flow/compositor_context.cc - mirrors/engine - Git at Google

 // Copyright 2013 The Flutter 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 "flutter/flow/compositor_context.h"

 #include <optional>
 #include <utility>
 #include "flutter/flow/layers/layer_tree.h"
 #include "third_party/skia/include/core/SkCanvas.h"

 namespace flutter {

 std::optional<SkRect> FrameDamage::ComputeClipRect(
     flutter::LayerTree& layer_tree,
     bool has_raster_cache,
     bool impeller_enabled) {
   if (layer_tree.root_layer()) {
     PaintRegionMap empty_paint_region_map;
     DiffContext context(layer_tree.frame_size(), layer_tree.paint_region_map(),
                         prev_layer_tree_ ? prev_layer_tree_->paint_region_map()
                                          : empty_paint_region_map,
                         has_raster_cache, impeller_enabled);
     context.PushCullRect(SkRect::MakeIWH(layer_tree.frame_size().width(),
                                          layer_tree.frame_size().height()));
     {
       DiffContext::AutoSubtreeRestore subtree(&context);
       const Layer* prev_root_layer = nullptr;
       if (!prev_layer_tree_ ||
           prev_layer_tree_->frame_size() != layer_tree.frame_size()) {
         // If there is no previous layer tree assume the entire frame must be
         // repainted.
         context.MarkSubtreeDirty(SkRect::MakeIWH(
             layer_tree.frame_size().width(), layer_tree.frame_size().height()));
       } else {
         prev_root_layer = prev_layer_tree_->root_layer();
       }
       layer_tree.root_layer()->Diff(&context, prev_root_layer);
     }

     damage_ =
         context.ComputeDamage(additional_damage_, horizontal_clip_alignment_,
                               vertical_clip_alignment_);
     return SkRect::Make(damage_->buffer_damage);
   }
   return std::nullopt;
 }

 CompositorContext::CompositorContext()
     : texture_registry_(std::make_shared<TextureRegistry>()),
       raster_time_(fixed_refresh_rate_updater_),
       ui_time_(fixed_refresh_rate_updater_) {}

 CompositorContext::CompositorContext(Stopwatch::RefreshRateUpdater& updater)
     : texture_registry_(std::make_shared<TextureRegistry>()),
       raster_time_(updater),
       ui_time_(updater) {}

 CompositorContext::~CompositorContext() = default;

 void CompositorContext::BeginFrame(ScopedFrame& frame,
                                    bool enable_instrumentation) {
   if (enable_instrumentation) {
     raster_time_.Start();
   }
 }

 void CompositorContext::EndFrame(ScopedFrame& frame,
                                  bool enable_instrumentation) {
   if (enable_instrumentation) {
     raster_time_.Stop();
   }
 }

 std::unique_ptr<CompositorContext::ScopedFrame> CompositorContext::AcquireFrame(
     GrDirectContext* gr_context,
     DlCanvas* canvas,
     ExternalViewEmbedder* view_embedder,
     const SkMatrix& root_surface_transformation,
     bool instrumentation_enabled,
     bool surface_supports_readback,
     fml::RefPtr<fml::RasterThreadMerger>
         raster_thread_merger,  // NOLINT(performance-unnecessary-value-param)
     impeller::AiksContext* aiks_context) {
   return std::make_unique<ScopedFrame>(
       *this, gr_context, canvas, view_embedder, root_surface_transformation,
       instrumentation_enabled, surface_supports_readback, raster_thread_merger,
       aiks_context);
 }

 CompositorContext::ScopedFrame::ScopedFrame(
     CompositorContext& context,
     GrDirectContext* gr_context,
     DlCanvas* canvas,
     ExternalViewEmbedder* view_embedder,
     const SkMatrix& root_surface_transformation,
     bool instrumentation_enabled,
     bool surface_supports_readback,
     fml::RefPtr<fml::RasterThreadMerger> raster_thread_merger,
     impeller::AiksContext* aiks_context)
     : context_(context),
       gr_context_(gr_context),
       canvas_(canvas),
       aiks_context_(aiks_context),
       view_embedder_(view_embedder),
       root_surface_transformation_(root_surface_transformation),
       instrumentation_enabled_(instrumentation_enabled),
       surface_supports_readback_(surface_supports_readback),
       raster_thread_merger_(std::move(raster_thread_merger)) {
   context_.BeginFrame(*this, instrumentation_enabled_);
 }

 CompositorContext::ScopedFrame::~ScopedFrame() {
   context_.EndFrame(*this, instrumentation_enabled_);
 }

 RasterStatus CompositorContext::ScopedFrame::Raster(
     flutter::LayerTree& layer_tree,
     bool ignore_raster_cache,
     FrameDamage* frame_damage) {
   TRACE_EVENT0("flutter", "CompositorContext::ScopedFrame::Raster");

   std::optional<SkRect> clip_rect;
   if (frame_damage) {
     clip_rect = frame_damage->ComputeClipRect(layer_tree, !ignore_raster_cache,
                                               !gr_context_);

     if (aiks_context_ &&
         !ShouldPerformPartialRepaint(clip_rect, layer_tree.frame_size())) {
       clip_rect = std::nullopt;
       frame_damage->Reset();
     }
   }

   bool root_needs_readback = layer_tree.Preroll(
       *this, ignore_raster_cache, clip_rect ? *clip_rect : kGiantRect);
   bool needs_save_layer = root_needs_readback && !surface_supports_readback();
   PostPrerollResult post_preroll_result = PostPrerollResult::kSuccess;
   if (view_embedder_ && raster_thread_merger_) {
     post_preroll_result =
         view_embedder_->PostPrerollAction(raster_thread_merger_);
   }

   if (post_preroll_result == PostPrerollResult::kResubmitFrame) {
     return RasterStatus::kResubmit;
   }
   if (post_preroll_result == PostPrerollResult::kSkipAndRetryFrame) {
     return RasterStatus::kSkipAndRetry;
   }

   if (aiks_context_) {
     PaintLayerTreeImpeller(layer_tree, clip_rect, ignore_raster_cache);
   } else {
     PaintLayerTreeSkia(layer_tree, clip_rect, needs_save_layer,
                        ignore_raster_cache);
   }
   return RasterStatus::kSuccess;
 }

 void CompositorContext::ScopedFrame::PaintLayerTreeSkia(
     flutter::LayerTree& layer_tree,
     std::optional<SkRect> clip_rect,
     bool needs_save_layer,
     bool ignore_raster_cache) {
   DlAutoCanvasRestore restore(canvas(), clip_rect.has_value());

   if (canvas()) {
     if (clip_rect) {
       canvas()->ClipRect(*clip_rect);
     }

     if (needs_save_layer) {
       TRACE_EVENT0("flutter", "Canvas::saveLayer");
       SkRect bounds = SkRect::Make(layer_tree.frame_size());
       DlPaint paint;
       paint.setBlendMode(DlBlendMode::kSrc);
       canvas()->SaveLayer(&bounds, &paint);
     }
     canvas()->Clear(DlColor::kTransparent());
   }

   // The canvas()->Restore() is taken care of by the DlAutoCanvasRestore
   layer_tree.Paint(*this, ignore_raster_cache);
 }

 void CompositorContext::ScopedFrame::PaintLayerTreeImpeller(
     flutter::LayerTree& layer_tree,
     std::optional<SkRect> clip_rect,
     bool ignore_raster_cache) {
   if (canvas() && clip_rect) {
     canvas()->Translate(-clip_rect->x(), -clip_rect->y());
   }

   layer_tree.Paint(*this, ignore_raster_cache);
 }

 /// @brief The max ratio of pixel width or height to size that is dirty which
 ///        results in a partial repaint.
 ///
 ///        Performing a partial repaint has a small overhead - Impeller needs to
 ///        allocate a fairly large resolve texture for the root pass instead of
 ///        using the drawable texture, and a final blit must be performed. At a
 ///        minimum, if the damage rect is the entire buffer, we must not perform
 ///        a partial repaint. Beyond that, we could only experimentally
 ///        determine what this value should be. From looking at the Flutter
 ///        Gallery, we noticed that there are occassionally small partial
 ///        repaints which shave off trivial numbers of pixels.
 constexpr float kImpellerRepaintRatio = 0.7f;

 bool CompositorContext::ShouldPerformPartialRepaint(
     std::optional<SkRect> damage_rect,
     SkISize layer_tree_size) {
   if (!damage_rect.has_value()) {
     return false;
   }
   if (damage_rect->width() >= layer_tree_size.width() &&
       damage_rect->height() >= layer_tree_size.height()) {
     return false;
   }
   auto rx = damage_rect->width() / layer_tree_size.width();
   auto ry = damage_rect->height() / layer_tree_size.height();
   return rx <= kImpellerRepaintRatio || ry <= kImpellerRepaintRatio;
 }

 void CompositorContext::OnGrContextCreated() {
   texture_registry_->OnGrContextCreated();
   raster_cache_.Clear();
 }

 void CompositorContext::OnGrContextDestroyed() {
   texture_registry_->OnGrContextDestroyed();
   raster_cache_.Clear();
 }

 }  // namespace flutter
	// Copyright 2013 The Flutter 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 "flutter/flow/compositor_context.h"

	#include <optional>
	#include <utility>
	#include "flutter/flow/layers/layer_tree.h"
	#include "third_party/skia/include/core/SkCanvas.h"

	namespace flutter {

	std::optional<SkRect> FrameDamage::ComputeClipRect(
	flutter::LayerTree& layer_tree,
	bool has_raster_cache,
	bool impeller_enabled) {
	if (layer_tree.root_layer()) {
	PaintRegionMap empty_paint_region_map;
	DiffContext context(layer_tree.frame_size(), layer_tree.paint_region_map(),
	prev_layer_tree_ ? prev_layer_tree_->paint_region_map()
	: empty_paint_region_map,
	has_raster_cache, impeller_enabled);
	context.PushCullRect(SkRect::MakeIWH(layer_tree.frame_size().width(),
	layer_tree.frame_size().height()));
	{
	DiffContext::AutoSubtreeRestore subtree(&context);
	const Layer* prev_root_layer = nullptr;
	if (!prev_layer_tree_ \|\|
	prev_layer_tree_->frame_size() != layer_tree.frame_size()) {
	// If there is no previous layer tree assume the entire frame must be
	// repainted.
	context.MarkSubtreeDirty(SkRect::MakeIWH(
	layer_tree.frame_size().width(), layer_tree.frame_size().height()));
	} else {
	prev_root_layer = prev_layer_tree_->root_layer();
	}
	layer_tree.root_layer()->Diff(&context, prev_root_layer);
	}

	damage_ =
	context.ComputeDamage(additional_damage_, horizontal_clip_alignment_,
	vertical_clip_alignment_);
	return SkRect::Make(damage_->buffer_damage);
	}
	return std::nullopt;
	}

	CompositorContext::CompositorContext()
	: texture_registry_(std::make_shared<TextureRegistry>()),
	raster_time_(fixed_refresh_rate_updater_),
	ui_time_(fixed_refresh_rate_updater_) {}

	CompositorContext::CompositorContext(Stopwatch::RefreshRateUpdater& updater)
	: texture_registry_(std::make_shared<TextureRegistry>()),
	raster_time_(updater),
	ui_time_(updater) {}

	CompositorContext::~CompositorContext() = default;

	void CompositorContext::BeginFrame(ScopedFrame& frame,
	bool enable_instrumentation) {
	if (enable_instrumentation) {
	raster_time_.Start();
	}
	}

	void CompositorContext::EndFrame(ScopedFrame& frame,
	bool enable_instrumentation) {
	if (enable_instrumentation) {
	raster_time_.Stop();
	}
	}

	std::unique_ptr<CompositorContext::ScopedFrame> CompositorContext::AcquireFrame(
	GrDirectContext* gr_context,
	DlCanvas* canvas,
	ExternalViewEmbedder* view_embedder,
	const SkMatrix& root_surface_transformation,
	bool instrumentation_enabled,
	bool surface_supports_readback,
	fml::RefPtr<fml::RasterThreadMerger>
	raster_thread_merger, // NOLINT(performance-unnecessary-value-param)
	impeller::AiksContext* aiks_context) {
	return std::make_unique<ScopedFrame>(
	*this, gr_context, canvas, view_embedder, root_surface_transformation,
	instrumentation_enabled, surface_supports_readback, raster_thread_merger,
	aiks_context);
	}

	CompositorContext::ScopedFrame::ScopedFrame(
	CompositorContext& context,
	GrDirectContext* gr_context,
	DlCanvas* canvas,
	ExternalViewEmbedder* view_embedder,
	const SkMatrix& root_surface_transformation,
	bool instrumentation_enabled,
	bool surface_supports_readback,
	fml::RefPtr<fml::RasterThreadMerger> raster_thread_merger,
	impeller::AiksContext* aiks_context)
	: context_(context),
	gr_context_(gr_context),
	canvas_(canvas),
	aiks_context_(aiks_context),
	view_embedder_(view_embedder),
	root_surface_transformation_(root_surface_transformation),
	instrumentation_enabled_(instrumentation_enabled),
	surface_supports_readback_(surface_supports_readback),
	raster_thread_merger_(std::move(raster_thread_merger)) {
	context_.BeginFrame(*this, instrumentation_enabled_);
	}

	CompositorContext::ScopedFrame::~ScopedFrame() {
	context_.EndFrame(*this, instrumentation_enabled_);
	}

	RasterStatus CompositorContext::ScopedFrame::Raster(
	flutter::LayerTree& layer_tree,
	bool ignore_raster_cache,
	FrameDamage* frame_damage) {
	TRACE_EVENT0("flutter", "CompositorContext::ScopedFrame::Raster");

	std::optional<SkRect> clip_rect;
	if (frame_damage) {
	clip_rect = frame_damage->ComputeClipRect(layer_tree, !ignore_raster_cache,
	!gr_context_);

	if (aiks_context_ &&
	!ShouldPerformPartialRepaint(clip_rect, layer_tree.frame_size())) {
	clip_rect = std::nullopt;
	frame_damage->Reset();
	}
	}

	bool root_needs_readback = layer_tree.Preroll(
	this, ignore_raster_cache, clip_rect ? clip_rect : kGiantRect);
	bool needs_save_layer = root_needs_readback && !surface_supports_readback();
	PostPrerollResult post_preroll_result = PostPrerollResult::kSuccess;
	if (view_embedder_ && raster_thread_merger_) {
	post_preroll_result =
	view_embedder_->PostPrerollAction(raster_thread_merger_);
	}

	if (post_preroll_result == PostPrerollResult::kResubmitFrame) {
	return RasterStatus::kResubmit;
	}
	if (post_preroll_result == PostPrerollResult::kSkipAndRetryFrame) {
	return RasterStatus::kSkipAndRetry;
	}

	if (aiks_context_) {
	PaintLayerTreeImpeller(layer_tree, clip_rect, ignore_raster_cache);
	} else {
	PaintLayerTreeSkia(layer_tree, clip_rect, needs_save_layer,
	ignore_raster_cache);
	}
	return RasterStatus::kSuccess;
	}

	void CompositorContext::ScopedFrame::PaintLayerTreeSkia(
	flutter::LayerTree& layer_tree,
	std::optional<SkRect> clip_rect,
	bool needs_save_layer,
	bool ignore_raster_cache) {
	DlAutoCanvasRestore restore(canvas(), clip_rect.has_value());

	if (canvas()) {
	if (clip_rect) {
	canvas()->ClipRect(*clip_rect);
	}

	if (needs_save_layer) {
	TRACE_EVENT0("flutter", "Canvas::saveLayer");
	SkRect bounds = SkRect::Make(layer_tree.frame_size());
	DlPaint paint;
	paint.setBlendMode(DlBlendMode::kSrc);
	canvas()->SaveLayer(&bounds, &paint);
	}
	canvas()->Clear(DlColor::kTransparent());
	}

	// The canvas()->Restore() is taken care of by the DlAutoCanvasRestore
	layer_tree.Paint(*this, ignore_raster_cache);
	}

	void CompositorContext::ScopedFrame::PaintLayerTreeImpeller(
	flutter::LayerTree& layer_tree,
	std::optional<SkRect> clip_rect,
	bool ignore_raster_cache) {
	if (canvas() && clip_rect) {
	canvas()->Translate(-clip_rect->x(), -clip_rect->y());
	}

	layer_tree.Paint(*this, ignore_raster_cache);
	}

	/// @brief The max ratio of pixel width or height to size that is dirty which
	/// results in a partial repaint.
	///
	/// Performing a partial repaint has a small overhead - Impeller needs to
	/// allocate a fairly large resolve texture for the root pass instead of
	/// using the drawable texture, and a final blit must be performed. At a
	/// minimum, if the damage rect is the entire buffer, we must not perform
	/// a partial repaint. Beyond that, we could only experimentally
	/// determine what this value should be. From looking at the Flutter
	/// Gallery, we noticed that there are occassionally small partial
	/// repaints which shave off trivial numbers of pixels.
	constexpr float kImpellerRepaintRatio = 0.7f;

	bool CompositorContext::ShouldPerformPartialRepaint(
	std::optional<SkRect> damage_rect,
	SkISize layer_tree_size) {
	if (!damage_rect.has_value()) {
	return false;
	}
	if (damage_rect->width() >= layer_tree_size.width() &&
	damage_rect->height() >= layer_tree_size.height()) {
	return false;
	}
	auto rx = damage_rect->width() / layer_tree_size.width();
	auto ry = damage_rect->height() / layer_tree_size.height();
	return rx <= kImpellerRepaintRatio \|\| ry <= kImpellerRepaintRatio;
	}

	void CompositorContext::OnGrContextCreated() {
	texture_registry_->OnGrContextCreated();
	raster_cache_.Clear();
	}

	void CompositorContext::OnGrContextDestroyed() {
	texture_registry_->OnGrContextDestroyed();
	raster_cache_.Clear();
	}

	} // namespace flutter