"
	#include "base/trace_event/trace_event.h"
	#include "cc/base/histograms.h"
	#include "cc/playback/image_hijack_canvas.h"
	#include "cc/playback/raster_source.h"
	#include "cc/raster/scoped_gpu_raster.h"
	#include "cc/resources/resource.h"
	#include "gpu/command_buffer/client/gles2_interface.h"
	#include "third_party/skia/include/core/SkMultiPictureDraw.h"
	#include "third_party/skia/include/core/SkPictureRecorder.h"
	#include "third_party/skia/include/core/SkSurface.h"
	#include "third_party/skia/include/gpu/GrContext.h"

	namespace cc {
	namespace {

	static sk_sp<SkPicture> PlaybackToPicture(
	const RasterSource* raster_source,
	bool resource_has_previous_content,
	const gfx::Size& resource_size,
	const gfx::Rect& raster_full_rect,
	const gfx::Rect& raster_dirty_rect,
	float scale,
	const RasterSource::PlaybackSettings& playback_settings) {
	// GPU raster doesn't do low res tiles, so should always include images.
	DCHECK(!playback_settings.skip_images);

	gfx::Rect playback_rect = raster_full_rect;
	if (resource_has_previous_content) {
	playback_rect.Intersect(raster_dirty_rect);
	}
	DCHECK(!playback_rect.IsEmpty())
	<< "Why are we rastering a tile that's not dirty?";

	// Log a histogram of the percentage of pixels that were saved due to
	// partial raster.
	const char* client_name = GetClientNameForMetrics();
	float full_rect_size = raster_full_rect.size().GetArea();
	if (full_rect_size > 0 && client_name) {
	float fraction_partial_rastered =
	static_cast<float>(playback_rect.size().GetArea()) / full_rect_size;
	float fraction_saved = 1.0f - fraction_partial_rastered;
	UMA_HISTOGRAM_PERCENTAGE(
	base::StringPrintf("Renderer4.%s.PartialRasterPercentageSaved.Gpu",
	client_name),
	100.0f * fraction_saved);
	}

	// Play back raster_source into temp SkPicture.
	SkPictureRecorder recorder;
	sk_sp<SkCanvas> canvas = sk_ref_sp(
	recorder.beginRecording(resource_size.width(), resource_size.height()));
	canvas->save();

	// The GPU image decode controller assumes that Skia is done with an image
	// when playback is complete. However, in this case, where we play back to a
	// picture, we don't actually finish with the images until the picture is
	// rasterized later. This can cause lifetime issues in the GPU image decode
	// controller. To avoid this, we disable the image hijack canvas (and image
	// decode controller) for this playback step, instead enabling it for the
	// later picture rasterization.
	RasterSource::PlaybackSettings settings = playback_settings;
	settings.use_image_hijack_canvas = false;
	raster_source->PlaybackToCanvas(canvas.get(), raster_full_rect, playback_rect,
	scale, settings);
	canvas->restore();
	return recorder.finishRecordingAsPicture();
	}

	static void RasterizePicture(SkPicture* picture,
	ContextProvider* context_provider,
	ResourceProvider::ScopedWriteLockGL* resource_lock,
	bool async_worker_context_enabled,
	bool use_distance_field_text,
	bool can_use_lcd_text,
	int msaa_sample_count,
	ImageDecodeController* image_decode_controller,
	bool use_image_hijack_canvas) {
	ScopedGpuRaster gpu_raster(context_provider);

	ResourceProvider::ScopedSkSurfaceProvider scoped_surface(
	context_provider, resource_lock, async_worker_context_enabled,
	use_distance_field_text, can_use_lcd_text, msaa_sample_count);
	SkSurface* sk_surface = scoped_surface.sk_surface();
	// Allocating an SkSurface will fail after a lost context. Pretend we
	// rasterized, as the contents of the resource don't matter anymore.
	if (!sk_surface)
	return;

	// As we did not use the image hijack canvas during the initial playback to
	// \|picture\| (see PlaybackToPicture), we must enable it here if requested.
	SkCanvas* canvas = sk_surface->getCanvas();
	std::unique_ptr<ImageHijackCanvas> hijack_canvas;
	if (use_image_hijack_canvas) {
	DCHECK(image_decode_controller);
	const SkImageInfo& info = canvas->imageInfo();
	hijack_canvas.reset(new ImageHijackCanvas(info.width(), info.height(),
	image_decode_controller));
	SkIRect raster_bounds;
	canvas->getClipDeviceBounds(&raster_bounds);
	hijack_canvas->clipRect(SkRect::MakeFromIRect(raster_bounds));
	hijack_canvas->setMatrix(canvas->getTotalMatrix());
	hijack_canvas->addCanvas(canvas);

	// Replace canvas with our ImageHijackCanvas which is wrapping it.
	canvas = hijack_canvas.get();
	}

	SkMultiPictureDraw multi_picture_draw;
	multi_picture_draw.add(canvas, picture);
	multi_picture_draw.draw(false);
	}

	} // namespace

	GpuRasterBufferProvider::RasterBufferImpl::RasterBufferImpl(
	GpuRasterBufferProvider* client,
	ResourceProvider* resource_provider,
	ResourceId resource_id,
	bool async_worker_context_enabled,
	bool resource_has_previous_content)
	: client_(client),
	lock_(resource_provider, resource_id, async_worker_context_enabled),
	resource_has_previous_content_(resource_has_previous_content) {
	client_->pending_raster_buffers_.insert(this);
	}

	GpuRasterBufferProvider::RasterBufferImpl::~RasterBufferImpl() {
	client_->pending_raster_buffers_.erase(this);
	}

	void GpuRasterBufferProvider::RasterBufferImpl::Playback(
	const RasterSource* raster_source,
	const gfx::Rect& raster_full_rect,
	const gfx::Rect& raster_dirty_rect,
	uint64_t new_content_id,
	float scale,
	const RasterSource::PlaybackSettings& playback_settings) {
	TRACE_EVENT0("cc", "GpuRasterBuffer::Playback");
	client_->PlaybackOnWorkerThread(&lock_, sync_token_,
	resource_has_previous_content_, raster_source,
	raster_full_rect, raster_dirty_rect,
	new_content_id, scale, playback_settings);
	}

	GpuRasterBufferProvider::GpuRasterBufferProvider(
	ContextProvider* compositor_context_provider,
	ContextProvider* worker_context_provider,
	ResourceProvider* resource_provider,
	bool use_distance_field_text,
	int gpu_rasterization_msaa_sample_count,
	bool async_worker_context_enabled)
	: compositor_context_provider_(compositor_context_provider),
	worker_context_provider_(worker_context_provider),
	resource_provider_(resource_provider),
	use_distance_field_text_(use_distance_field_text),
	msaa_sample_count_(gpu_rasterization_msaa_sample_count),
	async_worker_context_enabled_(async_worker_context_enabled) {
	DCHECK(compositor_context_provider);
	DCHECK(worker_context_provider);
	}

	GpuRasterBufferProvider::~GpuRasterBufferProvider() {
	DCHECK(pending_raster_buffers_.empty());
	}

	std::unique_ptr<RasterBuffer> GpuRasterBufferProvider::AcquireBufferForRaster(
	const Resource* resource,
	uint64_t resource_content_id,
	uint64_t previous_content_id) {
	bool resource_has_previous_content =
	resource_content_id && resource_content_id == previous_content_id;
	return base::WrapUnique(new RasterBufferImpl(
	this, resource_provider_, resource->id(), async_worker_context_enabled_,
	resource_has_previous_content));
	}

	void GpuRasterBufferProvider::ReleaseBufferForRaster(
	std::unique_ptr<RasterBuffer> buffer) {
	// Nothing to do here. RasterBufferImpl destructor cleans up after itself.
	}

	void GpuRasterBufferProvider::OrderingBarrier() {
	TRACE_EVENT0("cc", "GpuRasterBufferProvider::OrderingBarrier");

	gpu::gles2::GLES2Interface* gl = compositor_context_provider_->ContextGL();
	if (async_worker_context_enabled_) {
	GLuint64 fence = gl->InsertFenceSyncCHROMIUM();
	gl->OrderingBarrierCHROMIUM();

	gpu::SyncToken sync_token;
	gl->GenUnverifiedSyncTokenCHROMIUM(fence, sync_token.GetData());

	DCHECK(sync_token.HasData() \|\|
	gl->GetGraphicsResetStatusKHR() != GL_NO_ERROR);

	for (RasterBufferImpl* buffer : pending_raster_buffers_)
	buffer->set_sync_token(sync_token);
	} else {
	gl->OrderingBarrierCHROMIUM();
	}
	pending_raster_buffers_.clear();
	}

	ResourceFormat GpuRasterBufferProvider::GetResourceFormat(
	bool must_support_alpha) const {
	return resource_provider_->best_render_buffer_format();
	}

	bool GpuRasterBufferProvider::IsResourceSwizzleRequired(
	bool must_support_alpha) const {
	// This doesn't require a swizzle because we rasterize to the correct format.
	return false;
	}

	bool GpuRasterBufferProvider::CanPartialRasterIntoProvidedResource() const {
	// Partial raster doesn't support MSAA, as the MSAA resolve is unaware of clip
	// rects.
	// TODO(crbug.com/629683): See if we can work around this limitation.
	return msaa_sample_count_ == 0;
	}

	void GpuRasterBufferProvider::Shutdown() {
	pending_raster_buffers_.clear();
	}

	void GpuRasterBufferProvider::PlaybackOnWorkerThread(
	ResourceProvider::ScopedWriteLockGL* resource_lock,
	const gpu::SyncToken& sync_token,
	bool resource_has_previous_content,
	const RasterSource* raster_source,
	const gfx::Rect& raster_full_rect,
	const gfx::Rect& raster_dirty_rect,
	uint64_t new_content_id,
	float scale,
	const RasterSource::PlaybackSettings& playback_settings) {
	ContextProvider::ScopedContextLock scoped_context(worker_context_provider_);
	gpu::gles2::GLES2Interface* gl = scoped_context.ContextGL();
	DCHECK(gl);

	if (async_worker_context_enabled_) {
	// Early out if sync token is invalid. This happens if the compositor
	// context was lost before ScheduleTasks was called.
	if (!sync_token.HasData())
	return;
	// Synchronize with compositor.
	gl->WaitSyncTokenCHROMIUM(sync_token.GetConstData());
	}

	sk_sp<SkPicture> picture = PlaybackToPicture(
	raster_source, resource_has_previous_content, resource_lock->size(),
	raster_full_rect, raster_dirty_rect, scale, playback_settings);

	// Turn on distance fields for layers that have ever animated.
	bool use_distance_field_text =
	use_distance_field_text_ \|\|
	raster_source->ShouldAttemptToUseDistanceFieldText();

	RasterizePicture(picture.get(), worker_context_provider_, resource_lock,
	async_worker_context_enabled_, use_distance_field_text,
	raster_source->CanUseLCDText(), msaa_sample_count_,
	raster_source->image_decode_controller(),
	playback_settings.use_image_hijack_canvas);

	const uint64_t fence_sync = gl->InsertFenceSyncCHROMIUM();

	// Barrier to sync worker context output to cc context.
	gl->OrderingBarrierCHROMIUM();

	// Generate sync token after the barrier for cross context synchronization.
	gpu::SyncToken resource_sync_token;
	gl->GenUnverifiedSyncTokenCHROMIUM(fence_sync, resource_sync_token.GetData());
	resource_lock->set_sync_token(resource_sync_token);
	resource_lock->set_synchronized(!async_worker_context_enabled_);
	}

	} // namespace cc