// Copyright 2011 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/trees/layer_tree_host_impl.h" #include #include #include "base/basictypes.h" #include "base/containers/hash_tables.h" #include "base/json/json_writer.h" #include "base/metrics/histogram.h" #include "base/stl_util.h" #include "base/strings/stringprintf.h" #include "base/trace_event/trace_event_argument.h" #include "cc/animation/animation_id_provider.h" #include "cc/animation/scroll_offset_animation_curve.h" #include "cc/animation/scrollbar_animation_controller.h" #include "cc/animation/timing_function.h" #include "cc/base/latency_info_swap_promise_monitor.h" #include "cc/base/math_util.h" #include "cc/base/util.h" #include "cc/debug/benchmark_instrumentation.h" #include "cc/debug/debug_rect_history.h" #include "cc/debug/devtools_instrumentation.h" #include "cc/debug/frame_rate_counter.h" #include "cc/debug/paint_time_counter.h" #include "cc/debug/rendering_stats_instrumentation.h" #include "cc/debug/traced_value.h" #include "cc/input/page_scale_animation.h" #include "cc/input/scroll_elasticity_helper.h" #include "cc/input/top_controls_manager.h" #include "cc/layers/append_quads_data.h" #include "cc/layers/heads_up_display_layer_impl.h" #include "cc/layers/layer_impl.h" #include "cc/layers/layer_iterator.h" #include "cc/layers/painted_scrollbar_layer_impl.h" #include "cc/layers/render_surface_impl.h" #include "cc/layers/scrollbar_layer_impl_base.h" #include "cc/output/compositor_frame_metadata.h" #include "cc/output/copy_output_request.h" #include "cc/output/delegating_renderer.h" #include "cc/output/gl_renderer.h" #include "cc/output/software_renderer.h" #include "cc/quads/render_pass_draw_quad.h" #include "cc/quads/shared_quad_state.h" #include "cc/quads/solid_color_draw_quad.h" #include "cc/quads/texture_draw_quad.h" #include "cc/resources/bitmap_tile_task_worker_pool.h" #include "cc/resources/eviction_tile_priority_queue.h" #include "cc/resources/gpu_rasterizer.h" #include "cc/resources/gpu_tile_task_worker_pool.h" #include "cc/resources/memory_history.h" #include "cc/resources/one_copy_tile_task_worker_pool.h" #include "cc/resources/picture_layer_tiling.h" #include "cc/resources/pixel_buffer_tile_task_worker_pool.h" #include "cc/resources/prioritized_resource_manager.h" #include "cc/resources/raster_tile_priority_queue.h" #include "cc/resources/resource_pool.h" #include "cc/resources/software_rasterizer.h" #include "cc/resources/texture_mailbox_deleter.h" #include "cc/resources/tile_task_worker_pool.h" #include "cc/resources/ui_resource_bitmap.h" #include "cc/resources/zero_copy_tile_task_worker_pool.h" #include "cc/scheduler/delay_based_time_source.h" #include "cc/trees/damage_tracker.h" #include "cc/trees/layer_tree_host.h" #include "cc/trees/layer_tree_host_common.h" #include "cc/trees/layer_tree_impl.h" #include "cc/trees/single_thread_proxy.h" #include "cc/trees/tree_synchronizer.h" #include "gpu/command_buffer/client/gles2_interface.h" #include "gpu/GLES2/gl2extchromium.h" #include "ui/gfx/frame_time.h" #include "ui/gfx/geometry/rect_conversions.h" #include "ui/gfx/geometry/size_conversions.h" #include "ui/gfx/geometry/vector2d_conversions.h" namespace cc { namespace { // Small helper class that saves the current viewport location as the user sees // it and resets to the same location. class ViewportAnchor { public: ViewportAnchor(LayerImpl* inner_scroll, LayerImpl* outer_scroll) : inner_(inner_scroll), outer_(outer_scroll) { viewport_in_content_coordinates_ = inner_->CurrentScrollOffset(); if (outer_) viewport_in_content_coordinates_ += outer_->CurrentScrollOffset(); } void ResetViewportToAnchoredPosition() { DCHECK(outer_); inner_->ClampScrollToMaxScrollOffset(); outer_->ClampScrollToMaxScrollOffset(); gfx::ScrollOffset viewport_location = inner_->CurrentScrollOffset() + outer_->CurrentScrollOffset(); gfx::Vector2dF delta = viewport_in_content_coordinates_.DeltaFrom(viewport_location); delta = outer_->ScrollBy(delta); inner_->ScrollBy(delta); } private: LayerImpl* inner_; LayerImpl* outer_; gfx::ScrollOffset viewport_in_content_coordinates_; }; void DidVisibilityChange(LayerTreeHostImpl* id, bool visible) { if (visible) { TRACE_EVENT_ASYNC_BEGIN1("cc", "LayerTreeHostImpl::SetVisible", id, "LayerTreeHostImpl", id); return; } TRACE_EVENT_ASYNC_END0("cc", "LayerTreeHostImpl::SetVisible", id); } size_t GetMaxTransferBufferUsageBytes( const ContextProvider::Capabilities& context_capabilities, double refresh_rate) { // We want to make sure the default transfer buffer size is equal to the // amount of data that can be uploaded by the compositor to avoid stalling // the pipeline. // For reference Chromebook Pixel can upload 1MB in about 0.5ms. const size_t kMaxBytesUploadedPerMs = 1024 * 1024 * 2; // We need to upload at least enough work to keep the GPU process busy until // the next time it can handle a request to start more uploads from the // compositor. We assume that it will pick up any sent upload requests within // the time of a vsync, since the browser will want to swap a frame within // that time interval, and then uploads should have a chance to be processed. size_t ms_per_frame = std::floor(1000.0 / refresh_rate); size_t max_transfer_buffer_usage_bytes = ms_per_frame * kMaxBytesUploadedPerMs; // The context may request a lower limit based on the device capabilities. return std::min(context_capabilities.max_transfer_buffer_usage_bytes, max_transfer_buffer_usage_bytes); } size_t GetMaxStagingResourceCount() { // Upper bound for number of staging resource to allow. return 32; } } // namespace LayerTreeHostImpl::FrameData::FrameData() : has_no_damage(false) { } LayerTreeHostImpl::FrameData::~FrameData() {} scoped_ptr LayerTreeHostImpl::Create( const LayerTreeSettings& settings, LayerTreeHostImplClient* client, Proxy* proxy, RenderingStatsInstrumentation* rendering_stats_instrumentation, SharedBitmapManager* shared_bitmap_manager, gpu::GpuMemoryBufferManager* gpu_memory_buffer_manager, int id) { return make_scoped_ptr(new LayerTreeHostImpl(settings, client, proxy, rendering_stats_instrumentation, shared_bitmap_manager, gpu_memory_buffer_manager, id)); } LayerTreeHostImpl::LayerTreeHostImpl( const LayerTreeSettings& settings, LayerTreeHostImplClient* client, Proxy* proxy, RenderingStatsInstrumentation* rendering_stats_instrumentation, SharedBitmapManager* shared_bitmap_manager, gpu::GpuMemoryBufferManager* gpu_memory_buffer_manager, int id) : client_(client), proxy_(proxy), use_gpu_rasterization_(false), gpu_rasterization_status_(GpuRasterizationStatus::OFF_DEVICE), input_handler_client_(NULL), did_lock_scrolling_layer_(false), should_bubble_scrolls_(false), wheel_scrolling_(false), scroll_affects_scroll_handler_(false), scroll_layer_id_when_mouse_over_scrollbar_(0), tile_priorities_dirty_(false), root_layer_scroll_offset_delegate_(NULL), settings_(settings), visible_(true), cached_managed_memory_policy_( PrioritizedResourceManager::DefaultMemoryAllocationLimit(), gpu::MemoryAllocation::CUTOFF_ALLOW_EVERYTHING, ManagedMemoryPolicy::kDefaultNumResourcesLimit), pinch_gesture_active_(false), pinch_gesture_end_should_clear_scrolling_layer_(false), fps_counter_(FrameRateCounter::Create(proxy_->HasImplThread())), paint_time_counter_(PaintTimeCounter::Create()), memory_history_(MemoryHistory::Create()), debug_rect_history_(DebugRectHistory::Create()), texture_mailbox_deleter_(new TextureMailboxDeleter( proxy_->HasImplThread() ? proxy_->ImplThreadTaskRunner() : proxy_->MainThreadTaskRunner())), max_memory_needed_bytes_(0), zero_budget_(false), device_scale_factor_(1.f), resourceless_software_draw_(false), begin_impl_frame_interval_(BeginFrameArgs::DefaultInterval()), animation_registrar_(AnimationRegistrar::Create()), rendering_stats_instrumentation_(rendering_stats_instrumentation), micro_benchmark_controller_(this), shared_bitmap_manager_(shared_bitmap_manager), gpu_memory_buffer_manager_(gpu_memory_buffer_manager), id_(id), requires_high_res_to_draw_(false), is_likely_to_require_a_draw_(false), frame_timing_tracker_(FrameTimingTracker::Create()) { DCHECK(proxy_->IsImplThread()); DidVisibilityChange(this, visible_); animation_registrar_->set_supports_scroll_animations( proxy_->SupportsImplScrolling()); SetDebugState(settings.initial_debug_state); // LTHI always has an active tree. active_tree_ = LayerTreeImpl::create(this, new SyncedProperty(), new SyncedTopControls, new SyncedElasticOverscroll); TRACE_EVENT_OBJECT_CREATED_WITH_ID( TRACE_DISABLED_BY_DEFAULT("cc.debug"), "cc::LayerTreeHostImpl", id_); if (settings.calculate_top_controls_position) { top_controls_manager_ = TopControlsManager::Create(this, settings.top_controls_show_threshold, settings.top_controls_hide_threshold); } } LayerTreeHostImpl::~LayerTreeHostImpl() { DCHECK(proxy_->IsImplThread()); TRACE_EVENT0("cc", "LayerTreeHostImpl::~LayerTreeHostImpl()"); TRACE_EVENT_OBJECT_DELETED_WITH_ID( TRACE_DISABLED_BY_DEFAULT("cc.debug"), "cc::LayerTreeHostImpl", id_); if (input_handler_client_) { input_handler_client_->WillShutdown(); input_handler_client_ = NULL; } if (scroll_elasticity_helper_) scroll_elasticity_helper_.reset(); // The layer trees must be destroyed before the layer tree host. We've // made a contract with our animation controllers that the registrar // will outlive them, and we must make good. if (recycle_tree_) recycle_tree_->Shutdown(); if (pending_tree_) pending_tree_->Shutdown(); active_tree_->Shutdown(); recycle_tree_ = nullptr; pending_tree_ = nullptr; active_tree_ = nullptr; DestroyTileManager(); } void LayerTreeHostImpl::BeginMainFrameAborted(CommitEarlyOutReason reason) { // If the begin frame data was handled, then scroll and scale set was applied // by the main thread, so the active tree needs to be updated as if these sent // values were applied and committed. if (CommitEarlyOutHandledCommit(reason)) { active_tree_->ApplySentScrollAndScaleDeltasFromAbortedCommit(); active_tree_->ResetContentsTexturesPurged(); } } void LayerTreeHostImpl::BeginCommit() { TRACE_EVENT0("cc", "LayerTreeHostImpl::BeginCommit"); // Ensure all textures are returned so partial texture updates can happen // during the commit. Impl-side-painting doesn't upload during commits, so // is unaffected. if (!settings_.impl_side_painting && output_surface_) output_surface_->ForceReclaimResources(); if (settings_.impl_side_painting && !proxy_->CommitToActiveTree()) CreatePendingTree(); } void LayerTreeHostImpl::CommitComplete() { TRACE_EVENT0("cc", "LayerTreeHostImpl::CommitComplete"); sync_tree()->set_needs_update_draw_properties(); if (settings_.impl_side_painting) { // Impl-side painting needs an update immediately post-commit to have the // opportunity to create tilings. Other paths can call UpdateDrawProperties // more lazily when needed prior to drawing. Because invalidations may // be coming from the main thread, it's safe to do an update for lcd text // at this point and see if lcd text needs to be disabled on any layers. bool update_lcd_text = true; sync_tree()->UpdateDrawProperties(update_lcd_text); // Start working on newly created tiles immediately if needed. if (tile_manager_ && tile_priorities_dirty_) PrepareTiles(); else NotifyReadyToActivate(); } else { // If we're not in impl-side painting, the tree is immediately considered // active. ActivateSyncTree(); } micro_benchmark_controller_.DidCompleteCommit(); } bool LayerTreeHostImpl::CanDraw() const { // Note: If you are changing this function or any other function that might // affect the result of CanDraw, make sure to call // client_->OnCanDrawStateChanged in the proper places and update the // NotifyIfCanDrawChanged test. if (!renderer_) { TRACE_EVENT_INSTANT0("cc", "LayerTreeHostImpl::CanDraw no renderer", TRACE_EVENT_SCOPE_THREAD); return false; } // Must have an OutputSurface if |renderer_| is not NULL. DCHECK(output_surface_); // TODO(boliu): Make draws without root_layer work and move this below // draw_and_swap_full_viewport_every_frame check. Tracked in crbug.com/264967. if (!active_tree_->root_layer()) { TRACE_EVENT_INSTANT0("cc", "LayerTreeHostImpl::CanDraw no root layer", TRACE_EVENT_SCOPE_THREAD); return false; } if (output_surface_->capabilities().draw_and_swap_full_viewport_every_frame) return true; if (DrawViewportSize().IsEmpty()) { TRACE_EVENT_INSTANT0("cc", "LayerTreeHostImpl::CanDraw empty viewport", TRACE_EVENT_SCOPE_THREAD); return false; } if (active_tree_->ViewportSizeInvalid()) { TRACE_EVENT_INSTANT0( "cc", "LayerTreeHostImpl::CanDraw viewport size recently changed", TRACE_EVENT_SCOPE_THREAD); return false; } if (active_tree_->ContentsTexturesPurged()) { TRACE_EVENT_INSTANT0( "cc", "LayerTreeHostImpl::CanDraw contents textures purged", TRACE_EVENT_SCOPE_THREAD); return false; } if (EvictedUIResourcesExist()) { TRACE_EVENT_INSTANT0( "cc", "LayerTreeHostImpl::CanDraw UI resources evicted not recreated", TRACE_EVENT_SCOPE_THREAD); return false; } return true; } void LayerTreeHostImpl::Animate(base::TimeTicks monotonic_time) { if (input_handler_client_) input_handler_client_->Animate(monotonic_time); AnimatePageScale(monotonic_time); AnimateLayers(monotonic_time); AnimateScrollbars(monotonic_time); AnimateTopControls(monotonic_time); } void LayerTreeHostImpl::PrepareTiles() { if (!tile_manager_) return; if (!tile_priorities_dirty_) return; tile_priorities_dirty_ = false; tile_manager_->PrepareTiles(global_tile_state_); client_->DidPrepareTiles(); } void LayerTreeHostImpl::StartPageScaleAnimation( const gfx::Vector2d& target_offset, bool anchor_point, float page_scale, base::TimeDelta duration) { if (!InnerViewportScrollLayer()) return; gfx::ScrollOffset scroll_total = active_tree_->TotalScrollOffset(); gfx::SizeF scaled_scrollable_size = active_tree_->ScrollableSize(); gfx::SizeF viewport_size = active_tree_->InnerViewportContainerLayer()->bounds(); // Easing constants experimentally determined. scoped_ptr timing_function = CubicBezierTimingFunction::Create(.8, 0, .3, .9); // TODO(miletus) : Pass in ScrollOffset. page_scale_animation_ = PageScaleAnimation::Create( ScrollOffsetToVector2dF(scroll_total), active_tree_->current_page_scale_factor(), viewport_size, scaled_scrollable_size, timing_function.Pass()); if (anchor_point) { gfx::Vector2dF anchor(target_offset); page_scale_animation_->ZoomWithAnchor(anchor, page_scale, duration.InSecondsF()); } else { gfx::Vector2dF scaled_target_offset = target_offset; page_scale_animation_->ZoomTo(scaled_target_offset, page_scale, duration.InSecondsF()); } SetNeedsAnimate(); client_->SetNeedsCommitOnImplThread(); client_->RenewTreePriority(); } bool LayerTreeHostImpl::IsCurrentlyScrollingLayerAt( const gfx::Point& viewport_point, InputHandler::ScrollInputType type) { if (!CurrentlyScrollingLayer()) return false; gfx::PointF device_viewport_point = gfx::ScalePoint(viewport_point, device_scale_factor_); LayerImpl* layer_impl = active_tree_->FindLayerThatIsHitByPoint(device_viewport_point); bool scroll_on_main_thread = false; LayerImpl* scrolling_layer_impl = FindScrollLayerForDeviceViewportPoint( device_viewport_point, type, layer_impl, &scroll_on_main_thread, NULL); return CurrentlyScrollingLayer() == scrolling_layer_impl; } bool LayerTreeHostImpl::HaveWheelEventHandlersAt( const gfx::Point& viewport_point) { gfx::PointF device_viewport_point = gfx::ScalePoint(viewport_point, device_scale_factor_); LayerImpl* layer_impl = active_tree_->FindLayerWithWheelHandlerThatIsHitByPoint( device_viewport_point); return layer_impl != NULL; } static LayerImpl* NextScrollLayer(LayerImpl* layer) { if (LayerImpl* scroll_parent = layer->scroll_parent()) return scroll_parent; return layer->parent(); } static ScrollBlocksOn EffectiveScrollBlocksOn(LayerImpl* layer) { ScrollBlocksOn blocks = SCROLL_BLOCKS_ON_NONE; for (; layer; layer = NextScrollLayer(layer)) { blocks |= layer->scroll_blocks_on(); } return blocks; } bool LayerTreeHostImpl::DoTouchEventsBlockScrollAt( const gfx::Point& viewport_point) { gfx::PointF device_viewport_point = gfx::ScalePoint(viewport_point, device_scale_factor_); // First check if scrolling at this point is required to block on any // touch event handlers. Note that we must start at the innermost layer // (as opposed to only the layer found to contain a touch handler region // below) to ensure all relevant scroll-blocks-on values are applied. LayerImpl* layer_impl = active_tree_->FindLayerThatIsHitByPoint(device_viewport_point); ScrollBlocksOn blocking = EffectiveScrollBlocksOn(layer_impl); if (!(blocking & SCROLL_BLOCKS_ON_START_TOUCH)) return false; // Now determine if there are actually any handlers at that point. // TODO(rbyers): Consider also honoring touch-action (crbug.com/347272). layer_impl = active_tree_->FindLayerThatIsHitByPointInTouchHandlerRegion( device_viewport_point); return layer_impl != NULL; } scoped_ptr LayerTreeHostImpl::CreateLatencyInfoSwapPromiseMonitor( ui::LatencyInfo* latency) { return make_scoped_ptr( new LatencyInfoSwapPromiseMonitor(latency, NULL, this)); } ScrollElasticityHelper* LayerTreeHostImpl::CreateScrollElasticityHelper() { DCHECK(!scroll_elasticity_helper_); if (settings_.enable_elastic_overscroll) { scroll_elasticity_helper_.reset( ScrollElasticityHelper::CreateForLayerTreeHostImpl(this)); } return scroll_elasticity_helper_.get(); } void LayerTreeHostImpl::QueueSwapPromiseForMainThreadScrollUpdate( scoped_ptr swap_promise) { swap_promises_for_main_thread_scroll_update_.push_back(swap_promise.Pass()); } void LayerTreeHostImpl::TrackDamageForAllSurfaces( LayerImpl* root_draw_layer, const LayerImplList& render_surface_layer_list) { // For now, we use damage tracking to compute a global scissor. To do this, we // must compute all damage tracking before drawing anything, so that we know // the root damage rect. The root damage rect is then used to scissor each // surface. for (int surface_index = render_surface_layer_list.size() - 1; surface_index >= 0; --surface_index) { LayerImpl* render_surface_layer = render_surface_layer_list[surface_index]; RenderSurfaceImpl* render_surface = render_surface_layer->render_surface(); DCHECK(render_surface); render_surface->damage_tracker()->UpdateDamageTrackingState( render_surface->layer_list(), render_surface_layer->id(), render_surface->SurfacePropertyChangedOnlyFromDescendant(), render_surface->content_rect(), render_surface_layer->mask_layer(), render_surface_layer->filters()); } } void LayerTreeHostImpl::FrameData::AsValueInto( base::trace_event::TracedValue* value) const { value->SetBoolean("has_no_damage", has_no_damage); // Quad data can be quite large, so only dump render passes if we select // cc.debug.quads. bool quads_enabled; TRACE_EVENT_CATEGORY_GROUP_ENABLED( TRACE_DISABLED_BY_DEFAULT("cc.debug.quads"), &quads_enabled); if (quads_enabled) { value->BeginArray("render_passes"); for (size_t i = 0; i < render_passes.size(); ++i) { value->BeginDictionary(); render_passes[i]->AsValueInto(value); value->EndDictionary(); } value->EndArray(); } } void LayerTreeHostImpl::FrameData::AppendRenderPass( scoped_ptr render_pass) { render_passes_by_id[render_pass->id] = render_pass.get(); render_passes.push_back(render_pass.Pass()); } DrawMode LayerTreeHostImpl::GetDrawMode() const { if (resourceless_software_draw_) { return DRAW_MODE_RESOURCELESS_SOFTWARE; } else if (output_surface_->context_provider()) { return DRAW_MODE_HARDWARE; } else { DCHECK_EQ(!output_surface_->software_device(), output_surface_->capabilities().delegated_rendering && !output_surface_->capabilities().deferred_gl_initialization) << output_surface_->capabilities().delegated_rendering << " " << output_surface_->capabilities().deferred_gl_initialization; return DRAW_MODE_SOFTWARE; } } static void AppendQuadsForRenderSurfaceLayer( RenderPass* target_render_pass, LayerImpl* layer, const RenderPass* contributing_render_pass, AppendQuadsData* append_quads_data) { RenderSurfaceImpl* surface = layer->render_surface(); const gfx::Transform& draw_transform = surface->draw_transform(); const Occlusion& occlusion = surface->occlusion_in_content_space(); SkColor debug_border_color = surface->GetDebugBorderColor(); float debug_border_width = surface->GetDebugBorderWidth(); LayerImpl* mask_layer = layer->mask_layer(); surface->AppendQuads(target_render_pass, draw_transform, occlusion, debug_border_color, debug_border_width, mask_layer, append_quads_data, contributing_render_pass->id); // Add replica after the surface so that it appears below the surface. if (layer->has_replica()) { const gfx::Transform& replica_draw_transform = surface->replica_draw_transform(); Occlusion replica_occlusion = occlusion.GetOcclusionWithGivenDrawTransform( surface->replica_draw_transform()); SkColor replica_debug_border_color = surface->GetReplicaDebugBorderColor(); float replica_debug_border_width = surface->GetReplicaDebugBorderWidth(); // TODO(danakj): By using the same RenderSurfaceImpl for both the // content and its reflection, it's currently not possible to apply a // separate mask to the reflection layer or correctly handle opacity in // reflections (opacity must be applied after drawing both the layer and its // reflection). The solution is to introduce yet another RenderSurfaceImpl // to draw the layer and its reflection in. For now we only apply a separate // reflection mask if the contents don't have a mask of their own. LayerImpl* replica_mask_layer = mask_layer ? mask_layer : layer->replica_layer()->mask_layer(); surface->AppendQuads(target_render_pass, replica_draw_transform, replica_occlusion, replica_debug_border_color, replica_debug_border_width, replica_mask_layer, append_quads_data, contributing_render_pass->id); } } static void AppendQuadsToFillScreen(const gfx::Rect& root_scroll_layer_rect, RenderPass* target_render_pass, LayerImpl* root_layer, SkColor screen_background_color, const Region& fill_region) { if (!root_layer || !SkColorGetA(screen_background_color)) return; if (fill_region.IsEmpty()) return; // Manually create the quad state for the gutter quads, as the root layer // doesn't have any bounds and so can't generate this itself. // TODO(danakj): Make the gutter quads generated by the solid color layer // (make it smarter about generating quads to fill unoccluded areas). gfx::Rect root_target_rect = root_layer->render_surface()->content_rect(); float opacity = 1.f; int sorting_context_id = 0; SharedQuadState* shared_quad_state = target_render_pass->CreateAndAppendSharedQuadState(); shared_quad_state->SetAll(gfx::Transform(), root_target_rect.size(), root_target_rect, root_target_rect, false, opacity, SkXfermode::kSrcOver_Mode, sorting_context_id); for (Region::Iterator fill_rects(fill_region); fill_rects.has_rect(); fill_rects.next()) { gfx::Rect screen_space_rect = fill_rects.rect(); gfx::Rect visible_screen_space_rect = screen_space_rect; // Skip the quad culler and just append the quads directly to avoid // occlusion checks. SolidColorDrawQuad* quad = target_render_pass->CreateAndAppendDrawQuad(); quad->SetNew(shared_quad_state, screen_space_rect, visible_screen_space_rect, screen_background_color, false); } } DrawResult LayerTreeHostImpl::CalculateRenderPasses( FrameData* frame) { DCHECK(frame->render_passes.empty()); DCHECK(CanDraw()); DCHECK(active_tree_->root_layer()); TrackDamageForAllSurfaces(active_tree_->root_layer(), *frame->render_surface_layer_list); // If the root render surface has no visible damage, then don't generate a // frame at all. RenderSurfaceImpl* root_surface = active_tree_->root_layer()->render_surface(); bool root_surface_has_no_visible_damage = !root_surface->damage_tracker()->current_damage_rect().Intersects( root_surface->content_rect()); bool root_surface_has_contributing_layers = !root_surface->layer_list().empty(); bool hud_wants_to_draw_ = active_tree_->hud_layer() && active_tree_->hud_layer()->IsAnimatingHUDContents(); if (root_surface_has_contributing_layers && root_surface_has_no_visible_damage && active_tree_->LayersWithCopyOutputRequest().empty() && !output_surface_->capabilities().can_force_reclaim_resources && !hud_wants_to_draw_) { TRACE_EVENT0("cc", "LayerTreeHostImpl::CalculateRenderPasses::EmptyDamageRect"); frame->has_no_damage = true; DCHECK(!output_surface_->capabilities() .draw_and_swap_full_viewport_every_frame); return DRAW_SUCCESS; } TRACE_EVENT1("cc", "LayerTreeHostImpl::CalculateRenderPasses", "render_surface_layer_list.size()", static_cast(frame->render_surface_layer_list->size())); // Create the render passes in dependency order. for (int surface_index = frame->render_surface_layer_list->size() - 1; surface_index >= 0; --surface_index) { LayerImpl* render_surface_layer = (*frame->render_surface_layer_list)[surface_index]; RenderSurfaceImpl* render_surface = render_surface_layer->render_surface(); bool should_draw_into_render_pass = render_surface_layer->parent() == NULL || render_surface->contributes_to_drawn_surface() || render_surface_layer->HasCopyRequest(); if (should_draw_into_render_pass) render_surface->AppendRenderPasses(frame); } // When we are displaying the HUD, change the root damage rect to cover the // entire root surface. This will disable partial-swap/scissor optimizations // that would prevent the HUD from updating, since the HUD does not cause // damage itself, to prevent it from messing with damage visualizations. Since // damage visualizations are done off the LayerImpls and RenderSurfaceImpls, // changing the RenderPass does not affect them. if (active_tree_->hud_layer()) { RenderPass* root_pass = frame->render_passes.back(); root_pass->damage_rect = root_pass->output_rect; } // Grab this region here before iterating layers. Taking copy requests from // the layers while constructing the render passes will dirty the render // surface layer list and this unoccluded region, flipping the dirty bit to // true, and making us able to query for it without doing // UpdateDrawProperties again. The value inside the Region is not actually // changed until UpdateDrawProperties happens, so a reference to it is safe. const Region& unoccluded_screen_space_region = active_tree_->UnoccludedScreenSpaceRegion(); // Typically when we are missing a texture and use a checkerboard quad, we // still draw the frame. However when the layer being checkerboarded is moving // due to an impl-animation, we drop the frame to avoid flashing due to the // texture suddenly appearing in the future. DrawResult draw_result = DRAW_SUCCESS; // When we have a copy request for a layer, we need to draw no matter // what, as the layer may disappear after this frame. bool have_copy_request = false; int layers_drawn = 0; const DrawMode draw_mode = GetDrawMode(); int num_missing_tiles = 0; int num_incomplete_tiles = 0; auto end = LayerIterator::End(frame->render_surface_layer_list); for (auto it = LayerIterator::Begin(frame->render_surface_layer_list); it != end; ++it) { RenderPassId target_render_pass_id = it.target_render_surface_layer()->render_surface()->GetRenderPassId(); RenderPass* target_render_pass = frame->render_passes_by_id[target_render_pass_id]; AppendQuadsData append_quads_data; if (it.represents_target_render_surface()) { if (it->HasCopyRequest()) { have_copy_request = true; it->TakeCopyRequestsAndTransformToTarget( &target_render_pass->copy_requests); } } else if (it.represents_contributing_render_surface() && it->render_surface()->contributes_to_drawn_surface()) { RenderPassId contributing_render_pass_id = it->render_surface()->GetRenderPassId(); RenderPass* contributing_render_pass = frame->render_passes_by_id[contributing_render_pass_id]; AppendQuadsForRenderSurfaceLayer(target_render_pass, *it, contributing_render_pass, &append_quads_data); } else if (it.represents_itself() && !it->visible_content_rect().IsEmpty()) { bool occluded = it->draw_properties().occlusion_in_content_space.IsOccluded( it->visible_content_rect()); if (!occluded && it->WillDraw(draw_mode, resource_provider_.get())) { DCHECK_EQ(active_tree_, it->layer_tree_impl()); frame->will_draw_layers.push_back(*it); if (it->HasContributingDelegatedRenderPasses()) { RenderPassId contributing_render_pass_id = it->FirstContributingRenderPassId(); while (frame->render_passes_by_id.find(contributing_render_pass_id) != frame->render_passes_by_id.end()) { RenderPass* render_pass = frame->render_passes_by_id[contributing_render_pass_id]; it->AppendQuads(render_pass, &append_quads_data); contributing_render_pass_id = it->NextContributingRenderPassId(contributing_render_pass_id); } } it->AppendQuads(target_render_pass, &append_quads_data); // For layers that represent themselves, add composite frame timing // requests if the visible rect intersects the requested rect. for (const auto& request : it->frame_timing_requests()) { const gfx::Rect& request_content_rect = it->LayerRectToContentRect(request.rect()); if (request_content_rect.Intersects(it->visible_content_rect())) { frame->composite_events.push_back( FrameTimingTracker::FrameAndRectIds( active_tree_->source_frame_number(), request.id())); } } } ++layers_drawn; } rendering_stats_instrumentation_->AddVisibleContentArea( append_quads_data.visible_content_area); rendering_stats_instrumentation_->AddApproximatedVisibleContentArea( append_quads_data.approximated_visible_content_area); num_missing_tiles += append_quads_data.num_missing_tiles; num_incomplete_tiles += append_quads_data.num_incomplete_tiles; if (append_quads_data.num_missing_tiles) { bool layer_has_animating_transform = it->screen_space_transform_is_animating() || it->draw_transform_is_animating(); if (layer_has_animating_transform) draw_result = DRAW_ABORTED_CHECKERBOARD_ANIMATIONS; } if (append_quads_data.num_incomplete_tiles || append_quads_data.num_missing_tiles) { if (RequiresHighResToDraw()) draw_result = DRAW_ABORTED_MISSING_HIGH_RES_CONTENT; } } if (have_copy_request || output_surface_->capabilities().draw_and_swap_full_viewport_every_frame) draw_result = DRAW_SUCCESS; #if DCHECK_IS_ON() for (const auto& render_pass : frame->render_passes) { for (const auto& quad : render_pass->quad_list) DCHECK(quad->shared_quad_state); DCHECK(frame->render_passes_by_id.find(render_pass->id) != frame->render_passes_by_id.end()); } #endif DCHECK(frame->render_passes.back()->output_rect.origin().IsOrigin()); if (!active_tree_->has_transparent_background()) { frame->render_passes.back()->has_transparent_background = false; AppendQuadsToFillScreen( active_tree_->RootScrollLayerDeviceViewportBounds(), frame->render_passes.back(), active_tree_->root_layer(), active_tree_->background_color(), unoccluded_screen_space_region); } RemoveRenderPasses(CullRenderPassesWithNoQuads(), frame); renderer_->DecideRenderPassAllocationsForFrame(frame->render_passes); // Any copy requests left in the tree are not going to get serviced, and // should be aborted. ScopedPtrVector requests_to_abort; while (!active_tree_->LayersWithCopyOutputRequest().empty()) { LayerImpl* layer = active_tree_->LayersWithCopyOutputRequest().back(); layer->TakeCopyRequestsAndTransformToTarget(&requests_to_abort); } for (size_t i = 0; i < requests_to_abort.size(); ++i) requests_to_abort[i]->SendEmptyResult(); // If we're making a frame to draw, it better have at least one render pass. DCHECK(!frame->render_passes.empty()); if (active_tree_->has_ever_been_drawn()) { UMA_HISTOGRAM_COUNTS_100( "Compositing.RenderPass.AppendQuadData.NumMissingTiles", num_missing_tiles); UMA_HISTOGRAM_COUNTS_100( "Compositing.RenderPass.AppendQuadData.NumIncompleteTiles", num_incomplete_tiles); } // Should only have one render pass in resourceless software mode. DCHECK(draw_mode != DRAW_MODE_RESOURCELESS_SOFTWARE || frame->render_passes.size() == 1u) << frame->render_passes.size(); return draw_result; } void LayerTreeHostImpl::MainThreadHasStoppedFlinging() { if (input_handler_client_) input_handler_client_->MainThreadHasStoppedFlinging(); } void LayerTreeHostImpl::DidAnimateScrollOffset() { client_->SetNeedsCommitOnImplThread(); client_->RenewTreePriority(); } void LayerTreeHostImpl::SetViewportDamage(const gfx::Rect& damage_rect) { viewport_damage_rect_.Union(damage_rect); } static inline RenderPass* FindRenderPassById( RenderPassId render_pass_id, const LayerTreeHostImpl::FrameData& frame) { RenderPassIdHashMap::const_iterator it = frame.render_passes_by_id.find(render_pass_id); return it != frame.render_passes_by_id.end() ? it->second : NULL; } static void RemoveRenderPassesRecursive(RenderPassId remove_render_pass_id, LayerTreeHostImpl::FrameData* frame) { RenderPass* remove_render_pass = FindRenderPassById(remove_render_pass_id, *frame); // The pass was already removed by another quad - probably the original, and // we are the replica. if (!remove_render_pass) return; RenderPassList& render_passes = frame->render_passes; RenderPassList::iterator to_remove = std::find(render_passes.begin(), render_passes.end(), remove_render_pass); DCHECK(to_remove != render_passes.end()); scoped_ptr removed_pass = render_passes.take(to_remove); frame->render_passes.erase(to_remove); frame->render_passes_by_id.erase(remove_render_pass_id); // Now follow up for all RenderPass quads and remove their RenderPasses // recursively. const QuadList& quad_list = removed_pass->quad_list; for (auto quad_list_iterator = quad_list.BackToFrontBegin(); quad_list_iterator != quad_list.BackToFrontEnd(); ++quad_list_iterator) { const DrawQuad* current_quad = *quad_list_iterator; if (current_quad->material != DrawQuad::RENDER_PASS) continue; RenderPassId next_remove_render_pass_id = RenderPassDrawQuad::MaterialCast(current_quad)->render_pass_id; RemoveRenderPassesRecursive(next_remove_render_pass_id, frame); } } bool LayerTreeHostImpl::CullRenderPassesWithNoQuads::ShouldRemoveRenderPass( const RenderPassDrawQuad& quad, const FrameData& frame) const { const RenderPass* render_pass = FindRenderPassById(quad.render_pass_id, frame); if (!render_pass) return false; // If any quad or RenderPass draws into this RenderPass, then keep it. const QuadList& quad_list = render_pass->quad_list; for (auto quad_list_iterator = quad_list.BackToFrontBegin(); quad_list_iterator != quad_list.BackToFrontEnd(); ++quad_list_iterator) { const DrawQuad* current_quad = *quad_list_iterator; if (current_quad->material != DrawQuad::RENDER_PASS) return false; const RenderPass* contributing_pass = FindRenderPassById( RenderPassDrawQuad::MaterialCast(current_quad)->render_pass_id, frame); if (contributing_pass) return false; } return true; } // Defined for linking tests. template CC_EXPORT void LayerTreeHostImpl::RemoveRenderPasses< LayerTreeHostImpl::CullRenderPassesWithNoQuads>( CullRenderPassesWithNoQuads culler, FrameData*); // static template void LayerTreeHostImpl::RemoveRenderPasses(RenderPassCuller culler, FrameData* frame) { for (size_t it = culler.RenderPassListBegin(frame->render_passes); it != culler.RenderPassListEnd(frame->render_passes); it = culler.RenderPassListNext(it)) { const RenderPass* current_pass = frame->render_passes[it]; const QuadList& quad_list = current_pass->quad_list; for (auto quad_list_iterator = quad_list.BackToFrontBegin(); quad_list_iterator != quad_list.BackToFrontEnd(); ++quad_list_iterator) { const DrawQuad* current_quad = *quad_list_iterator; if (current_quad->material != DrawQuad::RENDER_PASS) continue; const RenderPassDrawQuad* render_pass_quad = RenderPassDrawQuad::MaterialCast(current_quad); if (!culler.ShouldRemoveRenderPass(*render_pass_quad, *frame)) continue; // We are changing the vector in the middle of iteration. Because we // delete render passes that draw into the current pass, we are // guaranteed that any data from the iterator to the end will not // change. So, capture the iterator position from the end of the // list, and restore it after the change. size_t position_from_end = frame->render_passes.size() - it; RemoveRenderPassesRecursive(render_pass_quad->render_pass_id, frame); it = frame->render_passes.size() - position_from_end; DCHECK_GE(frame->render_passes.size(), position_from_end); } } } DrawResult LayerTreeHostImpl::PrepareToDraw(FrameData* frame) { TRACE_EVENT1("cc", "LayerTreeHostImpl::PrepareToDraw", "SourceFrameNumber", active_tree_->source_frame_number()); if (input_handler_client_) input_handler_client_->ReconcileElasticOverscrollAndRootScroll(); UMA_HISTOGRAM_CUSTOM_COUNTS( "Compositing.NumActiveLayers", active_tree_->NumLayers(), 1, 400, 20); bool update_lcd_text = false; bool ok = active_tree_->UpdateDrawProperties(update_lcd_text); DCHECK(ok) << "UpdateDrawProperties failed during draw"; // This will cause NotifyTileStateChanged() to be called for any visible tiles // that completed, which will add damage to the frame for them so they appear // as part of the current frame being drawn. if (settings().impl_side_painting) tile_manager_->UpdateVisibleTiles(global_tile_state_); frame->render_surface_layer_list = &active_tree_->RenderSurfaceLayerList(); frame->render_passes.clear(); frame->render_passes_by_id.clear(); frame->will_draw_layers.clear(); frame->has_no_damage = false; if (active_tree_->root_layer()) { gfx::Rect device_viewport_damage_rect = viewport_damage_rect_; viewport_damage_rect_ = gfx::Rect(); active_tree_->root_layer()->render_surface()->damage_tracker()-> AddDamageNextUpdate(device_viewport_damage_rect); } DrawResult draw_result = CalculateRenderPasses(frame); if (draw_result != DRAW_SUCCESS) { DCHECK(!output_surface_->capabilities() .draw_and_swap_full_viewport_every_frame); return draw_result; } // If we return DRAW_SUCCESS, then we expect DrawLayers() to be called before // this function is called again. return draw_result; } void LayerTreeHostImpl::EvictTexturesForTesting() { EnforceManagedMemoryPolicy(ManagedMemoryPolicy(0)); } void LayerTreeHostImpl::BlockNotifyReadyToActivateForTesting(bool block) { NOTREACHED(); } void LayerTreeHostImpl::ResetTreesForTesting() { if (active_tree_) active_tree_->DetachLayerTree(); active_tree_ = LayerTreeImpl::create(this, active_tree()->page_scale_factor(), active_tree()->top_controls_shown_ratio(), active_tree()->elastic_overscroll()); if (pending_tree_) pending_tree_->DetachLayerTree(); pending_tree_ = nullptr; if (recycle_tree_) recycle_tree_->DetachLayerTree(); recycle_tree_ = nullptr; } void LayerTreeHostImpl::EnforceManagedMemoryPolicy( const ManagedMemoryPolicy& policy) { bool evicted_resources = client_->ReduceContentsTextureMemoryOnImplThread( visible_ ? policy.bytes_limit_when_visible : 0, ManagedMemoryPolicy::PriorityCutoffToValue( visible_ ? policy.priority_cutoff_when_visible : gpu::MemoryAllocation::CUTOFF_ALLOW_NOTHING)); if (evicted_resources) { active_tree_->SetContentsTexturesPurged(); if (pending_tree_) pending_tree_->SetContentsTexturesPurged(); client_->SetNeedsCommitOnImplThread(); client_->OnCanDrawStateChanged(CanDraw()); client_->RenewTreePriority(); } UpdateTileManagerMemoryPolicy(policy); } void LayerTreeHostImpl::UpdateTileManagerMemoryPolicy( const ManagedMemoryPolicy& policy) { if (!tile_manager_) return; global_tile_state_.hard_memory_limit_in_bytes = 0; global_tile_state_.soft_memory_limit_in_bytes = 0; if (visible_ && policy.bytes_limit_when_visible > 0) { global_tile_state_.hard_memory_limit_in_bytes = policy.bytes_limit_when_visible; global_tile_state_.soft_memory_limit_in_bytes = (static_cast(global_tile_state_.hard_memory_limit_in_bytes) * settings_.max_memory_for_prepaint_percentage) / 100; } global_tile_state_.memory_limit_policy = ManagedMemoryPolicy::PriorityCutoffToTileMemoryLimitPolicy( visible_ ? policy.priority_cutoff_when_visible : gpu::MemoryAllocation::CUTOFF_ALLOW_NOTHING); global_tile_state_.num_resources_limit = policy.num_resources_limit; // TODO(reveman): We should avoid keeping around unused resources if // possible. crbug.com/224475 // Unused limit is calculated from soft-limit, as hard-limit may // be very high and shouldn't typically be exceeded. size_t unused_memory_limit_in_bytes = static_cast( (static_cast(global_tile_state_.soft_memory_limit_in_bytes) * settings_.max_unused_resource_memory_percentage) / 100); DCHECK(resource_pool_); resource_pool_->CheckBusyResources(false); // Soft limit is used for resource pool such that memory returns to soft // limit after going over. resource_pool_->SetResourceUsageLimits( global_tile_state_.soft_memory_limit_in_bytes, unused_memory_limit_in_bytes, global_tile_state_.num_resources_limit); // Release all staging resources when invisible. if (staging_resource_pool_) { staging_resource_pool_->CheckBusyResources(false); staging_resource_pool_->SetResourceUsageLimits( std::numeric_limits::max(), std::numeric_limits::max(), visible_ ? GetMaxStagingResourceCount() : 0); } DidModifyTilePriorities(); } void LayerTreeHostImpl::DidModifyTilePriorities() { DCHECK(settings_.impl_side_painting); // Mark priorities as dirty and schedule a PrepareTiles(). tile_priorities_dirty_ = true; client_->SetNeedsPrepareTilesOnImplThread(); } void LayerTreeHostImpl::GetPictureLayerImplPairs( std::vector* layer_pairs, bool need_valid_tile_priorities) const { DCHECK(layer_pairs->empty()); for (auto& layer : active_tree_->picture_layers()) { if (need_valid_tile_priorities && !layer->HasValidTilePriorities()) continue; PictureLayerImpl* twin_layer = layer->GetPendingOrActiveTwinLayer(); // Ignore the twin layer when tile priorities are invalid. if (need_valid_tile_priorities && twin_layer && !twin_layer->HasValidTilePriorities()) { twin_layer = nullptr; } layer_pairs->push_back(PictureLayerImpl::Pair(layer, twin_layer)); } if (pending_tree_) { for (auto& layer : pending_tree_->picture_layers()) { if (need_valid_tile_priorities && !layer->HasValidTilePriorities()) continue; if (PictureLayerImpl* twin_layer = layer->GetPendingOrActiveTwinLayer()) { if (!need_valid_tile_priorities || twin_layer->HasValidTilePriorities()) { // Already captured from the active tree. continue; } } layer_pairs->push_back(PictureLayerImpl::Pair(nullptr, layer)); } } } scoped_ptr LayerTreeHostImpl::BuildRasterQueue( TreePriority tree_priority, RasterTilePriorityQueue::Type type) { TRACE_EVENT0("cc", "LayerTreeHostImpl::BuildRasterQueue"); picture_layer_pairs_.clear(); GetPictureLayerImplPairs(&picture_layer_pairs_, true); return RasterTilePriorityQueue::Create(picture_layer_pairs_, tree_priority, type); } scoped_ptr LayerTreeHostImpl::BuildEvictionQueue( TreePriority tree_priority) { TRACE_EVENT0("cc", "LayerTreeHostImpl::BuildEvictionQueue"); scoped_ptr queue(new EvictionTilePriorityQueue); picture_layer_pairs_.clear(); GetPictureLayerImplPairs(&picture_layer_pairs_, false); queue->Build(picture_layer_pairs_, tree_priority); return queue; } void LayerTreeHostImpl::SetIsLikelyToRequireADraw( bool is_likely_to_require_a_draw) { // Proactively tell the scheduler that we expect to draw within each vsync // until we get all the tiles ready to draw. If we happen to miss a required // for draw tile here, then we will miss telling the scheduler each frame that // we intend to draw so it may make worse scheduling decisions. is_likely_to_require_a_draw_ = is_likely_to_require_a_draw; } void LayerTreeHostImpl::NotifyReadyToActivate() { client_->NotifyReadyToActivate(); } void LayerTreeHostImpl::NotifyReadyToDraw() { // Tiles that are ready will cause NotifyTileStateChanged() to be called so we // don't need to schedule a draw here. Just stop WillBeginImplFrame() from // causing optimistic requests to draw a frame. is_likely_to_require_a_draw_ = false; client_->NotifyReadyToDraw(); } void LayerTreeHostImpl::NotifyTileStateChanged(const Tile* tile) { TRACE_EVENT0("cc", "LayerTreeHostImpl::NotifyTileStateChanged"); if (active_tree_) { LayerImpl* layer_impl = active_tree_->FindActiveTreeLayerById(tile->layer_id()); if (layer_impl) layer_impl->NotifyTileStateChanged(tile); } if (pending_tree_) { LayerImpl* layer_impl = pending_tree_->FindPendingTreeLayerById(tile->layer_id()); if (layer_impl) layer_impl->NotifyTileStateChanged(tile); } // Check for a non-null active tree to avoid doing this during shutdown. if (active_tree_ && !client_->IsInsideDraw() && tile->required_for_draw()) { // The LayerImpl::NotifyTileStateChanged() should damage the layer, so this // redraw will make those tiles be displayed. SetNeedsRedraw(); } } void LayerTreeHostImpl::SetMemoryPolicy(const ManagedMemoryPolicy& policy) { SetManagedMemoryPolicy(policy, zero_budget_); } void LayerTreeHostImpl::SetTreeActivationCallback( const base::Closure& callback) { DCHECK(proxy_->IsImplThread()); DCHECK(settings_.impl_side_painting || callback.is_null()); tree_activation_callback_ = callback; } void LayerTreeHostImpl::SetManagedMemoryPolicy( const ManagedMemoryPolicy& policy, bool zero_budget) { if (cached_managed_memory_policy_ == policy && zero_budget_ == zero_budget) return; ManagedMemoryPolicy old_policy = ActualManagedMemoryPolicy(); cached_managed_memory_policy_ = policy; zero_budget_ = zero_budget; ManagedMemoryPolicy actual_policy = ActualManagedMemoryPolicy(); if (old_policy == actual_policy) return; if (!proxy_->HasImplThread()) { // In single-thread mode, this can be called on the main thread by // GLRenderer::OnMemoryAllocationChanged. DebugScopedSetImplThread impl_thread(proxy_); EnforceManagedMemoryPolicy(actual_policy); } else { DCHECK(proxy_->IsImplThread()); EnforceManagedMemoryPolicy(actual_policy); } // If there is already enough memory to draw everything imaginable and the // new memory limit does not change this, then do not re-commit. Don't bother // skipping commits if this is not visible (commits don't happen when not // visible, there will almost always be a commit when this becomes visible). bool needs_commit = true; if (visible() && actual_policy.bytes_limit_when_visible >= max_memory_needed_bytes_ && old_policy.bytes_limit_when_visible >= max_memory_needed_bytes_ && actual_policy.priority_cutoff_when_visible == old_policy.priority_cutoff_when_visible) { needs_commit = false; } if (needs_commit) client_->SetNeedsCommitOnImplThread(); } void LayerTreeHostImpl::SetExternalDrawConstraints( const gfx::Transform& transform, const gfx::Rect& viewport, const gfx::Rect& clip, const gfx::Rect& viewport_rect_for_tile_priority, const gfx::Transform& transform_for_tile_priority, bool resourceless_software_draw) { gfx::Rect viewport_rect_for_tile_priority_in_view_space; if (!resourceless_software_draw) { gfx::Transform screen_to_view(gfx::Transform::kSkipInitialization); if (transform_for_tile_priority.GetInverse(&screen_to_view)) { // Convert from screen space to view space. viewport_rect_for_tile_priority_in_view_space = gfx::ToEnclosingRect(MathUtil::ProjectClippedRect( screen_to_view, viewport_rect_for_tile_priority)); } } if (external_transform_ != transform || external_viewport_ != viewport || resourceless_software_draw_ != resourceless_software_draw || viewport_rect_for_tile_priority_ != viewport_rect_for_tile_priority_in_view_space) { active_tree_->set_needs_update_draw_properties(); } external_transform_ = transform; external_viewport_ = viewport; external_clip_ = clip; viewport_rect_for_tile_priority_ = viewport_rect_for_tile_priority_in_view_space; resourceless_software_draw_ = resourceless_software_draw; } void LayerTreeHostImpl::SetNeedsRedrawRect(const gfx::Rect& damage_rect) { if (damage_rect.IsEmpty()) return; NotifySwapPromiseMonitorsOfSetNeedsRedraw(); client_->SetNeedsRedrawRectOnImplThread(damage_rect); } void LayerTreeHostImpl::DidSwapBuffers() { client_->DidSwapBuffersOnImplThread(); } void LayerTreeHostImpl::DidSwapBuffersComplete() { client_->DidSwapBuffersCompleteOnImplThread(); } void LayerTreeHostImpl::ReclaimResources(const CompositorFrameAck* ack) { // TODO(piman): We may need to do some validation on this ack before // processing it. if (renderer_) renderer_->ReceiveSwapBuffersAck(*ack); // In OOM, we now might be able to release more resources that were held // because they were exported. if (tile_manager_) { DCHECK(resource_pool_); resource_pool_->CheckBusyResources(false); resource_pool_->ReduceResourceUsage(); } // If we're not visible, we likely released resources, so we want to // aggressively flush here to make sure those DeleteTextures make it to the // GPU process to free up the memory. if (output_surface_->context_provider() && !visible_) { output_surface_->context_provider()->ContextGL()->ShallowFlushCHROMIUM(); } } void LayerTreeHostImpl::OnCanDrawStateChangedForTree() { client_->OnCanDrawStateChanged(CanDraw()); } CompositorFrameMetadata LayerTreeHostImpl::MakeCompositorFrameMetadata() const { CompositorFrameMetadata metadata; metadata.device_scale_factor = device_scale_factor_; metadata.page_scale_factor = active_tree_->current_page_scale_factor(); metadata.scrollable_viewport_size = active_tree_->ScrollableViewportSize(); metadata.root_layer_size = active_tree_->ScrollableSize(); metadata.min_page_scale_factor = active_tree_->min_page_scale_factor(); metadata.max_page_scale_factor = active_tree_->max_page_scale_factor(); if (top_controls_manager_) { metadata.location_bar_offset = gfx::Vector2dF(0.f, top_controls_manager_->ControlsTopOffset()); metadata.location_bar_content_translation = gfx::Vector2dF(0.f, top_controls_manager_->ContentTopOffset()); } active_tree_->GetViewportSelection(&metadata.selection_start, &metadata.selection_end); LayerImpl* root_layer_for_overflow = OuterViewportScrollLayer() ? OuterViewportScrollLayer() : InnerViewportScrollLayer(); if (root_layer_for_overflow) { metadata.root_overflow_x_hidden = !root_layer_for_overflow->user_scrollable_horizontal(); metadata.root_overflow_y_hidden = !root_layer_for_overflow->user_scrollable_vertical(); } if (!InnerViewportScrollLayer()) return metadata; // TODO(miletus) : Change the metadata to hold ScrollOffset. metadata.root_scroll_offset = gfx::ScrollOffsetToVector2dF( active_tree_->TotalScrollOffset()); return metadata; } static void LayerTreeHostImplDidBeginTracingCallback(LayerImpl* layer) { layer->DidBeginTracing(); } void LayerTreeHostImpl::DrawLayers(FrameData* frame, base::TimeTicks frame_begin_time) { TRACE_EVENT0("cc", "LayerTreeHostImpl::DrawLayers"); DCHECK(CanDraw()); if (!frame->composite_events.empty()) { frame_timing_tracker_->SaveTimeStamps(frame_begin_time, frame->composite_events); } if (frame->has_no_damage) { TRACE_EVENT_INSTANT0("cc", "EarlyOut_NoDamage", TRACE_EVENT_SCOPE_THREAD); DCHECK(!output_surface_->capabilities() .draw_and_swap_full_viewport_every_frame); return; } DCHECK(!frame->render_passes.empty()); fps_counter_->SaveTimeStamp(frame_begin_time, !output_surface_->context_provider()); rendering_stats_instrumentation_->IncrementFrameCount(1); if (tile_manager_) { memory_history_->SaveEntry( tile_manager_->memory_stats_from_last_assign()); } if (debug_state_.ShowHudRects()) { debug_rect_history_->SaveDebugRectsForCurrentFrame( active_tree_->root_layer(), active_tree_->hud_layer(), *frame->render_surface_layer_list, debug_state_); } if (!settings_.impl_side_painting && debug_state_.continuous_painting) { const RenderingStats& stats = rendering_stats_instrumentation_->GetRenderingStats(); paint_time_counter_->SavePaintTime( stats.begin_main_frame_to_commit_duration.GetLastTimeDelta()); } bool is_new_trace; TRACE_EVENT_IS_NEW_TRACE(&is_new_trace); if (is_new_trace) { if (pending_tree_) { LayerTreeHostCommon::CallFunctionForSubtree( pending_tree_->root_layer(), base::Bind(&LayerTreeHostImplDidBeginTracingCallback)); } LayerTreeHostCommon::CallFunctionForSubtree( active_tree_->root_layer(), base::Bind(&LayerTreeHostImplDidBeginTracingCallback)); } { TRACE_EVENT0("cc", "DrawLayers.FrameViewerTracing"); TRACE_EVENT_OBJECT_SNAPSHOT_WITH_ID( TRACE_DISABLED_BY_DEFAULT("cc.debug") "," TRACE_DISABLED_BY_DEFAULT("cc.debug.quads") "," TRACE_DISABLED_BY_DEFAULT("devtools.timeline.layers"), "cc::LayerTreeHostImpl", id_, AsValueWithFrame(frame)); } const DrawMode draw_mode = GetDrawMode(); // Because the contents of the HUD depend on everything else in the frame, the // contents of its texture are updated as the last thing before the frame is // drawn. if (active_tree_->hud_layer()) { TRACE_EVENT0("cc", "DrawLayers.UpdateHudTexture"); active_tree_->hud_layer()->UpdateHudTexture(draw_mode, resource_provider_.get()); } if (draw_mode == DRAW_MODE_RESOURCELESS_SOFTWARE) { bool disable_picture_quad_image_filtering = IsActivelyScrolling() || needs_animate_layers(); scoped_ptr temp_software_renderer = SoftwareRenderer::Create(this, &settings_.renderer_settings, output_surface_.get(), NULL); temp_software_renderer->DrawFrame(&frame->render_passes, device_scale_factor_, DeviceViewport(), DeviceClip(), disable_picture_quad_image_filtering); } else { renderer_->DrawFrame(&frame->render_passes, device_scale_factor_, DeviceViewport(), DeviceClip(), false); } // The render passes should be consumed by the renderer. DCHECK(frame->render_passes.empty()); frame->render_passes_by_id.clear(); // The next frame should start by assuming nothing has changed, and changes // are noted as they occur. // TODO(boliu): If we did a temporary software renderer frame, propogate the // damage forward to the next frame. for (size_t i = 0; i < frame->render_surface_layer_list->size(); i++) { (*frame->render_surface_layer_list)[i]->render_surface()->damage_tracker()-> DidDrawDamagedArea(); } active_tree_->root_layer()->ResetAllChangeTrackingForSubtree(); active_tree_->set_has_ever_been_drawn(true); devtools_instrumentation::DidDrawFrame(id_); benchmark_instrumentation::IssueImplThreadRenderingStatsEvent( rendering_stats_instrumentation_->impl_thread_rendering_stats()); rendering_stats_instrumentation_->AccumulateAndClearImplThreadStats(); } void LayerTreeHostImpl::DidDrawAllLayers(const FrameData& frame) { for (size_t i = 0; i < frame.will_draw_layers.size(); ++i) frame.will_draw_layers[i]->DidDraw(resource_provider_.get()); // Once all layers have been drawn, pending texture uploads should no // longer block future uploads. resource_provider_->MarkPendingUploadsAsNonBlocking(); } void LayerTreeHostImpl::FinishAllRendering() { if (renderer_) renderer_->Finish(); } void LayerTreeHostImpl::SetUseGpuRasterization(bool use_gpu) { if (use_gpu == use_gpu_rasterization_) return; // Note that this must happen first, in case the rest of the calls want to // query the new state of |use_gpu_rasterization_|. use_gpu_rasterization_ = use_gpu; // Clean up and replace existing tile manager with another one that uses // appropriate rasterizer. ReleaseTreeResources(); if (tile_manager_) { DestroyTileManager(); CreateAndSetTileManager(); } RecreateTreeResources(); // We have released tilings for both active and pending tree. // We would not have any content to draw until the pending tree is activated. // Prevent the active tree from drawing until activation. SetRequiresHighResToDraw(); } const RendererCapabilitiesImpl& LayerTreeHostImpl::GetRendererCapabilities() const { return renderer_->Capabilities(); } bool LayerTreeHostImpl::SwapBuffers(const LayerTreeHostImpl::FrameData& frame) { ResetRequiresHighResToDraw(); if (frame.has_no_damage) { active_tree()->BreakSwapPromises(SwapPromise::SWAP_FAILS); return false; } CompositorFrameMetadata metadata = MakeCompositorFrameMetadata(); active_tree()->FinishSwapPromises(&metadata); for (auto& latency : metadata.latency_info) { TRACE_EVENT_FLOW_STEP0( "input,benchmark", "LatencyInfo.Flow", TRACE_ID_DONT_MANGLE(latency.trace_id), "SwapBuffers"); // Only add the latency component once for renderer swap, not the browser // swap. if (!latency.FindLatency(ui::INPUT_EVENT_LATENCY_RENDERER_SWAP_COMPONENT, 0, nullptr)) { latency.AddLatencyNumber(ui::INPUT_EVENT_LATENCY_RENDERER_SWAP_COMPONENT, 0, 0); } } renderer_->SwapBuffers(metadata); return true; } void LayerTreeHostImpl::WillBeginImplFrame(const BeginFrameArgs& args) { // Sample the frame time now. This time will be used for updating animations // when we draw. UpdateCurrentBeginFrameArgs(args); // Cache the begin impl frame interval begin_impl_frame_interval_ = args.interval; if (is_likely_to_require_a_draw_) { // Optimistically schedule a draw. This will let us expect the tile manager // to complete its work so that we can draw new tiles within the impl frame // we are beginning now. SetNeedsRedraw(); } } void LayerTreeHostImpl::UpdateViewportContainerSizes() { LayerImpl* inner_container = active_tree_->InnerViewportContainerLayer(); LayerImpl* outer_container = active_tree_->OuterViewportContainerLayer(); if (!inner_container || !top_controls_manager_) return; ViewportAnchor anchor(InnerViewportScrollLayer(), OuterViewportScrollLayer()); // Adjust the inner viewport by shrinking/expanding the container to account // for the change in top controls height since the last Resize from Blink. float top_controls_layout_height = active_tree_->top_controls_shrink_blink_size() ? active_tree_->top_controls_height() : 0.f; inner_container->SetBoundsDelta(gfx::Vector2dF( 0, top_controls_layout_height - top_controls_manager_->ContentTopOffset())); if (!outer_container || outer_container->BoundsForScrolling().IsEmpty()) return; // Adjust the outer viewport container as well, since adjusting only the // inner may cause its bounds to exceed those of the outer, causing scroll // clamping. We adjust it so it maintains the same aspect ratio as the // inner viewport. float aspect_ratio = inner_container->BoundsForScrolling().width() / inner_container->BoundsForScrolling().height(); float target_height = outer_container->BoundsForScrolling().width() / aspect_ratio; float current_outer_height = outer_container->BoundsForScrolling().height() - outer_container->bounds_delta().y(); gfx::Vector2dF delta(0, target_height - current_outer_height); outer_container->SetBoundsDelta(delta); active_tree_->InnerViewportScrollLayer()->SetBoundsDelta(delta); anchor.ResetViewportToAnchoredPosition(); } void LayerTreeHostImpl::SynchronouslyInitializeAllTiles() { // Only valid for the single-threaded non-scheduled/synchronous case // using the zero copy raster worker pool. single_thread_synchronous_task_graph_runner_->RunUntilIdle(); } void LayerTreeHostImpl::DidLoseOutputSurface() { if (resource_provider_) resource_provider_->DidLoseOutputSurface(); client_->DidLoseOutputSurfaceOnImplThread(); } bool LayerTreeHostImpl::HaveRootScrollLayer() const { return !!InnerViewportScrollLayer(); } LayerImpl* LayerTreeHostImpl::RootLayer() const { return active_tree_->root_layer(); } LayerImpl* LayerTreeHostImpl::InnerViewportScrollLayer() const { return active_tree_->InnerViewportScrollLayer(); } LayerImpl* LayerTreeHostImpl::OuterViewportScrollLayer() const { return active_tree_->OuterViewportScrollLayer(); } LayerImpl* LayerTreeHostImpl::CurrentlyScrollingLayer() const { return active_tree_->CurrentlyScrollingLayer(); } bool LayerTreeHostImpl::IsActivelyScrolling() const { return (did_lock_scrolling_layer_ && CurrentlyScrollingLayer()) || (InnerViewportScrollLayer() && InnerViewportScrollLayer()->IsExternalFlingActive()) || (OuterViewportScrollLayer() && OuterViewportScrollLayer()->IsExternalFlingActive()); } // Content layers can be either directly scrollable or contained in an outer // scrolling layer which applies the scroll transform. Given a content layer, // this function returns the associated scroll layer if any. static LayerImpl* FindScrollLayerForContentLayer(LayerImpl* layer_impl) { if (!layer_impl) return NULL; if (layer_impl->scrollable()) return layer_impl; if (layer_impl->DrawsContent() && layer_impl->parent() && layer_impl->parent()->scrollable()) return layer_impl->parent(); return NULL; } void LayerTreeHostImpl::CreatePendingTree() { CHECK(!pending_tree_); if (recycle_tree_) recycle_tree_.swap(pending_tree_); else pending_tree_ = LayerTreeImpl::create(this, active_tree()->page_scale_factor(), active_tree()->top_controls_shown_ratio(), active_tree()->elastic_overscroll()); client_->OnCanDrawStateChanged(CanDraw()); TRACE_EVENT_ASYNC_BEGIN0("cc", "PendingTree:waiting", pending_tree_.get()); } void LayerTreeHostImpl::ActivateSyncTree() { if (pending_tree_) { TRACE_EVENT_ASYNC_END0("cc", "PendingTree:waiting", pending_tree_.get()); active_tree_->SetRootLayerScrollOffsetDelegate(NULL); active_tree_->PushPersistedState(pending_tree_.get()); // Process any requests in the UI resource queue. The request queue is // given in LayerTreeHost::FinishCommitOnImplThread. This must take place // before the swap. pending_tree_->ProcessUIResourceRequestQueue(); if (pending_tree_->needs_full_tree_sync()) { active_tree_->SetRootLayer( TreeSynchronizer::SynchronizeTrees(pending_tree_->root_layer(), active_tree_->DetachLayerTree(), active_tree_.get())); } TreeSynchronizer::PushProperties(pending_tree_->root_layer(), active_tree_->root_layer()); pending_tree_->PushPropertiesTo(active_tree_.get()); // Now that we've synced everything from the pending tree to the active // tree, rename the pending tree the recycle tree so we can reuse it on the // next sync. DCHECK(!recycle_tree_); pending_tree_.swap(recycle_tree_); active_tree_->SetRootLayerScrollOffsetDelegate( root_layer_scroll_offset_delegate_); UpdateViewportContainerSizes(); } else { active_tree_->ProcessUIResourceRequestQueue(); } active_tree_->DidBecomeActive(); ActivateAnimations(); if (settings_.impl_side_painting) { client_->RenewTreePriority(); // If we have any picture layers, then by activating we also modified tile // priorities. if (!active_tree_->picture_layers().empty()) DidModifyTilePriorities(); } client_->OnCanDrawStateChanged(CanDraw()); client_->DidActivateSyncTree(); if (!tree_activation_callback_.is_null()) tree_activation_callback_.Run(); if (debug_state_.continuous_painting) { const RenderingStats& stats = rendering_stats_instrumentation_->GetRenderingStats(); // TODO(hendrikw): This requires a different metric when we commit directly // to the active tree. See crbug.com/429311. paint_time_counter_->SavePaintTime( stats.commit_to_activate_duration.GetLastTimeDelta() + stats.draw_duration.GetLastTimeDelta()); } scoped_ptr pending_page_scale_animation = active_tree_->TakePendingPageScaleAnimation(); if (pending_page_scale_animation) { StartPageScaleAnimation( pending_page_scale_animation->target_offset, pending_page_scale_animation->use_anchor, pending_page_scale_animation->scale, pending_page_scale_animation->duration); } } void LayerTreeHostImpl::SetVisible(bool visible) { DCHECK(proxy_->IsImplThread()); if (visible_ == visible) return; visible_ = visible; DidVisibilityChange(this, visible_); EnforceManagedMemoryPolicy(ActualManagedMemoryPolicy()); // If we just became visible, we have to ensure that we draw high res tiles, // to prevent checkerboard/low res flashes. if (visible_) SetRequiresHighResToDraw(); else EvictAllUIResources(); // Evict tiles immediately if invisible since this tab may never get another // draw or timer tick. if (!visible_) PrepareTiles(); if (!renderer_) return; renderer_->SetVisible(visible); } void LayerTreeHostImpl::SetNeedsAnimate() { NotifySwapPromiseMonitorsOfSetNeedsRedraw(); client_->SetNeedsAnimateOnImplThread(); } void LayerTreeHostImpl::SetNeedsRedraw() { NotifySwapPromiseMonitorsOfSetNeedsRedraw(); client_->SetNeedsRedrawOnImplThread(); } ManagedMemoryPolicy LayerTreeHostImpl::ActualManagedMemoryPolicy() const { ManagedMemoryPolicy actual = cached_managed_memory_policy_; if (debug_state_.rasterize_only_visible_content) { actual.priority_cutoff_when_visible = gpu::MemoryAllocation::CUTOFF_ALLOW_REQUIRED_ONLY; } else if (use_gpu_rasterization()) { actual.priority_cutoff_when_visible = gpu::MemoryAllocation::CUTOFF_ALLOW_NICE_TO_HAVE; } if (zero_budget_) { actual.bytes_limit_when_visible = 0; } return actual; } size_t LayerTreeHostImpl::memory_allocation_limit_bytes() const { return ActualManagedMemoryPolicy().bytes_limit_when_visible; } int LayerTreeHostImpl::memory_allocation_priority_cutoff() const { return ManagedMemoryPolicy::PriorityCutoffToValue( ActualManagedMemoryPolicy().priority_cutoff_when_visible); } void LayerTreeHostImpl::ReleaseTreeResources() { active_tree_->ReleaseResources(); if (pending_tree_) pending_tree_->ReleaseResources(); if (recycle_tree_) recycle_tree_->ReleaseResources(); EvictAllUIResources(); } void LayerTreeHostImpl::RecreateTreeResources() { active_tree_->RecreateResources(); if (pending_tree_) pending_tree_->RecreateResources(); if (recycle_tree_) recycle_tree_->RecreateResources(); } void LayerTreeHostImpl::CreateAndSetRenderer() { DCHECK(!renderer_); DCHECK(output_surface_); DCHECK(resource_provider_); if (output_surface_->capabilities().delegated_rendering) { renderer_ = DelegatingRenderer::Create(this, &settings_.renderer_settings, output_surface_.get(), resource_provider_.get()); } else if (output_surface_->context_provider()) { renderer_ = GLRenderer::Create( this, &settings_.renderer_settings, output_surface_.get(), resource_provider_.get(), texture_mailbox_deleter_.get(), settings_.renderer_settings.highp_threshold_min); } else if (output_surface_->software_device()) { renderer_ = SoftwareRenderer::Create(this, &settings_.renderer_settings, output_surface_.get(), resource_provider_.get()); } DCHECK(renderer_); renderer_->SetVisible(visible_); SetFullRootLayerDamage(); // See note in LayerTreeImpl::UpdateDrawProperties. Renderer needs to be // initialized to get max texture size. Also, after releasing resources, // trees need another update to generate new ones. active_tree_->set_needs_update_draw_properties(); if (pending_tree_) pending_tree_->set_needs_update_draw_properties(); client_->UpdateRendererCapabilitiesOnImplThread(); } void LayerTreeHostImpl::CreateAndSetTileManager() { DCHECK(!tile_manager_); DCHECK(settings_.impl_side_painting); DCHECK(output_surface_); DCHECK(resource_provider_); rasterizer_ = CreateRasterizer(); CreateResourceAndTileTaskWorkerPool(&tile_task_worker_pool_, &resource_pool_, &staging_resource_pool_); DCHECK(tile_task_worker_pool_); DCHECK(resource_pool_); base::SingleThreadTaskRunner* task_runner = proxy_->HasImplThread() ? proxy_->ImplThreadTaskRunner() : proxy_->MainThreadTaskRunner(); DCHECK(task_runner); size_t scheduled_raster_task_limit = IsSynchronousSingleThreaded() ? std::numeric_limits::max() : settings_.scheduled_raster_task_limit; tile_manager_ = TileManager::Create(this, task_runner, resource_pool_.get(), tile_task_worker_pool_->AsTileTaskRunner(), rasterizer_.get(), scheduled_raster_task_limit); UpdateTileManagerMemoryPolicy(ActualManagedMemoryPolicy()); } scoped_ptr LayerTreeHostImpl::CreateRasterizer() { ContextProvider* context_provider = output_surface_->context_provider(); if (use_gpu_rasterization_ && context_provider) { return GpuRasterizer::Create(context_provider, resource_provider_.get(), settings_.use_distance_field_text, settings_.threaded_gpu_rasterization_enabled, settings_.gpu_rasterization_msaa_sample_count); } return SoftwareRasterizer::Create(); } void LayerTreeHostImpl::CreateResourceAndTileTaskWorkerPool( scoped_ptr* tile_task_worker_pool, scoped_ptr* resource_pool, scoped_ptr* staging_resource_pool) { base::SingleThreadTaskRunner* task_runner = proxy_->HasImplThread() ? proxy_->ImplThreadTaskRunner() : proxy_->MainThreadTaskRunner(); DCHECK(task_runner); ContextProvider* context_provider = output_surface_->context_provider(); if (!context_provider) { *resource_pool = ResourcePool::Create(resource_provider_.get(), GL_TEXTURE_2D); *tile_task_worker_pool = BitmapTileTaskWorkerPool::Create( task_runner, TileTaskWorkerPool::GetTaskGraphRunner(), resource_provider_.get()); return; } if (use_gpu_rasterization_) { *resource_pool = ResourcePool::Create(resource_provider_.get(), GL_TEXTURE_2D); *tile_task_worker_pool = GpuTileTaskWorkerPool::Create( task_runner, TileTaskWorkerPool::GetTaskGraphRunner(), static_cast(rasterizer_.get())); return; } if (GetRendererCapabilities().using_image) { unsigned image_target = settings_.use_image_texture_target; DCHECK_IMPLIES( image_target == GL_TEXTURE_RECTANGLE_ARB, context_provider->ContextCapabilities().gpu.texture_rectangle); DCHECK_IMPLIES( image_target == GL_TEXTURE_EXTERNAL_OES, context_provider->ContextCapabilities().gpu.egl_image_external); if (settings_.use_zero_copy || IsSynchronousSingleThreaded()) { *resource_pool = ResourcePool::Create(resource_provider_.get(), image_target); TaskGraphRunner* task_graph_runner; if (IsSynchronousSingleThreaded()) { DCHECK(!single_thread_synchronous_task_graph_runner_); single_thread_synchronous_task_graph_runner_.reset(new TaskGraphRunner); task_graph_runner = single_thread_synchronous_task_graph_runner_.get(); } else { task_graph_runner = TileTaskWorkerPool::GetTaskGraphRunner(); } *tile_task_worker_pool = ZeroCopyTileTaskWorkerPool::Create( task_runner, task_graph_runner, resource_provider_.get()); return; } if (settings_.use_one_copy) { // We need to create a staging resource pool when using copy rasterizer. *staging_resource_pool = ResourcePool::Create(resource_provider_.get(), image_target); *resource_pool = ResourcePool::Create(resource_provider_.get(), GL_TEXTURE_2D); *tile_task_worker_pool = OneCopyTileTaskWorkerPool::Create( task_runner, TileTaskWorkerPool::GetTaskGraphRunner(), context_provider, resource_provider_.get(), staging_resource_pool_.get()); return; } } *resource_pool = ResourcePool::Create( resource_provider_.get(), GL_TEXTURE_2D); *tile_task_worker_pool = PixelBufferTileTaskWorkerPool::Create( task_runner, TileTaskWorkerPool::GetTaskGraphRunner(), context_provider, resource_provider_.get(), GetMaxTransferBufferUsageBytes(context_provider->ContextCapabilities(), settings_.renderer_settings.refresh_rate)); } void LayerTreeHostImpl::DestroyTileManager() { tile_manager_ = nullptr; resource_pool_ = nullptr; staging_resource_pool_ = nullptr; tile_task_worker_pool_ = nullptr; rasterizer_ = nullptr; single_thread_synchronous_task_graph_runner_ = nullptr; } bool LayerTreeHostImpl::IsSynchronousSingleThreaded() const { return !proxy_->HasImplThread() && !settings_.single_thread_proxy_scheduler; } void LayerTreeHostImpl::EnforceZeroBudget(bool zero_budget) { SetManagedMemoryPolicy(cached_managed_memory_policy_, zero_budget); } bool LayerTreeHostImpl::InitializeRenderer( scoped_ptr output_surface) { TRACE_EVENT0("cc", "LayerTreeHostImpl::InitializeRenderer"); // Since we will create a new resource provider, we cannot continue to use // the old resources (i.e. render_surfaces and texture IDs). Clear them // before we destroy the old resource provider. ReleaseTreeResources(); // Note: order is important here. renderer_ = nullptr; DestroyTileManager(); resource_provider_ = nullptr; output_surface_ = nullptr; if (!output_surface->BindToClient(this)) { // Avoid recreating tree resources because we might not have enough // information to do this yet (eg. we don't have a TileManager at this // point). return false; } output_surface_ = output_surface.Pass(); resource_provider_ = ResourceProvider::Create( output_surface_.get(), shared_bitmap_manager_, gpu_memory_buffer_manager_, proxy_->blocking_main_thread_task_runner(), settings_.renderer_settings.highp_threshold_min, settings_.renderer_settings.use_rgba_4444_textures, settings_.renderer_settings.texture_id_allocation_chunk_size); if (output_surface_->capabilities().deferred_gl_initialization) EnforceZeroBudget(true); CreateAndSetRenderer(); if (settings_.impl_side_painting) CreateAndSetTileManager(); RecreateTreeResources(); // Initialize vsync parameters to sane values. const base::TimeDelta display_refresh_interval = base::TimeDelta::FromMicroseconds( base::Time::kMicrosecondsPerSecond / settings_.renderer_settings.refresh_rate); CommitVSyncParameters(base::TimeTicks(), display_refresh_interval); // TODO(brianderson): Don't use a hard-coded parent draw time. base::TimeDelta parent_draw_time = (!settings_.use_external_begin_frame_source && output_surface_->capabilities().adjust_deadline_for_parent) ? BeginFrameArgs::DefaultEstimatedParentDrawTime() : base::TimeDelta(); client_->SetEstimatedParentDrawTime(parent_draw_time); int max_frames_pending = output_surface_->capabilities().max_frames_pending; if (max_frames_pending <= 0) max_frames_pending = OutputSurface::DEFAULT_MAX_FRAMES_PENDING; client_->SetMaxSwapsPendingOnImplThread(max_frames_pending); client_->OnCanDrawStateChanged(CanDraw()); // There will not be anything to draw here, so set high res // to avoid checkerboards, typically when we are recovering // from lost context. SetRequiresHighResToDraw(); return true; } void LayerTreeHostImpl::CommitVSyncParameters(base::TimeTicks timebase, base::TimeDelta interval) { client_->CommitVSyncParameters(timebase, interval); } void LayerTreeHostImpl::DeferredInitialize() { DCHECK(output_surface_->capabilities().deferred_gl_initialization); DCHECK(settings_.impl_side_painting); DCHECK(output_surface_->context_provider()); ReleaseTreeResources(); renderer_ = nullptr; DestroyTileManager(); resource_provider_->InitializeGL(); CreateAndSetRenderer(); EnforceZeroBudget(false); CreateAndSetTileManager(); RecreateTreeResources(); client_->SetNeedsCommitOnImplThread(); } void LayerTreeHostImpl::ReleaseGL() { DCHECK(output_surface_->capabilities().deferred_gl_initialization); DCHECK(settings_.impl_side_painting); DCHECK(output_surface_->context_provider()); ReleaseTreeResources(); renderer_ = nullptr; DestroyTileManager(); resource_provider_->InitializeSoftware(); output_surface_->ReleaseContextProvider(); CreateAndSetRenderer(); EnforceZeroBudget(true); CreateAndSetTileManager(); RecreateTreeResources(); client_->SetNeedsCommitOnImplThread(); } void LayerTreeHostImpl::SetViewportSize(const gfx::Size& device_viewport_size) { if (device_viewport_size == device_viewport_size_) return; TRACE_EVENT_INSTANT2("cc", "LayerTreeHostImpl::SetViewportSize", TRACE_EVENT_SCOPE_THREAD, "width", device_viewport_size.width(), "height", device_viewport_size.height()); if (pending_tree_) active_tree_->SetViewportSizeInvalid(); device_viewport_size_ = device_viewport_size; UpdateViewportContainerSizes(); client_->OnCanDrawStateChanged(CanDraw()); SetFullRootLayerDamage(); active_tree_->set_needs_update_draw_properties(); } void LayerTreeHostImpl::SetDeviceScaleFactor(float device_scale_factor) { if (device_scale_factor == device_scale_factor_) return; device_scale_factor_ = device_scale_factor; SetFullRootLayerDamage(); } void LayerTreeHostImpl::SetPageScaleOnActiveTree(float page_scale_factor) { active_tree_->SetPageScaleOnActiveTree(page_scale_factor); } const gfx::Rect LayerTreeHostImpl::ViewportRectForTilePriority() const { if (viewport_rect_for_tile_priority_.IsEmpty()) return DeviceViewport(); return viewport_rect_for_tile_priority_; } gfx::Size LayerTreeHostImpl::DrawViewportSize() const { return DeviceViewport().size(); } gfx::Rect LayerTreeHostImpl::DeviceViewport() const { if (external_viewport_.IsEmpty()) return gfx::Rect(device_viewport_size_); return external_viewport_; } gfx::Rect LayerTreeHostImpl::DeviceClip() const { if (external_clip_.IsEmpty()) return DeviceViewport(); return external_clip_; } const gfx::Transform& LayerTreeHostImpl::DrawTransform() const { return external_transform_; } void LayerTreeHostImpl::DidChangeTopControlsPosition() { UpdateViewportContainerSizes(); SetNeedsRedraw(); SetNeedsAnimate(); active_tree_->set_needs_update_draw_properties(); SetFullRootLayerDamage(); } float LayerTreeHostImpl::TopControlsHeight() const { return active_tree_->top_controls_height(); } void LayerTreeHostImpl::SetCurrentTopControlsShownRatio(float ratio) { if (active_tree_->SetCurrentTopControlsShownRatio(ratio)) DidChangeTopControlsPosition(); } float LayerTreeHostImpl::CurrentTopControlsShownRatio() const { return active_tree_->CurrentTopControlsShownRatio(); } void LayerTreeHostImpl::BindToClient(InputHandlerClient* client) { DCHECK(input_handler_client_ == NULL); input_handler_client_ = client; } LayerImpl* LayerTreeHostImpl::FindScrollLayerForDeviceViewportPoint( const gfx::PointF& device_viewport_point, InputHandler::ScrollInputType type, LayerImpl* layer_impl, bool* scroll_on_main_thread, bool* optional_has_ancestor_scroll_handler) const { DCHECK(scroll_on_main_thread); ScrollBlocksOn block_mode = EffectiveScrollBlocksOn(layer_impl); // Walk up the hierarchy and look for a scrollable layer. LayerImpl* potentially_scrolling_layer_impl = NULL; for (; layer_impl; layer_impl = NextScrollLayer(layer_impl)) { // The content layer can also block attempts to scroll outside the main // thread. ScrollStatus status = layer_impl->TryScroll(device_viewport_point, type, block_mode); if (status == SCROLL_ON_MAIN_THREAD) { *scroll_on_main_thread = true; return NULL; } LayerImpl* scroll_layer_impl = FindScrollLayerForContentLayer(layer_impl); if (!scroll_layer_impl) continue; status = scroll_layer_impl->TryScroll(device_viewport_point, type, block_mode); // If any layer wants to divert the scroll event to the main thread, abort. if (status == SCROLL_ON_MAIN_THREAD) { *scroll_on_main_thread = true; return NULL; } if (optional_has_ancestor_scroll_handler && scroll_layer_impl->have_scroll_event_handlers()) *optional_has_ancestor_scroll_handler = true; if (status == SCROLL_STARTED && !potentially_scrolling_layer_impl) potentially_scrolling_layer_impl = scroll_layer_impl; } // Falling back to the root scroll layer ensures generation of root overscroll // notifications while preventing scroll updates from being unintentionally // forwarded to the main thread. if (!potentially_scrolling_layer_impl) potentially_scrolling_layer_impl = OuterViewportScrollLayer() ? OuterViewportScrollLayer() : InnerViewportScrollLayer(); return potentially_scrolling_layer_impl; } // Similar to LayerImpl::HasAncestor, but walks up the scroll parents. static bool HasScrollAncestor(LayerImpl* child, LayerImpl* scroll_ancestor) { DCHECK(scroll_ancestor); for (LayerImpl* ancestor = child; ancestor; ancestor = NextScrollLayer(ancestor)) { if (ancestor->scrollable()) return ancestor == scroll_ancestor; } return false; } InputHandler::ScrollStatus LayerTreeHostImpl::ScrollBegin( const gfx::Point& viewport_point, InputHandler::ScrollInputType type) { TRACE_EVENT0("cc", "LayerTreeHostImpl::ScrollBegin"); if (top_controls_manager_) top_controls_manager_->ScrollBegin(); DCHECK(!CurrentlyScrollingLayer()); ClearCurrentlyScrollingLayer(); gfx::PointF device_viewport_point = gfx::ScalePoint(viewport_point, device_scale_factor_); LayerImpl* layer_impl = active_tree_->FindLayerThatIsHitByPoint(device_viewport_point); if (layer_impl) { LayerImpl* scroll_layer_impl = active_tree_->FindFirstScrollingLayerThatIsHitByPoint( device_viewport_point); if (scroll_layer_impl && !HasScrollAncestor(layer_impl, scroll_layer_impl)) return SCROLL_UNKNOWN; } bool scroll_on_main_thread = false; LayerImpl* scrolling_layer_impl = FindScrollLayerForDeviceViewportPoint(device_viewport_point, type, layer_impl, &scroll_on_main_thread, &scroll_affects_scroll_handler_); if (scroll_on_main_thread) { UMA_HISTOGRAM_BOOLEAN("TryScroll.SlowScroll", true); return SCROLL_ON_MAIN_THREAD; } if (scrolling_layer_impl) { active_tree_->SetCurrentlyScrollingLayer(scrolling_layer_impl); should_bubble_scrolls_ = (type != NON_BUBBLING_GESTURE); wheel_scrolling_ = (type == WHEEL); client_->RenewTreePriority(); UMA_HISTOGRAM_BOOLEAN("TryScroll.SlowScroll", false); return SCROLL_STARTED; } return SCROLL_IGNORED; } InputHandler::ScrollStatus LayerTreeHostImpl::ScrollAnimated( const gfx::Point& viewport_point, const gfx::Vector2dF& scroll_delta) { if (LayerImpl* layer_impl = CurrentlyScrollingLayer()) { Animation* animation = layer_impl->layer_animation_controller()->GetAnimation( Animation::SCROLL_OFFSET); if (!animation) return SCROLL_IGNORED; ScrollOffsetAnimationCurve* curve = animation->curve()->ToScrollOffsetAnimationCurve(); gfx::ScrollOffset new_target = gfx::ScrollOffsetWithDelta(curve->target_value(), scroll_delta); new_target.SetToMax(gfx::ScrollOffset()); new_target.SetToMin(layer_impl->MaxScrollOffset()); curve->UpdateTarget( animation->TrimTimeToCurrentIteration( CurrentBeginFrameArgs().frame_time).InSecondsF(), new_target); return SCROLL_STARTED; } // ScrollAnimated is only used for wheel scrolls. We use the same bubbling // behavior as ScrollBy to determine which layer to animate, but we do not // do the Android-specific things in ScrollBy like showing top controls. InputHandler::ScrollStatus scroll_status = ScrollBegin(viewport_point, WHEEL); if (scroll_status == SCROLL_STARTED) { gfx::Vector2dF pending_delta = scroll_delta; for (LayerImpl* layer_impl = CurrentlyScrollingLayer(); layer_impl; layer_impl = layer_impl->parent()) { if (!layer_impl->scrollable()) continue; gfx::ScrollOffset current_offset = layer_impl->CurrentScrollOffset(); gfx::ScrollOffset target_offset = ScrollOffsetWithDelta(current_offset, pending_delta); target_offset.SetToMax(gfx::ScrollOffset()); target_offset.SetToMin(layer_impl->MaxScrollOffset()); gfx::Vector2dF actual_delta = target_offset.DeltaFrom(current_offset); const float kEpsilon = 0.1f; bool can_layer_scroll = (std::abs(actual_delta.x()) > kEpsilon || std::abs(actual_delta.y()) > kEpsilon); if (!can_layer_scroll) { layer_impl->ScrollBy(actual_delta); pending_delta -= actual_delta; continue; } active_tree_->SetCurrentlyScrollingLayer(layer_impl); scoped_ptr curve = ScrollOffsetAnimationCurve::Create(target_offset, EaseInOutTimingFunction::Create()); curve->SetInitialValue(current_offset); scoped_ptr animation = Animation::Create( curve.Pass(), AnimationIdProvider::NextAnimationId(), AnimationIdProvider::NextGroupId(), Animation::SCROLL_OFFSET); animation->set_is_impl_only(true); layer_impl->layer_animation_controller()->AddAnimation(animation.Pass()); SetNeedsAnimate(); return SCROLL_STARTED; } } ScrollEnd(); return scroll_status; } gfx::Vector2dF LayerTreeHostImpl::ScrollLayerWithViewportSpaceDelta( LayerImpl* layer_impl, float scale_from_viewport_to_screen_space, const gfx::PointF& viewport_point, const gfx::Vector2dF& viewport_delta) { // Layers with non-invertible screen space transforms should not have passed // the scroll hit test in the first place. DCHECK(layer_impl->screen_space_transform().IsInvertible()); gfx::Transform inverse_screen_space_transform( gfx::Transform::kSkipInitialization); bool did_invert = layer_impl->screen_space_transform().GetInverse( &inverse_screen_space_transform); // TODO(shawnsingh): With the advent of impl-side crolling for non-root // layers, we may need to explicitly handle uninvertible transforms here. DCHECK(did_invert); gfx::PointF screen_space_point = gfx::ScalePoint(viewport_point, scale_from_viewport_to_screen_space); gfx::Vector2dF screen_space_delta = viewport_delta; screen_space_delta.Scale(scale_from_viewport_to_screen_space); // First project the scroll start and end points to local layer space to find // the scroll delta in layer coordinates. bool start_clipped, end_clipped; gfx::PointF screen_space_end_point = screen_space_point + screen_space_delta; gfx::PointF local_start_point = MathUtil::ProjectPoint(inverse_screen_space_transform, screen_space_point, &start_clipped); gfx::PointF local_end_point = MathUtil::ProjectPoint(inverse_screen_space_transform, screen_space_end_point, &end_clipped); // In general scroll point coordinates should not get clipped. DCHECK(!start_clipped); DCHECK(!end_clipped); if (start_clipped || end_clipped) return gfx::Vector2dF(); // local_start_point and local_end_point are in content space but we want to // move them to layer space for scrolling. float width_scale = 1.f / layer_impl->contents_scale_x(); float height_scale = 1.f / layer_impl->contents_scale_y(); local_start_point.Scale(width_scale, height_scale); local_end_point.Scale(width_scale, height_scale); // Apply the scroll delta. gfx::ScrollOffset previous_offset = layer_impl->CurrentScrollOffset(); layer_impl->ScrollBy(local_end_point - local_start_point); gfx::ScrollOffset scrolled = layer_impl->CurrentScrollOffset() - previous_offset; // Get the end point in the layer's content space so we can apply its // ScreenSpaceTransform. gfx::PointF actual_local_end_point = local_start_point + gfx::Vector2dF(scrolled.x(), scrolled.y()); gfx::PointF actual_local_content_end_point = gfx::ScalePoint(actual_local_end_point, 1.f / width_scale, 1.f / height_scale); // Calculate the applied scroll delta in viewport space coordinates. gfx::PointF actual_screen_space_end_point = MathUtil::MapPoint(layer_impl->screen_space_transform(), actual_local_content_end_point, &end_clipped); DCHECK(!end_clipped); if (end_clipped) return gfx::Vector2dF(); gfx::PointF actual_viewport_end_point = gfx::ScalePoint(actual_screen_space_end_point, 1.f / scale_from_viewport_to_screen_space); return actual_viewport_end_point - viewport_point; } static gfx::Vector2dF ScrollLayerWithLocalDelta( LayerImpl* layer_impl, const gfx::Vector2dF& local_delta, float page_scale_factor) { gfx::ScrollOffset previous_offset = layer_impl->CurrentScrollOffset(); gfx::Vector2dF delta = local_delta; delta.Scale(1.f / page_scale_factor); layer_impl->ScrollBy(delta); gfx::ScrollOffset scrolled = layer_impl->CurrentScrollOffset() - previous_offset; return gfx::Vector2dF(scrolled.x(), scrolled.y()); } bool LayerTreeHostImpl::ShouldTopControlsConsumeScroll( const gfx::Vector2dF& scroll_delta) const { DCHECK(CurrentlyScrollingLayer()); if (!top_controls_manager_) return false; // Always consume if it's in the direction to show the top controls. if (scroll_delta.y() < 0) return true; if (active_tree()->TotalScrollOffset().y() < active_tree()->TotalMaxScrollOffset().y()) return true; return false; } InputHandlerScrollResult LayerTreeHostImpl::ScrollBy( const gfx::Point& viewport_point, const gfx::Vector2dF& scroll_delta) { TRACE_EVENT0("cc", "LayerTreeHostImpl::ScrollBy"); if (!CurrentlyScrollingLayer()) return InputHandlerScrollResult(); gfx::Vector2dF pending_delta = scroll_delta; gfx::Vector2dF unused_root_delta; bool did_scroll_x = false; bool did_scroll_y = false; bool did_scroll_top_controls = false; bool consume_by_top_controls = ShouldTopControlsConsumeScroll(scroll_delta); // There's an edge case where the outer viewport isn't scrollable when the // scroll starts, however, as the top controls show the outer viewport becomes // scrollable. Therefore, always try scrolling the outer viewport before the // inner. // TODO(bokan): Move the top controls logic out of the loop since the scroll // that causes the outer viewport to become scrollable will still be applied // to the inner viewport. LayerImpl* start_layer = CurrentlyScrollingLayer(); if (start_layer == InnerViewportScrollLayer() && OuterViewportScrollLayer()) start_layer = OuterViewportScrollLayer(); for (LayerImpl* layer_impl = start_layer; layer_impl; layer_impl = layer_impl->parent()) { if (!layer_impl->scrollable()) continue; if (layer_impl == InnerViewportScrollLayer() || layer_impl == OuterViewportScrollLayer()) { if (consume_by_top_controls) { gfx::Vector2dF excess_delta = top_controls_manager_->ScrollBy(pending_delta); gfx::Vector2dF applied_delta = pending_delta - excess_delta; pending_delta = excess_delta; // Force updating of vertical adjust values if needed. if (applied_delta.y() != 0) did_scroll_top_controls = true; } // Track root layer deltas for reporting overscroll. if (layer_impl == InnerViewportScrollLayer()) unused_root_delta = pending_delta; } gfx::Vector2dF applied_delta; // Gesture events need to be transformed from viewport coordinates to local // layer coordinates so that the scrolling contents exactly follow the // user's finger. In contrast, wheel events represent a fixed amount of // scrolling so we can just apply them directly, but the page scale factor // is applied to the scroll delta. if (!wheel_scrolling_) { float scale_from_viewport_to_screen_space = device_scale_factor_; applied_delta = ScrollLayerWithViewportSpaceDelta(layer_impl, scale_from_viewport_to_screen_space, viewport_point, pending_delta); } else { applied_delta = ScrollLayerWithLocalDelta( layer_impl, pending_delta, active_tree_->current_page_scale_factor()); } const float kEpsilon = 0.1f; if (layer_impl == InnerViewportScrollLayer()) { unused_root_delta.Subtract(applied_delta); if (std::abs(unused_root_delta.x()) < kEpsilon) unused_root_delta.set_x(0.0f); if (std::abs(unused_root_delta.y()) < kEpsilon) unused_root_delta.set_y(0.0f); // Disable overscroll on axes which is impossible to scroll. if (settings_.report_overscroll_only_for_scrollable_axes) { if (std::abs(active_tree_->TotalMaxScrollOffset().x()) <= kEpsilon || !layer_impl->user_scrollable_horizontal()) unused_root_delta.set_x(0.0f); if (std::abs(active_tree_->TotalMaxScrollOffset().y()) <= kEpsilon || !layer_impl->user_scrollable_vertical()) unused_root_delta.set_y(0.0f); } } // Scrolls should bubble perfectly between the outer and inner viewports. bool allow_unrestricted_bubbling_for_current_layer = layer_impl == OuterViewportScrollLayer(); bool allow_bubbling_for_current_layer = allow_unrestricted_bubbling_for_current_layer || should_bubble_scrolls_; // If the layer wasn't able to move, try the next one in the hierarchy. bool did_move_layer_x = std::abs(applied_delta.x()) > kEpsilon; bool did_move_layer_y = std::abs(applied_delta.y()) > kEpsilon; did_scroll_x |= did_move_layer_x; did_scroll_y |= did_move_layer_y; if (!did_move_layer_x && !did_move_layer_y) { if (allow_bubbling_for_current_layer || !did_lock_scrolling_layer_) continue; else break; } did_lock_scrolling_layer_ = true; // When scrolls are allowed to bubble, it's important that the original // scrolling layer be preserved. This ensures that, after a scroll bubbles, // the user can reverse scroll directions and immediately resume scrolling // the original layer that scrolled. if (!should_bubble_scrolls_) active_tree_->SetCurrentlyScrollingLayer(layer_impl); if (!allow_bubbling_for_current_layer) break; if (allow_unrestricted_bubbling_for_current_layer) { pending_delta -= applied_delta; } else { // If the applied delta is within 45 degrees of the input delta, bail out // to make it easier to scroll just one layer in one direction without // affecting any of its parents. float angle_threshold = 45; if (MathUtil::SmallestAngleBetweenVectors(applied_delta, pending_delta) < angle_threshold) { pending_delta = gfx::Vector2dF(); break; } // Allow further movement only on an axis perpendicular to the direction // in which the layer moved. gfx::Vector2dF perpendicular_axis(-applied_delta.y(), applied_delta.x()); pending_delta = MathUtil::ProjectVector(pending_delta, perpendicular_axis); } if (gfx::ToRoundedVector2d(pending_delta).IsZero()) break; } bool did_scroll_content = did_scroll_x || did_scroll_y; if (did_scroll_content) { // If we are scrolling with an active scroll handler, forward latency // tracking information to the main thread so the delay introduced by the // handler is accounted for. if (scroll_affects_scroll_handler()) NotifySwapPromiseMonitorsOfForwardingToMainThread(); client_->SetNeedsCommitOnImplThread(); SetNeedsRedraw(); client_->RenewTreePriority(); } // Scrolling along an axis resets accumulated root overscroll for that axis. if (did_scroll_x) accumulated_root_overscroll_.set_x(0); if (did_scroll_y) accumulated_root_overscroll_.set_y(0); accumulated_root_overscroll_ += unused_root_delta; InputHandlerScrollResult scroll_result; scroll_result.did_scroll = did_scroll_content || did_scroll_top_controls; scroll_result.did_overscroll_root = !unused_root_delta.IsZero(); scroll_result.accumulated_root_overscroll = accumulated_root_overscroll_; scroll_result.unused_scroll_delta = unused_root_delta; return scroll_result; } // This implements scrolling by page as described here: // http://msdn.microsoft.com/en-us/library/windows/desktop/ms645601(v=vs.85).aspx#_win32_The_Mouse_Wheel // for events with WHEEL_PAGESCROLL set. bool LayerTreeHostImpl::ScrollVerticallyByPage(const gfx::Point& viewport_point, ScrollDirection direction) { DCHECK(wheel_scrolling_); for (LayerImpl* layer_impl = CurrentlyScrollingLayer(); layer_impl; layer_impl = layer_impl->parent()) { if (!layer_impl->scrollable()) continue; if (!layer_impl->HasScrollbar(VERTICAL)) continue; float height = layer_impl->clip_height(); // These magical values match WebKit and are designed to scroll nearly the // entire visible content height but leave a bit of overlap. float page = std::max(height * 0.875f, 1.f); if (direction == SCROLL_BACKWARD) page = -page; gfx::Vector2dF delta = gfx::Vector2dF(0.f, page); gfx::Vector2dF applied_delta = ScrollLayerWithLocalDelta(layer_impl, delta, 1.f); if (!applied_delta.IsZero()) { client_->SetNeedsCommitOnImplThread(); SetNeedsRedraw(); client_->RenewTreePriority(); return true; } active_tree_->SetCurrentlyScrollingLayer(layer_impl); } return false; } void LayerTreeHostImpl::SetRootLayerScrollOffsetDelegate( LayerScrollOffsetDelegate* root_layer_scroll_offset_delegate) { root_layer_scroll_offset_delegate_ = root_layer_scroll_offset_delegate; active_tree_->SetRootLayerScrollOffsetDelegate( root_layer_scroll_offset_delegate_); } void LayerTreeHostImpl::OnRootLayerDelegatedScrollOffsetChanged() { DCHECK(root_layer_scroll_offset_delegate_); client_->SetNeedsCommitOnImplThread(); SetNeedsRedraw(); active_tree_->OnRootLayerDelegatedScrollOffsetChanged(); active_tree_->set_needs_update_draw_properties(); } void LayerTreeHostImpl::ClearCurrentlyScrollingLayer() { active_tree_->ClearCurrentlyScrollingLayer(); did_lock_scrolling_layer_ = false; scroll_affects_scroll_handler_ = false; accumulated_root_overscroll_ = gfx::Vector2dF(); } void LayerTreeHostImpl::ScrollEnd() { if (top_controls_manager_) top_controls_manager_->ScrollEnd(); ClearCurrentlyScrollingLayer(); } InputHandler::ScrollStatus LayerTreeHostImpl::FlingScrollBegin() { if (!active_tree_->CurrentlyScrollingLayer()) return SCROLL_IGNORED; if (settings_.ignore_root_layer_flings && (active_tree_->CurrentlyScrollingLayer() == InnerViewportScrollLayer() || active_tree_->CurrentlyScrollingLayer() == OuterViewportScrollLayer())) { ClearCurrentlyScrollingLayer(); return SCROLL_IGNORED; } if (!wheel_scrolling_) { // Allow the fling to lock to the first layer that moves after the initial // fling |ScrollBy()| event. did_lock_scrolling_layer_ = false; should_bubble_scrolls_ = false; } return SCROLL_STARTED; } float LayerTreeHostImpl::DeviceSpaceDistanceToLayer( const gfx::PointF& device_viewport_point, LayerImpl* layer_impl) { if (!layer_impl) return std::numeric_limits::max(); gfx::Rect layer_impl_bounds( layer_impl->content_bounds()); gfx::RectF device_viewport_layer_impl_bounds = MathUtil::MapClippedRect( layer_impl->screen_space_transform(), layer_impl_bounds); return device_viewport_layer_impl_bounds.ManhattanDistanceToPoint( device_viewport_point); } void LayerTreeHostImpl::MouseMoveAt(const gfx::Point& viewport_point) { gfx::PointF device_viewport_point = gfx::ScalePoint(viewport_point, device_scale_factor_); LayerImpl* layer_impl = active_tree_->FindLayerThatIsHitByPoint(device_viewport_point); if (HandleMouseOverScrollbar(layer_impl, device_viewport_point)) return; if (scroll_layer_id_when_mouse_over_scrollbar_) { LayerImpl* scroll_layer_impl = active_tree_->LayerById( scroll_layer_id_when_mouse_over_scrollbar_); // The check for a null scroll_layer_impl below was added to see if it will // eliminate the crashes described in http://crbug.com/326635. // TODO(wjmaclean) Add a unit test if this fixes the crashes. ScrollbarAnimationController* animation_controller = scroll_layer_impl ? scroll_layer_impl->scrollbar_animation_controller() : NULL; if (animation_controller) animation_controller->DidMouseMoveOffScrollbar(); scroll_layer_id_when_mouse_over_scrollbar_ = 0; } bool scroll_on_main_thread = false; LayerImpl* scroll_layer_impl = FindScrollLayerForDeviceViewportPoint( device_viewport_point, InputHandler::GESTURE, layer_impl, &scroll_on_main_thread, NULL); if (scroll_on_main_thread || !scroll_layer_impl) return; ScrollbarAnimationController* animation_controller = scroll_layer_impl->scrollbar_animation_controller(); if (!animation_controller) return; // TODO(wjmaclean) Is it ok to choose distance from more than two scrollbars? float distance_to_scrollbar = std::numeric_limits::max(); for (LayerImpl::ScrollbarSet::iterator it = scroll_layer_impl->scrollbars()->begin(); it != scroll_layer_impl->scrollbars()->end(); ++it) distance_to_scrollbar = std::min(distance_to_scrollbar, DeviceSpaceDistanceToLayer(device_viewport_point, *it)); animation_controller->DidMouseMoveNear(distance_to_scrollbar / device_scale_factor_); } bool LayerTreeHostImpl::HandleMouseOverScrollbar(LayerImpl* layer_impl, const gfx::PointF& device_viewport_point) { if (layer_impl && layer_impl->ToScrollbarLayer()) { int scroll_layer_id = layer_impl->ToScrollbarLayer()->ScrollLayerId(); layer_impl = active_tree_->LayerById(scroll_layer_id); if (layer_impl && layer_impl->scrollbar_animation_controller()) { scroll_layer_id_when_mouse_over_scrollbar_ = scroll_layer_id; layer_impl->scrollbar_animation_controller()->DidMouseMoveNear(0); } else { scroll_layer_id_when_mouse_over_scrollbar_ = 0; } return true; } return false; } void LayerTreeHostImpl::PinchGestureBegin() { pinch_gesture_active_ = true; previous_pinch_anchor_ = gfx::Point(); client_->RenewTreePriority(); pinch_gesture_end_should_clear_scrolling_layer_ = !CurrentlyScrollingLayer(); if (active_tree_->OuterViewportScrollLayer()) { active_tree_->SetCurrentlyScrollingLayer( active_tree_->OuterViewportScrollLayer()); } else { active_tree_->SetCurrentlyScrollingLayer( active_tree_->InnerViewportScrollLayer()); } if (top_controls_manager_) top_controls_manager_->PinchBegin(); } void LayerTreeHostImpl::PinchGestureUpdate(float magnify_delta, const gfx::Point& anchor) { if (!InnerViewportScrollLayer()) return; TRACE_EVENT0("cc", "LayerTreeHostImpl::PinchGestureUpdate"); // For a moment the scroll offset ends up being outside of the max range. This // confuses the delegate so we switch it off till after we're done processing // the pinch update. active_tree_->SetRootLayerScrollOffsetDelegate(NULL); // Keep the center-of-pinch anchor specified by (x, y) in a stable // position over the course of the magnify. float page_scale = active_tree_->current_page_scale_factor(); gfx::PointF previous_scale_anchor = gfx::ScalePoint(anchor, 1.f / page_scale); active_tree_->SetPageScaleOnActiveTree(page_scale * magnify_delta); page_scale = active_tree_->current_page_scale_factor(); gfx::PointF new_scale_anchor = gfx::ScalePoint(anchor, 1.f / page_scale); gfx::Vector2dF move = previous_scale_anchor - new_scale_anchor; previous_pinch_anchor_ = anchor; // If clamping the inner viewport scroll offset causes a change, it should // be accounted for from the intended move. move -= InnerViewportScrollLayer()->ClampScrollToMaxScrollOffset(); // We manually manage the bubbling behaviour here as it is different to that // implemented in LayerTreeHostImpl::ScrollBy(). Specifically: // 1) we want to explicit limit the bubbling to the outer/inner viewports, // 2) we don't want the directional limitations on the unused parts that // ScrollBy() implements, and // 3) pinching should not engage the top controls manager. gfx::Vector2dF unused = OuterViewportScrollLayer() ? OuterViewportScrollLayer()->ScrollBy(move) : move; if (!unused.IsZero()) { InnerViewportScrollLayer()->ScrollBy(unused); InnerViewportScrollLayer()->ClampScrollToMaxScrollOffset(); } active_tree_->SetRootLayerScrollOffsetDelegate( root_layer_scroll_offset_delegate_); client_->SetNeedsCommitOnImplThread(); SetNeedsRedraw(); client_->RenewTreePriority(); } void LayerTreeHostImpl::PinchGestureEnd() { pinch_gesture_active_ = false; if (pinch_gesture_end_should_clear_scrolling_layer_) { pinch_gesture_end_should_clear_scrolling_layer_ = false; ClearCurrentlyScrollingLayer(); } if (top_controls_manager_) top_controls_manager_->PinchEnd(); client_->SetNeedsCommitOnImplThread(); // When a pinch ends, we may be displaying content cached at incorrect scales, // so updating draw properties and drawing will ensure we are using the right // scales that we want when we're not inside a pinch. active_tree_->set_needs_update_draw_properties(); SetNeedsRedraw(); } static void CollectScrollDeltas(ScrollAndScaleSet* scroll_info, LayerImpl* layer_impl) { if (!layer_impl) return; gfx::ScrollOffset scroll_delta = layer_impl->PullDeltaForMainThread(); if (!scroll_delta.IsZero()) { LayerTreeHostCommon::ScrollUpdateInfo scroll; scroll.layer_id = layer_impl->id(); scroll.scroll_delta = gfx::Vector2dF(scroll_delta.x(), scroll_delta.y()); scroll_info->scrolls.push_back(scroll); } for (size_t i = 0; i < layer_impl->children().size(); ++i) CollectScrollDeltas(scroll_info, layer_impl->children()[i]); } scoped_ptr LayerTreeHostImpl::ProcessScrollDeltas() { scoped_ptr scroll_info(new ScrollAndScaleSet()); CollectScrollDeltas(scroll_info.get(), active_tree_->root_layer()); scroll_info->page_scale_delta = active_tree_->page_scale_factor()->PullDeltaForMainThread(); scroll_info->top_controls_delta = active_tree()->top_controls_shown_ratio()->PullDeltaForMainThread(); scroll_info->elastic_overscroll_delta = active_tree_->elastic_overscroll()->PullDeltaForMainThread(); scroll_info->swap_promises.swap(swap_promises_for_main_thread_scroll_update_); return scroll_info.Pass(); } void LayerTreeHostImpl::SetFullRootLayerDamage() { SetViewportDamage(gfx::Rect(DrawViewportSize())); } void LayerTreeHostImpl::ScrollViewportInnerFirst(gfx::Vector2dF scroll_delta) { DCHECK(InnerViewportScrollLayer()); LayerImpl* scroll_layer = InnerViewportScrollLayer(); gfx::Vector2dF unused_delta = scroll_layer->ScrollBy(scroll_delta); if (!unused_delta.IsZero() && OuterViewportScrollLayer()) OuterViewportScrollLayer()->ScrollBy(unused_delta); } void LayerTreeHostImpl::ScrollViewportBy(gfx::Vector2dF scroll_delta) { DCHECK(InnerViewportScrollLayer()); LayerImpl* scroll_layer = OuterViewportScrollLayer() ? OuterViewportScrollLayer() : InnerViewportScrollLayer(); gfx::Vector2dF unused_delta = scroll_layer->ScrollBy(scroll_delta); if (!unused_delta.IsZero() && (scroll_layer == OuterViewportScrollLayer())) InnerViewportScrollLayer()->ScrollBy(unused_delta); } void LayerTreeHostImpl::AnimatePageScale(base::TimeTicks monotonic_time) { if (!page_scale_animation_) return; gfx::ScrollOffset scroll_total = active_tree_->TotalScrollOffset(); if (!page_scale_animation_->IsAnimationStarted()) page_scale_animation_->StartAnimation(monotonic_time); active_tree_->SetPageScaleOnActiveTree( page_scale_animation_->PageScaleFactorAtTime(monotonic_time)); gfx::ScrollOffset next_scroll = gfx::ScrollOffset( page_scale_animation_->ScrollOffsetAtTime(monotonic_time)); ScrollViewportInnerFirst(next_scroll.DeltaFrom(scroll_total)); SetNeedsRedraw(); if (page_scale_animation_->IsAnimationCompleteAtTime(monotonic_time)) { page_scale_animation_ = nullptr; client_->SetNeedsCommitOnImplThread(); client_->RenewTreePriority(); client_->DidCompletePageScaleAnimationOnImplThread(); } else { SetNeedsAnimate(); } } void LayerTreeHostImpl::AnimateTopControls(base::TimeTicks time) { if (!top_controls_manager_ || !top_controls_manager_->animation()) return; gfx::Vector2dF scroll = top_controls_manager_->Animate(time); if (top_controls_manager_->animation()) SetNeedsAnimate(); if (active_tree_->TotalScrollOffset().y() == 0.f) return; if (scroll.IsZero()) return; ScrollViewportBy(gfx::ScaleVector2d( scroll, 1.f / active_tree_->current_page_scale_factor())); SetNeedsRedraw(); client_->SetNeedsCommitOnImplThread(); client_->RenewTreePriority(); } void LayerTreeHostImpl::AnimateLayers(base::TimeTicks monotonic_time) { if (!settings_.accelerated_animation_enabled || !needs_animate_layers() || !active_tree_->root_layer()) return; TRACE_EVENT0("cc", "LayerTreeHostImpl::AnimateLayers"); AnimationRegistrar::AnimationControllerMap copy = animation_registrar_->active_animation_controllers(); for (AnimationRegistrar::AnimationControllerMap::iterator iter = copy.begin(); iter != copy.end(); ++iter) (*iter).second->Animate(monotonic_time); SetNeedsAnimate(); } void LayerTreeHostImpl::UpdateAnimationState(bool start_ready_animations) { if (!settings_.accelerated_animation_enabled || !needs_animate_layers() || !active_tree_->root_layer()) return; TRACE_EVENT0("cc", "LayerTreeHostImpl::UpdateAnimationState"); scoped_ptr events = make_scoped_ptr(new AnimationEventsVector); AnimationRegistrar::AnimationControllerMap copy = animation_registrar_->active_animation_controllers(); for (AnimationRegistrar::AnimationControllerMap::iterator iter = copy.begin(); iter != copy.end(); ++iter) (*iter).second->UpdateState(start_ready_animations, events.get()); if (!events->empty()) { client_->PostAnimationEventsToMainThreadOnImplThread(events.Pass()); } SetNeedsAnimate(); } void LayerTreeHostImpl::ActivateAnimations() { if (!settings_.accelerated_animation_enabled || !needs_animate_layers() || !active_tree_->root_layer()) return; TRACE_EVENT0("cc", "LayerTreeHostImpl::ActivateAnimations"); AnimationRegistrar::AnimationControllerMap copy = animation_registrar_->active_animation_controllers(); for (AnimationRegistrar::AnimationControllerMap::iterator iter = copy.begin(); iter != copy.end(); ++iter) (*iter).second->ActivateAnimations(); SetNeedsAnimate(); } std::string LayerTreeHostImpl::LayerTreeAsJson() const { std::string str; if (active_tree_->root_layer()) { scoped_ptr json(active_tree_->root_layer()->LayerTreeAsJson()); base::JSONWriter::WriteWithOptions( json.get(), base::JSONWriter::OPTIONS_PRETTY_PRINT, &str); } return str; } int LayerTreeHostImpl::SourceAnimationFrameNumber() const { return fps_counter_->current_frame_number(); } void LayerTreeHostImpl::AnimateScrollbars(base::TimeTicks time) { AnimateScrollbarsRecursive(active_tree_->root_layer(), time); } void LayerTreeHostImpl::AnimateScrollbarsRecursive(LayerImpl* layer, base::TimeTicks time) { if (!layer) return; ScrollbarAnimationController* scrollbar_controller = layer->scrollbar_animation_controller(); if (scrollbar_controller) scrollbar_controller->Animate(time); for (size_t i = 0; i < layer->children().size(); ++i) AnimateScrollbarsRecursive(layer->children()[i], time); } void LayerTreeHostImpl::PostDelayedScrollbarFade( const base::Closure& start_fade, base::TimeDelta delay) { client_->PostDelayedScrollbarFadeOnImplThread(start_fade, delay); } void LayerTreeHostImpl::SetNeedsScrollbarAnimationFrame() { TRACE_EVENT_INSTANT0( "cc", "LayerTreeHostImpl::SetNeedsRedraw due to scrollbar fade", TRACE_EVENT_SCOPE_THREAD); SetNeedsAnimate(); } void LayerTreeHostImpl::SetTreePriority(TreePriority priority) { if (!tile_manager_) return; if (global_tile_state_.tree_priority == priority) return; global_tile_state_.tree_priority = priority; DidModifyTilePriorities(); } TreePriority LayerTreeHostImpl::GetTreePriority() const { return global_tile_state_.tree_priority; } void LayerTreeHostImpl::UpdateCurrentBeginFrameArgs( const BeginFrameArgs& args) { DCHECK(!current_begin_frame_args_.IsValid()); current_begin_frame_args_ = args; // TODO(skyostil): Stop overriding the frame time once the usage of frame // timing is unified. current_begin_frame_args_.frame_time = gfx::FrameTime::Now(); } void LayerTreeHostImpl::ResetCurrentBeginFrameArgsForNextFrame() { current_begin_frame_args_ = BeginFrameArgs(); } BeginFrameArgs LayerTreeHostImpl::CurrentBeginFrameArgs() const { // Try to use the current frame time to keep animations non-jittery. But if // we're not in a frame (because this is during an input event or a delayed // task), fall back to physical time. This should still be monotonic. if (current_begin_frame_args_.IsValid()) return current_begin_frame_args_; return BeginFrameArgs::Create( BEGINFRAME_FROM_HERE, gfx::FrameTime::Now(), base::TimeTicks(), BeginFrameArgs::DefaultInterval(), BeginFrameArgs::NORMAL); } scoped_refptr LayerTreeHostImpl::AsValue() const { return AsValueWithFrame(NULL); } scoped_refptr LayerTreeHostImpl::AsValueWithFrame(FrameData* frame) const { scoped_refptr state = new base::trace_event::TracedValue(); AsValueWithFrameInto(frame, state.get()); return state; } void LayerTreeHostImpl::AsValueInto( base::trace_event::TracedValue* value) const { return AsValueWithFrameInto(NULL, value); } void LayerTreeHostImpl::AsValueWithFrameInto( FrameData* frame, base::trace_event::TracedValue* state) const { if (this->pending_tree_) { state->BeginDictionary("activation_state"); ActivationStateAsValueInto(state); state->EndDictionary(); } MathUtil::AddToTracedValue("device_viewport_size", device_viewport_size_, state); std::set tiles; active_tree_->GetAllTilesForTracing(&tiles); if (pending_tree_) pending_tree_->GetAllTilesForTracing(&tiles); state->BeginArray("active_tiles"); for (std::set::const_iterator it = tiles.begin(); it != tiles.end(); ++it) { const Tile* tile = *it; state->BeginDictionary(); tile->AsValueInto(state); state->EndDictionary(); } state->EndArray(); if (tile_manager_) { state->BeginDictionary("tile_manager_basic_state"); tile_manager_->BasicStateAsValueInto(state); state->EndDictionary(); } state->BeginDictionary("active_tree"); active_tree_->AsValueInto(state); state->EndDictionary(); if (pending_tree_) { state->BeginDictionary("pending_tree"); pending_tree_->AsValueInto(state); state->EndDictionary(); } if (frame) { state->BeginDictionary("frame"); frame->AsValueInto(state); state->EndDictionary(); } } scoped_refptr LayerTreeHostImpl::ActivationStateAsValue() const { scoped_refptr state = new base::trace_event::TracedValue(); ActivationStateAsValueInto(state.get()); return state; } void LayerTreeHostImpl::ActivationStateAsValueInto( base::trace_event::TracedValue* state) const { TracedValue::SetIDRef(this, state, "lthi"); if (tile_manager_) { state->BeginDictionary("tile_manager"); tile_manager_->BasicStateAsValueInto(state); state->EndDictionary(); } } void LayerTreeHostImpl::SetDebugState( const LayerTreeDebugState& new_debug_state) { if (LayerTreeDebugState::Equal(debug_state_, new_debug_state)) return; if (debug_state_.continuous_painting != new_debug_state.continuous_painting) paint_time_counter_->ClearHistory(); debug_state_ = new_debug_state; UpdateTileManagerMemoryPolicy(ActualManagedMemoryPolicy()); SetFullRootLayerDamage(); } void LayerTreeHostImpl::CreateUIResource(UIResourceId uid, const UIResourceBitmap& bitmap) { DCHECK_GT(uid, 0); GLint wrap_mode = 0; switch (bitmap.GetWrapMode()) { case UIResourceBitmap::CLAMP_TO_EDGE: wrap_mode = GL_CLAMP_TO_EDGE; break; case UIResourceBitmap::REPEAT: wrap_mode = GL_REPEAT; break; } // Allow for multiple creation requests with the same UIResourceId. The // previous resource is simply deleted. ResourceProvider::ResourceId id = ResourceIdForUIResource(uid); if (id) DeleteUIResource(uid); ResourceFormat format = resource_provider_->best_texture_format(); switch (bitmap.GetFormat()) { case UIResourceBitmap::RGBA8: break; case UIResourceBitmap::ALPHA_8: format = ALPHA_8; break; case UIResourceBitmap::ETC1: format = ETC1; break; } id = resource_provider_->CreateResource( bitmap.GetSize(), wrap_mode, ResourceProvider::TEXTURE_HINT_IMMUTABLE, format); UIResourceData data; data.resource_id = id; data.size = bitmap.GetSize(); data.opaque = bitmap.GetOpaque(); ui_resource_map_[uid] = data; AutoLockUIResourceBitmap bitmap_lock(bitmap); resource_provider_->CopyToResource(id, bitmap_lock.GetPixels(), bitmap.GetSize()); MarkUIResourceNotEvicted(uid); } void LayerTreeHostImpl::DeleteUIResource(UIResourceId uid) { ResourceProvider::ResourceId id = ResourceIdForUIResource(uid); if (id) { resource_provider_->DeleteResource(id); ui_resource_map_.erase(uid); } MarkUIResourceNotEvicted(uid); } void LayerTreeHostImpl::EvictAllUIResources() { if (ui_resource_map_.empty()) return; for (UIResourceMap::const_iterator iter = ui_resource_map_.begin(); iter != ui_resource_map_.end(); ++iter) { evicted_ui_resources_.insert(iter->first); resource_provider_->DeleteResource(iter->second.resource_id); } ui_resource_map_.clear(); client_->SetNeedsCommitOnImplThread(); client_->OnCanDrawStateChanged(CanDraw()); client_->RenewTreePriority(); } ResourceProvider::ResourceId LayerTreeHostImpl::ResourceIdForUIResource( UIResourceId uid) const { UIResourceMap::const_iterator iter = ui_resource_map_.find(uid); if (iter != ui_resource_map_.end()) return iter->second.resource_id; return 0; } bool LayerTreeHostImpl::IsUIResourceOpaque(UIResourceId uid) const { UIResourceMap::const_iterator iter = ui_resource_map_.find(uid); DCHECK(iter != ui_resource_map_.end()); return iter->second.opaque; } bool LayerTreeHostImpl::EvictedUIResourcesExist() const { return !evicted_ui_resources_.empty(); } void LayerTreeHostImpl::MarkUIResourceNotEvicted(UIResourceId uid) { std::set::iterator found_in_evicted = evicted_ui_resources_.find(uid); if (found_in_evicted == evicted_ui_resources_.end()) return; evicted_ui_resources_.erase(found_in_evicted); if (evicted_ui_resources_.empty()) client_->OnCanDrawStateChanged(CanDraw()); } void LayerTreeHostImpl::ScheduleMicroBenchmark( scoped_ptr benchmark) { micro_benchmark_controller_.ScheduleRun(benchmark.Pass()); } void LayerTreeHostImpl::InsertSwapPromiseMonitor(SwapPromiseMonitor* monitor) { swap_promise_monitor_.insert(monitor); } void LayerTreeHostImpl::RemoveSwapPromiseMonitor(SwapPromiseMonitor* monitor) { swap_promise_monitor_.erase(monitor); } void LayerTreeHostImpl::NotifySwapPromiseMonitorsOfSetNeedsRedraw() { std::set::iterator it = swap_promise_monitor_.begin(); for (; it != swap_promise_monitor_.end(); it++) (*it)->OnSetNeedsRedrawOnImpl(); } void LayerTreeHostImpl::NotifySwapPromiseMonitorsOfForwardingToMainThread() { std::set::iterator it = swap_promise_monitor_.begin(); for (; it != swap_promise_monitor_.end(); it++) (*it)->OnForwardScrollUpdateToMainThreadOnImpl(); } } // namespace cc