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chromium / chromium / src / fd6e4f4a7a3f166de9d2fbc89770b4f2eb90272f / . / cc / trees / layer_tree_impl.cc
blob: d44aa67fefea548b7336ed830cc9d27c9471fd60 [file] [log] [blame]
// 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_impl.h"
#include <stddef.h>
#include <stdint.h>
#include <algorithm>
#include <limits>
#include <set>
#include "base/metrics/histogram_macros.h"
#include "base/timer/elapsed_timer.h"
#include "base/trace_event/trace_event.h"
#include "base/trace_event/trace_event_argument.h"
#include "cc/animation/animation_host.h"
#include "cc/animation/keyframed_animation_curve.h"
#include "cc/animation/mutable_properties.h"
#include "cc/animation/scrollbar_animation_controller.h"
#include "cc/animation/scrollbar_animation_controller_linear_fade.h"
#include "cc/animation/scrollbar_animation_controller_thinning.h"
#include "cc/base/histograms.h"
#include "cc/base/math_util.h"
#include "cc/base/synced_property.h"
#include "cc/debug/devtools_instrumentation.h"
#include "cc/debug/traced_value.h"
#include "cc/input/page_scale_animation.h"
#include "cc/layers/heads_up_display_layer_impl.h"
#include "cc/layers/layer.h"
#include "cc/layers/layer_iterator.h"
#include "cc/layers/render_surface_impl.h"
#include "cc/layers/scrollbar_layer_impl_base.h"
#include "cc/resources/ui_resource_request.h"
#include "cc/trees/draw_property_utils.h"
#include "cc/trees/layer_tree_host_common.h"
#include "cc/trees/layer_tree_host_impl.h"
#include "cc/trees/occlusion_tracker.h"
#include "cc/trees/property_tree.h"
#include "cc/trees/property_tree_builder.h"
#include "ui/gfx/geometry/box_f.h"
#include "ui/gfx/geometry/point_conversions.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 {
const uint32_t kMainLayerFlags =
MutableProperty::kOpacity | MutableProperty::kTransform;
const uint32_t kScrollLayerFlags =
MutableProperty::kScrollLeft | MutableProperty::kScrollTop;
} // namespace
LayerTreeImpl::LayerTreeImpl(
LayerTreeHostImpl* layer_tree_host_impl,
scoped_refptr<SyncedProperty<ScaleGroup>> page_scale_factor,
scoped_refptr<SyncedTopControls> top_controls_shown_ratio,
scoped_refptr<SyncedElasticOverscroll> elastic_overscroll)
: layer_tree_host_impl_(layer_tree_host_impl),
source_frame_number_(-1),
is_first_frame_after_commit_tracker_(-1),
hud_layer_(0),
background_color_(0),
has_transparent_background_(false),
currently_scrolling_layer_id_(Layer::INVALID_ID),
last_scrolled_layer_id_(Layer::INVALID_ID),
overscroll_elasticity_layer_id_(Layer::INVALID_ID),
page_scale_layer_id_(Layer::INVALID_ID),
inner_viewport_scroll_layer_id_(Layer::INVALID_ID),
outer_viewport_scroll_layer_id_(Layer::INVALID_ID),
page_scale_factor_(page_scale_factor),
min_page_scale_factor_(0),
max_page_scale_factor_(0),
device_scale_factor_(1.f),
painted_device_scale_factor_(1.f),
elastic_overscroll_(elastic_overscroll),
viewport_size_invalid_(false),
needs_update_draw_properties_(true),
needs_full_tree_sync_(true),
next_activation_forces_redraw_(false),
has_ever_been_drawn_(false),
render_surface_layer_list_id_(0),
top_controls_shrink_blink_size_(false),
top_controls_height_(0),
top_controls_shown_ratio_(top_controls_shown_ratio) {}
LayerTreeImpl::~LayerTreeImpl() {
BreakSwapPromises(IsActiveTree() ? SwapPromise::SWAP_FAILS
: SwapPromise::ACTIVATION_FAILS);
// Need to explicitly clear the tree prior to destroying this so that
// the LayerTreeImpl pointer is still valid in the LayerImpl dtor.
DCHECK(!root_layer_);
DCHECK(layers_with_copy_output_request_.empty());
}
void LayerTreeImpl::Shutdown() {
root_layer_ = nullptr;
}
void LayerTreeImpl::ReleaseResources() {
if (root_layer_) {
LayerTreeHostCommon::CallFunctionForSubtree(
root_layer_.get(), [](LayerImpl* layer) { layer->ReleaseResources(); });
}
}
void LayerTreeImpl::RecreateResources() {
if (root_layer_) {
LayerTreeHostCommon::CallFunctionForSubtree(
root_layer_.get(),
[](LayerImpl* layer) { layer->RecreateResources(); });
}
}
void LayerTreeImpl::GatherFrameTimingRequestIds(
std::vector<int64_t>* request_ids) {
if (!root_layer_)
return;
// TODO(vmpstr): Early out if there are no requests on any of the layers. For
// that, we need to inform LayerTreeImpl whenever there are requests when we
// get them.
LayerTreeHostCommon::CallFunctionForSubtree(
root_layer_.get(), [request_ids](LayerImpl* layer) {
layer->GatherFrameTimingRequestIds(request_ids);
});
}
bool LayerTreeImpl::IsViewportLayerId(int id) const {
if (id == inner_viewport_scroll_layer_id_ ||
id == outer_viewport_scroll_layer_id_)
return true;
if (InnerViewportContainerLayer() &&
id == InnerViewportContainerLayer()->id())
return true;
if (OuterViewportContainerLayer() &&
id == OuterViewportContainerLayer()->id())
return true;
return false;
}
void LayerTreeImpl::DidUpdateScrollState(int layer_id) {
if (!IsActiveTree())
return;
if (layer_id == Layer::INVALID_ID)
return;
int scroll_layer_id, clip_layer_id;
if (IsViewportLayerId(layer_id)) {
if (!InnerViewportContainerLayer())
return;
// For scrollbar purposes, a change to any of the four viewport layers
// should affect the scrollbars tied to the outermost layers, which express
// the sum of the entire viewport.
scroll_layer_id = outer_viewport_scroll_layer_id_;
clip_layer_id = InnerViewportContainerLayer()->id();
} else {
// If the clip layer id was passed in, then look up the scroll layer, or
// vice versa.
auto i = clip_scroll_map_.find(layer_id);
if (i != clip_scroll_map_.end()) {
scroll_layer_id = i->second;
clip_layer_id = layer_id;
} else {
scroll_layer_id = layer_id;
clip_layer_id = LayerById(scroll_layer_id)->scroll_clip_layer_id();
}
}
UpdateScrollbars(scroll_layer_id, clip_layer_id);
}
void LayerTreeImpl::UpdateScrollbars(int scroll_layer_id, int clip_layer_id) {
DCHECK(IsActiveTree());
LayerImpl* clip_layer = LayerById(clip_layer_id);
LayerImpl* scroll_layer = LayerById(scroll_layer_id);
if (!clip_layer || !scroll_layer)
return;
gfx::SizeF clip_size(clip_layer->BoundsForScrolling());
gfx::SizeF scroll_size(scroll_layer->BoundsForScrolling());
if (scroll_size.IsEmpty())
return;
gfx::ScrollOffset current_offset = scroll_layer->CurrentScrollOffset();
if (IsViewportLayerId(scroll_layer_id)) {
current_offset += InnerViewportScrollLayer()->CurrentScrollOffset();
if (OuterViewportContainerLayer())
clip_size.SetToMin(OuterViewportContainerLayer()->BoundsForScrolling());
clip_size.Scale(1 / current_page_scale_factor());
}
bool scrollbar_needs_animation = false;
bool scroll_layer_size_did_change = false;
bool y_offset_did_change = false;
for (ScrollbarLayerImplBase* scrollbar : ScrollbarsFor(scroll_layer_id)) {
if (scrollbar->orientation() == HORIZONTAL) {
scrollbar_needs_animation |= scrollbar->SetCurrentPos(current_offset.x());
scrollbar_needs_animation |=
scrollbar->SetClipLayerLength(clip_size.width());
scrollbar_needs_animation |= scroll_layer_size_did_change |=
scrollbar->SetScrollLayerLength(scroll_size.width());
} else {
scrollbar_needs_animation |= y_offset_did_change |=
scrollbar->SetCurrentPos(current_offset.y());
scrollbar_needs_animation |=
scrollbar->SetClipLayerLength(clip_size.height());
scrollbar_needs_animation |= scroll_layer_size_did_change |=
scrollbar->SetScrollLayerLength(scroll_size.height());
}
scrollbar_needs_animation |=
scrollbar->SetVerticalAdjust(clip_layer->bounds_delta().y());
}
if (y_offset_did_change && IsViewportLayerId(scroll_layer_id))
TRACE_COUNTER_ID1("cc", "scroll_offset_y", scroll_layer->id(),
current_offset.y());
if (scrollbar_needs_animation) {
ScrollbarAnimationController* controller =
layer_tree_host_impl_->ScrollbarAnimationControllerForId(
scroll_layer_id);
if (controller)
controller->DidScrollUpdate(scroll_layer_size_did_change);
}
}
void LayerTreeImpl::SetRootLayer(scoped_ptr<LayerImpl> layer) {
root_layer_ = std::move(layer);
layer_tree_host_impl_->OnCanDrawStateChangedForTree();
}
LayerImpl* LayerTreeImpl::InnerViewportScrollLayer() const {
return LayerById(inner_viewport_scroll_layer_id_);
}
LayerImpl* LayerTreeImpl::OuterViewportScrollLayer() const {
return LayerById(outer_viewport_scroll_layer_id_);
}
gfx::ScrollOffset LayerTreeImpl::TotalScrollOffset() const {
gfx::ScrollOffset offset;
if (InnerViewportScrollLayer())
offset += InnerViewportScrollLayer()->CurrentScrollOffset();
if (OuterViewportScrollLayer())
offset += OuterViewportScrollLayer()->CurrentScrollOffset();
return offset;
}
gfx::ScrollOffset LayerTreeImpl::TotalMaxScrollOffset() const {
gfx::ScrollOffset offset;
if (InnerViewportScrollLayer())
offset += InnerViewportScrollLayer()->MaxScrollOffset();
if (OuterViewportScrollLayer())
offset += OuterViewportScrollLayer()->MaxScrollOffset();
return offset;
}
scoped_ptr<LayerImpl> LayerTreeImpl::DetachLayerTree() {
render_surface_layer_list_.clear();
set_needs_update_draw_properties();
return std::move(root_layer_);
}
static void UpdateClipTreeForBoundsDeltaOnLayer(LayerImpl* layer,
ClipTree* clip_tree) {
if (layer && layer->masks_to_bounds()) {
ClipNode* clip_node = clip_tree->Node(layer->clip_tree_index());
if (clip_node) {
DCHECK_EQ(layer->id(), clip_node->owner_id);
gfx::SizeF bounds = gfx::SizeF(layer->bounds());
if (clip_node->data.clip.size() != bounds) {
clip_node->data.clip.set_size(bounds);
clip_tree->set_needs_update(true);
}
}
}
}
void LayerTreeImpl::UpdatePropertyTreesForBoundsDelta() {
DCHECK(IsActiveTree());
LayerImpl* inner_container = InnerViewportContainerLayer();
LayerImpl* outer_container = OuterViewportContainerLayer();
UpdateClipTreeForBoundsDeltaOnLayer(inner_container,
&property_trees_.clip_tree);
UpdateClipTreeForBoundsDeltaOnLayer(InnerViewportScrollLayer(),
&property_trees_.clip_tree);
UpdateClipTreeForBoundsDeltaOnLayer(outer_container,
&property_trees_.clip_tree);
TransformTree& transform_tree = property_trees_.transform_tree;
if (inner_container)
transform_tree.SetInnerViewportBoundsDelta(inner_container->bounds_delta());
if (outer_container)
transform_tree.SetOuterViewportBoundsDelta(outer_container->bounds_delta());
}
void LayerTreeImpl::PushPropertiesTo(LayerTreeImpl* target_tree) {
// The request queue should have been processed and does not require a push.
DCHECK_EQ(ui_resource_request_queue_.size(), 0u);
target_tree->SetPropertyTrees(property_trees_);
if (next_activation_forces_redraw_) {
target_tree->ForceRedrawNextActivation();
next_activation_forces_redraw_ = false;
}
target_tree->PassSwapPromises(&swap_promise_list_);
target_tree->set_top_controls_shrink_blink_size(
top_controls_shrink_blink_size_);
target_tree->set_top_controls_height(top_controls_height_);
target_tree->PushTopControls(nullptr);
// Active tree already shares the page_scale_factor object with pending
// tree so only the limits need to be provided.
target_tree->PushPageScaleFactorAndLimits(nullptr, min_page_scale_factor(),
max_page_scale_factor());
target_tree->SetDeviceScaleFactor(device_scale_factor());
target_tree->set_painted_device_scale_factor(painted_device_scale_factor());
target_tree->elastic_overscroll()->PushPendingToActive();
target_tree->pending_page_scale_animation_ =
std::move(pending_page_scale_animation_);
target_tree->SetViewportLayersFromIds(
overscroll_elasticity_layer_id_, page_scale_layer_id_,
inner_viewport_scroll_layer_id_, outer_viewport_scroll_layer_id_);
target_tree->RegisterSelection(selection_);
// This should match the property synchronization in
// LayerTreeHost::finishCommitOnImplThread().
target_tree->set_source_frame_number(source_frame_number());
target_tree->set_background_color(background_color());
target_tree->set_has_transparent_background(has_transparent_background());
if (ViewportSizeInvalid())
target_tree->SetViewportSizeInvalid();
else
target_tree->ResetViewportSizeInvalid();
if (hud_layer())
target_tree->set_hud_layer(static_cast<HeadsUpDisplayLayerImpl*>(
LayerTreeHostCommon::FindLayerInSubtree(
target_tree->root_layer(), hud_layer()->id())));
else
target_tree->set_hud_layer(NULL);
target_tree->has_ever_been_drawn_ = false;
}
void LayerTreeImpl::AddToElementMap(LayerImpl* layer) {
if (!layer->element_id())
return;
TRACE_EVENT2(TRACE_DISABLED_BY_DEFAULT("compositor-worker"),
"LayerTreeImpl::AddToElementMap", "element_id",
layer->element_id(), "layer_id", layer->id());
ElementLayers& layers = element_layers_map_[layer->element_id()];
if (layer->mutable_properties() & kMainLayerFlags) {
if (!layers.main || layer->IsActive())
layers.main = layer;
}
if (layer->mutable_properties() & kScrollLayerFlags) {
if (!layers.scroll || layer->IsActive()) {
TRACE_EVENT2("compositor-worker", "LayerTreeImpl::AddToElementMap scroll",
"element_id", layer->element_id(), "layer_id", layer->id());
layers.scroll = layer;
}
}
}
void LayerTreeImpl::RemoveFromElementMap(LayerImpl* layer) {
if (!layer->element_id())
return;
TRACE_EVENT2(TRACE_DISABLED_BY_DEFAULT("compositor-worker"),
"LayerTreeImpl::RemoveFromElementMap", "element_id",
layer->element_id(), "layer_id", layer->id());
ElementLayers& layers = element_layers_map_[layer->element_id()];
if (layer->mutable_properties() & kMainLayerFlags)
layers.main = nullptr;
if (layer->mutable_properties() & kScrollLayerFlags)
layers.scroll = nullptr;
if (!layers.main && !layers.scroll)
element_layers_map_.erase(layer->element_id());
}
LayerTreeImpl::ElementLayers LayerTreeImpl::GetMutableLayers(
uint64_t element_id) {
auto iter = element_layers_map_.find(element_id);
if (iter == element_layers_map_.end())
return ElementLayers();
return iter->second;
}
LayerImpl* LayerTreeImpl::InnerViewportContainerLayer() const {
return InnerViewportScrollLayer()
? InnerViewportScrollLayer()->scroll_clip_layer()
: NULL;
}
LayerImpl* LayerTreeImpl::OuterViewportContainerLayer() const {
return OuterViewportScrollLayer()
? OuterViewportScrollLayer()->scroll_clip_layer()
: NULL;
}
LayerImpl* LayerTreeImpl::CurrentlyScrollingLayer() const {
DCHECK(IsActiveTree());
return LayerById(currently_scrolling_layer_id_);
}
int LayerTreeImpl::LastScrolledLayerId() const {
return last_scrolled_layer_id_;
}
void LayerTreeImpl::SetCurrentlyScrollingLayer(LayerImpl* layer) {
int new_id = layer ? layer->id() : Layer::INVALID_ID;
if (layer)
last_scrolled_layer_id_ = new_id;
if (currently_scrolling_layer_id_ == new_id)
return;
ScrollbarAnimationController* old_animation_controller =
layer_tree_host_impl_->ScrollbarAnimationControllerForId(
currently_scrolling_layer_id_);
ScrollbarAnimationController* new_animation_controller =
layer_tree_host_impl_->ScrollbarAnimationControllerForId(new_id);
if (old_animation_controller)
old_animation_controller->DidScrollEnd();
currently_scrolling_layer_id_ = new_id;
if (new_animation_controller)
new_animation_controller->DidScrollBegin();
}
void LayerTreeImpl::ClearCurrentlyScrollingLayer() {
SetCurrentlyScrollingLayer(NULL);
}
float LayerTreeImpl::ClampPageScaleFactorToLimits(
float page_scale_factor) const {
if (min_page_scale_factor_ && page_scale_factor < min_page_scale_factor_)
page_scale_factor = min_page_scale_factor_;
else if (max_page_scale_factor_ && page_scale_factor > max_page_scale_factor_)
page_scale_factor = max_page_scale_factor_;
return page_scale_factor;
}
void LayerTreeImpl::UpdatePropertyTreeScrollingAndAnimationFromMainThread() {
// TODO(enne): This should get replaced by pulling out scrolling and
// animations into their own trees. Then scrolls and animations would have
// their own ways of synchronizing across commits. This occurs to push
// updates from scrolling deltas on the compositor thread that have occurred
// after begin frame and updates from animations that have ticked since begin
// frame to a newly-committed property tree.
if (!root_layer())
return;
LayerTreeHostCommon::CallFunctionForSubtree(
root_layer(), [](LayerImpl* layer) {
layer->UpdatePropertyTreeForScrollingAndAnimationIfNeeded();
});
}
void LayerTreeImpl::SetPageScaleOnActiveTree(float active_page_scale) {
DCHECK(IsActiveTree());
if (page_scale_factor()->SetCurrent(
ClampPageScaleFactorToLimits(active_page_scale)))
DidUpdatePageScale();
}
void LayerTreeImpl::PushPageScaleFromMainThread(float page_scale_factor,
float min_page_scale_factor,
float max_page_scale_factor) {
PushPageScaleFactorAndLimits(&page_scale_factor, min_page_scale_factor,
max_page_scale_factor);
}
void LayerTreeImpl::PushPageScaleFactorAndLimits(const float* page_scale_factor,
float min_page_scale_factor,
float max_page_scale_factor) {
DCHECK(page_scale_factor || IsActiveTree());
bool changed_page_scale = false;
if (page_scale_factor) {
DCHECK(!IsActiveTree() || !layer_tree_host_impl_->pending_tree());
changed_page_scale |= page_scale_factor_->Delta() != 1.f;
// TODO(enne): Once CDP goes away, ignore this call below. The only time
// the property trees will differ is if there's been a page scale on the
// compositor thread after the begin frame, which is the delta check above.
changed_page_scale |=
page_scale_factor_->PushFromMainThread(*page_scale_factor);
}
if (IsActiveTree()) {
// TODO(enne): Pushing from pending to active should never require
// DidUpdatePageScale. The values should already be set by the fully
// computed property trees being synced from one tree to another. Remove
// this once CDP goes away.
changed_page_scale |= page_scale_factor_->PushPendingToActive();
}
changed_page_scale |=
SetPageScaleFactorLimits(min_page_scale_factor, max_page_scale_factor);
if (changed_page_scale)
DidUpdatePageScale();
}
void LayerTreeImpl::set_top_controls_shrink_blink_size(bool shrink) {
if (top_controls_shrink_blink_size_ == shrink)
return;
top_controls_shrink_blink_size_ = shrink;
if (IsActiveTree())
layer_tree_host_impl_->UpdateViewportContainerSizes();
}
void LayerTreeImpl::set_top_controls_height(float top_controls_height) {
if (top_controls_height_ == top_controls_height)
return;
top_controls_height_ = top_controls_height;
if (IsActiveTree())
layer_tree_host_impl_->UpdateViewportContainerSizes();
}
bool LayerTreeImpl::SetCurrentTopControlsShownRatio(float ratio) {
ratio = std::max(ratio, 0.f);
ratio = std::min(ratio, 1.f);
return top_controls_shown_ratio_->SetCurrent(ratio);
}
void LayerTreeImpl::PushTopControlsFromMainThread(
float top_controls_shown_ratio) {
PushTopControls(&top_controls_shown_ratio);
}
void LayerTreeImpl::PushTopControls(const float* top_controls_shown_ratio) {
DCHECK(top_controls_shown_ratio || IsActiveTree());
if (top_controls_shown_ratio) {
DCHECK(!IsActiveTree() || !layer_tree_host_impl_->pending_tree());
top_controls_shown_ratio_->PushFromMainThread(*top_controls_shown_ratio);
}
if (IsActiveTree()) {
if (top_controls_shown_ratio_->PushPendingToActive())
layer_tree_host_impl_->DidChangeTopControlsPosition();
}
}
bool LayerTreeImpl::SetPageScaleFactorLimits(float min_page_scale_factor,
float max_page_scale_factor) {
if (min_page_scale_factor == min_page_scale_factor_ &&
max_page_scale_factor == max_page_scale_factor_)
return false;
min_page_scale_factor_ = min_page_scale_factor;
max_page_scale_factor_ = max_page_scale_factor;
return true;
}
void LayerTreeImpl::DidUpdatePageScale() {
if (IsActiveTree())
page_scale_factor()->SetCurrent(
ClampPageScaleFactorToLimits(current_page_scale_factor()));
set_needs_update_draw_properties();
DidUpdateScrollState(inner_viewport_scroll_layer_id_);
}
void LayerTreeImpl::SetDeviceScaleFactor(float device_scale_factor) {
if (device_scale_factor == device_scale_factor_)
return;
device_scale_factor_ = device_scale_factor;
if (IsActiveTree())
layer_tree_host_impl_->SetFullRootLayerDamage();
}
SyncedProperty<ScaleGroup>* LayerTreeImpl::page_scale_factor() {
return page_scale_factor_.get();
}
const SyncedProperty<ScaleGroup>* LayerTreeImpl::page_scale_factor() const {
return page_scale_factor_.get();
}
gfx::SizeF LayerTreeImpl::ScrollableViewportSize() const {
if (!InnerViewportContainerLayer())
return gfx::SizeF();
return gfx::ScaleSize(InnerViewportContainerLayer()->BoundsForScrolling(),
1.0f / current_page_scale_factor());
}
gfx::Rect LayerTreeImpl::RootScrollLayerDeviceViewportBounds() const {
LayerImpl* root_scroll_layer = OuterViewportScrollLayer()
? OuterViewportScrollLayer()
: InnerViewportScrollLayer();
if (!root_scroll_layer || root_scroll_layer->children().empty())
return gfx::Rect();
LayerImpl* layer = root_scroll_layer->children()[0].get();
return MathUtil::MapEnclosingClippedRect(layer->ScreenSpaceTransform(),
gfx::Rect(layer->bounds()));
}
void LayerTreeImpl::ApplySentScrollAndScaleDeltasFromAbortedCommit() {
DCHECK(IsActiveTree());
page_scale_factor()->AbortCommit();
top_controls_shown_ratio()->AbortCommit();
elastic_overscroll()->AbortCommit();
if (!root_layer())
return;
LayerTreeHostCommon::CallFunctionForSubtree(
root_layer(), [](LayerImpl* layer) {
layer->ApplySentScrollDeltasFromAbortedCommit();
});
}
void LayerTreeImpl::SetViewportLayersFromIds(
int overscroll_elasticity_layer_id,
int page_scale_layer_id,
int inner_viewport_scroll_layer_id,
int outer_viewport_scroll_layer_id) {
overscroll_elasticity_layer_id_ = overscroll_elasticity_layer_id;
page_scale_layer_id_ = page_scale_layer_id;
inner_viewport_scroll_layer_id_ = inner_viewport_scroll_layer_id;
outer_viewport_scroll_layer_id_ = outer_viewport_scroll_layer_id;
}
void LayerTreeImpl::ClearViewportLayers() {
overscroll_elasticity_layer_id_ = Layer::INVALID_ID;
page_scale_layer_id_ = Layer::INVALID_ID;
inner_viewport_scroll_layer_id_ = Layer::INVALID_ID;
outer_viewport_scroll_layer_id_ = Layer::INVALID_ID;
}
#if DCHECK_IS_ON()
int SanityCheckCopyRequestCounts(LayerImpl* layer) {
int count = layer->HasCopyRequest() ? 1 : 0;
for (size_t i = 0; i < layer->children().size(); ++i) {
count += SanityCheckCopyRequestCounts(layer->child_at(i));
}
if (layer->layer_tree_impl()
->property_trees()
->effect_tree.Node(layer->effect_tree_index())
->owner_id == layer->id()) {
DCHECK_EQ(count, layer->num_copy_requests_in_target_subtree())
<< ", id: " << layer->id();
} else {
DCHECK_LE(count, layer->num_copy_requests_in_target_subtree())
<< ", id: " << layer->id();
}
return count;
}
#endif
bool LayerTreeImpl::UpdateDrawProperties(bool update_lcd_text) {
#if DCHECK_IS_ON()
if (root_layer())
SanityCheckCopyRequestCounts(root_layer());
#endif
if (!needs_update_draw_properties_)
return true;
// Calling UpdateDrawProperties must clear this flag, so there can be no
// early outs before this.
needs_update_draw_properties_ = false;
// For max_texture_size. When the renderer is re-created in
// CreateAndSetRenderer, the needs update draw properties flag is set
// again.
if (!layer_tree_host_impl_->renderer())
return false;
// Clear this after the renderer early out, as it should still be
// possible to hit test even without a renderer.
render_surface_layer_list_.clear();
if (!root_layer())
return false;
{
base::ElapsedTimer timer;
TRACE_EVENT2(
"cc", "LayerTreeImpl::UpdateDrawProperties::CalculateDrawProperties",
"IsActive", IsActiveTree(), "SourceFrameNumber", source_frame_number_);
bool can_render_to_separate_surface =
(layer_tree_host_impl_->GetDrawMode() !=
DRAW_MODE_RESOURCELESS_SOFTWARE);
++render_surface_layer_list_id_;
LayerTreeHostCommon::CalcDrawPropsImplInputs inputs(
root_layer(), DrawViewportSize(),
layer_tree_host_impl_->DrawTransform(), device_scale_factor(),
current_page_scale_factor(), PageScaleLayer(),
InnerViewportScrollLayer(), OuterViewportScrollLayer(),
elastic_overscroll()->Current(IsActiveTree()),
OverscrollElasticityLayer(), resource_provider()->max_texture_size(),
settings().can_use_lcd_text, settings().layers_always_allowed_lcd_text,
can_render_to_separate_surface,
settings().layer_transforms_should_scale_layer_contents,
settings().verify_property_trees, settings().use_property_trees,
&render_surface_layer_list_, render_surface_layer_list_id_,
&property_trees_);
LayerTreeHostCommon::CalculateDrawProperties(&inputs);
if (const char* client_name = GetClientNameForMetrics()) {
UMA_HISTOGRAM_COUNTS(
base::StringPrintf(
"Compositing.%s.LayerTreeImpl.CalculateDrawPropertiesUs",
client_name),
timer.Elapsed().InMicroseconds());
}
}
{
TRACE_EVENT2("cc", "LayerTreeImpl::UpdateDrawProperties::Occlusion",
"IsActive", IsActiveTree(), "SourceFrameNumber",
source_frame_number_);
OcclusionTracker occlusion_tracker(
root_layer()->render_surface()->content_rect());
occlusion_tracker.set_minimum_tracking_size(
settings().minimum_occlusion_tracking_size);
// LayerIterator is used here instead of CallFunctionForSubtree to only
// UpdateTilePriorities on layers that will be visible (and thus have valid
// draw properties) and not because any ordering is required.
LayerIterator end = LayerIterator::End(&render_surface_layer_list_);
for (LayerIterator it = LayerIterator::Begin(&render_surface_layer_list_);
it != end; ++it) {
occlusion_tracker.EnterLayer(it);
// There are very few render targets so this should be cheap to do for
// each layer instead of something more complicated.
bool inside_replica = false;
LayerImpl* layer = it->render_target();
while (layer && !inside_replica) {
if (layer->render_target()->has_replica())
inside_replica = true;
layer = layer->render_target()->parent();
}
// Don't use occlusion if a layer will appear in a replica, since the
// tile raster code does not know how to look for the replica and would
// consider it occluded even though the replica is visible.
// Since occlusion is only used for browser compositor (i.e.
// use_occlusion_for_tile_prioritization) and it won't use replicas,
// this should matter not.
if (it.represents_itself()) {
Occlusion occlusion =
inside_replica ? Occlusion()
: occlusion_tracker.GetCurrentOcclusionForLayer(
it->DrawTransform());
it->draw_properties().occlusion_in_content_space = occlusion;
}
if (it.represents_contributing_render_surface()) {
// Surfaces aren't used by the tile raster code, so they can have
// occlusion regardless of replicas.
Occlusion occlusion =
occlusion_tracker.GetCurrentOcclusionForContributingSurface(
it->render_surface()->draw_transform());
it->render_surface()->set_occlusion_in_content_space(occlusion);
// Masks are used to draw the contributing surface, so should have
// the same occlusion as the surface (nothing inside the surface
// occludes them).
if (LayerImpl* mask = it->mask_layer()) {
Occlusion mask_occlusion =
inside_replica
? Occlusion()
: occlusion_tracker.GetCurrentOcclusionForContributingSurface(
it->render_surface()->draw_transform() *
it->DrawTransform());
mask->draw_properties().occlusion_in_content_space = mask_occlusion;
}
if (LayerImpl* replica = it->replica_layer()) {
if (LayerImpl* mask = replica->mask_layer())
mask->draw_properties().occlusion_in_content_space = Occlusion();
}
}
occlusion_tracker.LeaveLayer(it);
}
unoccluded_screen_space_region_ =
occlusion_tracker.ComputeVisibleRegionInScreen();
}
// It'd be ideal if this could be done earlier, but when the raster source
// is updated from the main thread during push properties, update draw
// properties has not occurred yet and so it's not clear whether or not the
// layer can or cannot use lcd text. So, this is the cleanup pass to
// determine if the raster source needs to be replaced with a non-lcd
// raster source due to draw properties.
if (update_lcd_text) {
// TODO(enne): Make LTHI::sync_tree return this value.
LayerTreeImpl* sync_tree = layer_tree_host_impl_->CommitToActiveTree()
? layer_tree_host_impl_->active_tree()
: layer_tree_host_impl_->pending_tree();
// If this is not the sync tree, then it is not safe to update lcd text
// as it causes invalidations and the tiles may be in use.
DCHECK_EQ(this, sync_tree);
for (const auto& layer : picture_layers_)
layer->UpdateCanUseLCDTextAfterCommit();
}
{
TRACE_EVENT_BEGIN2("cc", "LayerTreeImpl::UpdateDrawProperties::UpdateTiles",
"IsActive", IsActiveTree(), "SourceFrameNumber",
source_frame_number_);
const bool resourceless_software_draw =
(layer_tree_host_impl_->GetDrawMode() ==
DRAW_MODE_RESOURCELESS_SOFTWARE);
size_t layers_updated_count = 0;
bool tile_priorities_updated = false;
for (PictureLayerImpl* layer : picture_layers_) {
if (!layer->IsDrawnRenderSurfaceLayerListMember())
continue;
++layers_updated_count;
tile_priorities_updated |= layer->UpdateTiles(resourceless_software_draw);
}
if (tile_priorities_updated)
DidModifyTilePriorities();
TRACE_EVENT_END1("cc", "LayerTreeImpl::UpdateDrawProperties::UpdateTiles",
"layers_updated_count", layers_updated_count);
}
DCHECK(!needs_update_draw_properties_) <<
"CalcDrawProperties should not set_needs_update_draw_properties()";
return true;
}
void LayerTreeImpl::BuildPropertyTreesForTesting() {
LayerTreeHostCommon::PreCalculateMetaInformationForTesting(root_layer_.get());
PropertyTreeBuilder::BuildPropertyTrees(
root_layer_.get(), PageScaleLayer(), InnerViewportScrollLayer(),
OuterViewportScrollLayer(), OverscrollElasticityLayer(),
elastic_overscroll()->Current(IsActiveTree()),
current_page_scale_factor(), device_scale_factor(),
gfx::Rect(DrawViewportSize()), layer_tree_host_impl_->DrawTransform(),
&property_trees_);
}
void LayerTreeImpl::IncrementRenderSurfaceListIdForTesting() {
render_surface_layer_list_id_++;
}
const LayerImplList& LayerTreeImpl::RenderSurfaceLayerList() const {
// If this assert triggers, then the list is dirty.
DCHECK(!needs_update_draw_properties_);
return render_surface_layer_list_;
}
const Region& LayerTreeImpl::UnoccludedScreenSpaceRegion() const {
// If this assert triggers, then the render_surface_layer_list_ is dirty, so
// the unoccluded_screen_space_region_ is not valid anymore.
DCHECK(!needs_update_draw_properties_);
return unoccluded_screen_space_region_;
}
gfx::SizeF LayerTreeImpl::ScrollableSize() const {
LayerImpl* root_scroll_layer = OuterViewportScrollLayer()
? OuterViewportScrollLayer()
: InnerViewportScrollLayer();
if (!root_scroll_layer || root_scroll_layer->children().empty())
return gfx::SizeF();
gfx::SizeF content_size =
root_scroll_layer->children()[0]->BoundsForScrolling();
gfx::SizeF viewport_size =
root_scroll_layer->scroll_clip_layer()->BoundsForScrolling();
content_size.SetToMax(viewport_size);
return content_size;
}
LayerImpl* LayerTreeImpl::LayerById(int id) const {
LayerIdMap::const_iterator iter = layer_id_map_.find(id);
return iter != layer_id_map_.end() ? iter->second : NULL;
}
void LayerTreeImpl::RegisterLayer(LayerImpl* layer) {
DCHECK(!LayerById(layer->id()));
layer_id_map_[layer->id()] = layer;
if (layer_tree_host_impl_->animation_host())
layer_tree_host_impl_->animation_host()->RegisterLayer(
layer->id(),
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING);
}
void LayerTreeImpl::UnregisterLayer(LayerImpl* layer) {
DCHECK(LayerById(layer->id()));
if (layer_tree_host_impl_->animation_host())
layer_tree_host_impl_->animation_host()->UnregisterLayer(
layer->id(),
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING);
layer_id_map_.erase(layer->id());
}
size_t LayerTreeImpl::NumLayers() {
return layer_id_map_.size();
}
void LayerTreeImpl::DidBecomeActive() {
if (next_activation_forces_redraw_) {
layer_tree_host_impl_->SetFullRootLayerDamage();
next_activation_forces_redraw_ = false;
}
// Always reset this flag on activation, as we would only have activated
// if we were in a good state.
layer_tree_host_impl_->ResetRequiresHighResToDraw();
if (root_layer()) {
LayerTreeHostCommon::CallFunctionForSubtree(
root_layer(), [](LayerImpl* layer) { layer->DidBecomeActive(); });
}
for (const auto& swap_promise : swap_promise_list_)
swap_promise->DidActivate();
devtools_instrumentation::DidActivateLayerTree(layer_tree_host_impl_->id(),
source_frame_number_);
}
bool LayerTreeImpl::RequiresHighResToDraw() const {
return layer_tree_host_impl_->RequiresHighResToDraw();
}
bool LayerTreeImpl::ViewportSizeInvalid() const {
return viewport_size_invalid_;
}
void LayerTreeImpl::SetViewportSizeInvalid() {
viewport_size_invalid_ = true;
layer_tree_host_impl_->OnCanDrawStateChangedForTree();
}
void LayerTreeImpl::ResetViewportSizeInvalid() {
viewport_size_invalid_ = false;
layer_tree_host_impl_->OnCanDrawStateChangedForTree();
}
TaskRunnerProvider* LayerTreeImpl::task_runner_provider() const {
return layer_tree_host_impl_->task_runner_provider();
}
const LayerTreeSettings& LayerTreeImpl::settings() const {
return layer_tree_host_impl_->settings();
}
const LayerTreeDebugState& LayerTreeImpl::debug_state() const {
return layer_tree_host_impl_->debug_state();
}
const RendererCapabilitiesImpl& LayerTreeImpl::GetRendererCapabilities() const {
return layer_tree_host_impl_->GetRendererCapabilities();
}
ContextProvider* LayerTreeImpl::context_provider() const {
return output_surface()->context_provider();
}
OutputSurface* LayerTreeImpl::output_surface() const {
return layer_tree_host_impl_->output_surface();
}
ResourceProvider* LayerTreeImpl::resource_provider() const {
return layer_tree_host_impl_->resource_provider();
}
TileManager* LayerTreeImpl::tile_manager() const {
return layer_tree_host_impl_->tile_manager();
}
FrameRateCounter* LayerTreeImpl::frame_rate_counter() const {
return layer_tree_host_impl_->fps_counter();
}
MemoryHistory* LayerTreeImpl::memory_history() const {
return layer_tree_host_impl_->memory_history();
}
gfx::Size LayerTreeImpl::device_viewport_size() const {
return layer_tree_host_impl_->device_viewport_size();
}
DebugRectHistory* LayerTreeImpl::debug_rect_history() const {
return layer_tree_host_impl_->debug_rect_history();
}
bool LayerTreeImpl::IsActiveTree() const {
return layer_tree_host_impl_->active_tree() == this;
}
bool LayerTreeImpl::IsPendingTree() const {
return layer_tree_host_impl_->pending_tree() == this;
}
bool LayerTreeImpl::IsRecycleTree() const {
return layer_tree_host_impl_->recycle_tree() == this;
}
bool LayerTreeImpl::IsSyncTree() const {
return layer_tree_host_impl_->sync_tree() == this;
}
LayerImpl* LayerTreeImpl::FindActiveTreeLayerById(int id) {
LayerTreeImpl* tree = layer_tree_host_impl_->active_tree();
if (!tree)
return NULL;
return tree->LayerById(id);
}
LayerImpl* LayerTreeImpl::FindPendingTreeLayerById(int id) {
LayerTreeImpl* tree = layer_tree_host_impl_->pending_tree();
if (!tree)
return NULL;
return tree->LayerById(id);
}
bool LayerTreeImpl::PinchGestureActive() const {
return layer_tree_host_impl_->pinch_gesture_active();
}
BeginFrameArgs LayerTreeImpl::CurrentBeginFrameArgs() const {
return layer_tree_host_impl_->CurrentBeginFrameArgs();
}
base::TimeDelta LayerTreeImpl::CurrentBeginFrameInterval() const {
return layer_tree_host_impl_->CurrentBeginFrameInterval();
}
gfx::Rect LayerTreeImpl::DeviceViewport() const {
return layer_tree_host_impl_->DeviceViewport();
}
gfx::Size LayerTreeImpl::DrawViewportSize() const {
return layer_tree_host_impl_->DrawViewportSize();
}
const gfx::Rect LayerTreeImpl::ViewportRectForTilePriority() const {
return layer_tree_host_impl_->ViewportRectForTilePriority();
}
scoped_ptr<ScrollbarAnimationController>
LayerTreeImpl::CreateScrollbarAnimationController(int scroll_layer_id) {
DCHECK(settings().scrollbar_fade_delay_ms);
DCHECK(settings().scrollbar_fade_duration_ms);
base::TimeDelta delay =
base::TimeDelta::FromMilliseconds(settings().scrollbar_fade_delay_ms);
base::TimeDelta resize_delay = base::TimeDelta::FromMilliseconds(
settings().scrollbar_fade_resize_delay_ms);
base::TimeDelta duration =
base::TimeDelta::FromMilliseconds(settings().scrollbar_fade_duration_ms);
switch (settings().scrollbar_animator) {
case LayerTreeSettings::LINEAR_FADE: {
return ScrollbarAnimationControllerLinearFade::Create(
scroll_layer_id, layer_tree_host_impl_, delay, resize_delay,
duration);
}
case LayerTreeSettings::THINNING: {
return ScrollbarAnimationControllerThinning::Create(
scroll_layer_id, layer_tree_host_impl_, delay, resize_delay,
duration);
}
case LayerTreeSettings::NO_ANIMATOR:
NOTREACHED();
break;
}
return nullptr;
}
void LayerTreeImpl::DidAnimateScrollOffset() {
layer_tree_host_impl_->DidAnimateScrollOffset();
}
bool LayerTreeImpl::use_gpu_rasterization() const {
return layer_tree_host_impl_->use_gpu_rasterization();
}
GpuRasterizationStatus LayerTreeImpl::GetGpuRasterizationStatus() const {
return layer_tree_host_impl_->gpu_rasterization_status();
}
bool LayerTreeImpl::create_low_res_tiling() const {
return layer_tree_host_impl_->create_low_res_tiling();
}
void LayerTreeImpl::SetNeedsRedraw() {
layer_tree_host_impl_->SetNeedsRedraw();
}
AnimationRegistrar* LayerTreeImpl::GetAnimationRegistrar() const {
return layer_tree_host_impl_->animation_registrar();
}
void LayerTreeImpl::GetAllPrioritizedTilesForTracing(
std::vector<PrioritizedTile>* prioritized_tiles) const {
LayerIterator end = LayerIterator::End(&render_surface_layer_list_);
for (LayerIterator it = LayerIterator::Begin(&render_surface_layer_list_);
it != end; ++it) {
if (!it.represents_itself())
continue;
LayerImpl* layer_impl = *it;
layer_impl->GetAllPrioritizedTilesForTracing(prioritized_tiles);
}
}
void LayerTreeImpl::AsValueInto(base::trace_event::TracedValue* state) const {
TracedValue::MakeDictIntoImplicitSnapshot(state, "cc::LayerTreeImpl", this);
state->SetInteger("source_frame_number", source_frame_number_);
state->BeginDictionary("root_layer");
root_layer_->AsValueInto(state);
state->EndDictionary();
state->BeginArray("render_surface_layer_list");
LayerIterator end = LayerIterator::End(&render_surface_layer_list_);
for (LayerIterator it = LayerIterator::Begin(&render_surface_layer_list_);
it != end; ++it) {
if (!it.represents_itself())
continue;
TracedValue::AppendIDRef(*it, state);
}
state->EndArray();
state->BeginArray("swap_promise_trace_ids");
for (const auto& swap_promise : swap_promise_list_)
state->AppendDouble(swap_promise->TraceId());
state->EndArray();
state->BeginArray("pinned_swap_promise_trace_ids");
for (const auto& swap_promise : pinned_swap_promise_list_)
state->AppendDouble(swap_promise->TraceId());
state->EndArray();
}
bool LayerTreeImpl::DistributeRootScrollOffset(
const gfx::ScrollOffset& root_offset) {
if (!InnerViewportScrollLayer())
return false;
DCHECK(OuterViewportScrollLayer());
// If we get here, we have both inner/outer viewports, and need to distribute
// the scroll offset between them.
gfx::ScrollOffset inner_viewport_offset =
InnerViewportScrollLayer()->CurrentScrollOffset();
gfx::ScrollOffset outer_viewport_offset =
OuterViewportScrollLayer()->CurrentScrollOffset();
// It may be nothing has changed.
DCHECK(inner_viewport_offset + outer_viewport_offset == TotalScrollOffset());
if (inner_viewport_offset + outer_viewport_offset == root_offset)
return false;
gfx::ScrollOffset max_outer_viewport_scroll_offset =
OuterViewportScrollLayer()->MaxScrollOffset();
outer_viewport_offset = root_offset - inner_viewport_offset;
outer_viewport_offset.SetToMin(max_outer_viewport_scroll_offset);
outer_viewport_offset.SetToMax(gfx::ScrollOffset());
OuterViewportScrollLayer()->SetCurrentScrollOffset(outer_viewport_offset);
inner_viewport_offset = root_offset - outer_viewport_offset;
InnerViewportScrollLayer()->SetCurrentScrollOffset(inner_viewport_offset);
return true;
}
void LayerTreeImpl::QueueSwapPromise(scoped_ptr<SwapPromise> swap_promise) {
DCHECK(swap_promise);
swap_promise_list_.push_back(std::move(swap_promise));
}
void LayerTreeImpl::QueuePinnedSwapPromise(
scoped_ptr<SwapPromise> swap_promise) {
DCHECK(IsActiveTree());
DCHECK(swap_promise);
pinned_swap_promise_list_.push_back(std::move(swap_promise));
}
void LayerTreeImpl::PassSwapPromises(
std::vector<scoped_ptr<SwapPromise>>* new_swap_promise) {
for (const auto& swap_promise : swap_promise_list_)
swap_promise->DidNotSwap(SwapPromise::SWAP_FAILS);
swap_promise_list_.clear();
swap_promise_list_.swap(*new_swap_promise);
}
void LayerTreeImpl::FinishSwapPromises(CompositorFrameMetadata* metadata) {
for (const auto& swap_promise : swap_promise_list_)
swap_promise->DidSwap(metadata);
swap_promise_list_.clear();
for (const auto& swap_promise : pinned_swap_promise_list_)
swap_promise->DidSwap(metadata);
pinned_swap_promise_list_.clear();
}
void LayerTreeImpl::BreakSwapPromises(SwapPromise::DidNotSwapReason reason) {
for (const auto& swap_promise : swap_promise_list_)
swap_promise->DidNotSwap(reason);
swap_promise_list_.clear();
for (const auto& swap_promise : pinned_swap_promise_list_)
swap_promise->DidNotSwap(reason);
pinned_swap_promise_list_.clear();
}
void LayerTreeImpl::DidModifyTilePriorities() {
layer_tree_host_impl_->DidModifyTilePriorities();
}
void LayerTreeImpl::set_ui_resource_request_queue(
const UIResourceRequestQueue& queue) {
ui_resource_request_queue_ = queue;
}
ResourceId LayerTreeImpl::ResourceIdForUIResource(UIResourceId uid) const {
return layer_tree_host_impl_->ResourceIdForUIResource(uid);
}
bool LayerTreeImpl::IsUIResourceOpaque(UIResourceId uid) const {
return layer_tree_host_impl_->IsUIResourceOpaque(uid);
}
void LayerTreeImpl::ProcessUIResourceRequestQueue() {
for (const auto& req : ui_resource_request_queue_) {
switch (req.GetType()) {
case UIResourceRequest::UI_RESOURCE_CREATE:
layer_tree_host_impl_->CreateUIResource(req.GetId(), req.GetBitmap());
break;
case UIResourceRequest::UI_RESOURCE_DELETE:
layer_tree_host_impl_->DeleteUIResource(req.GetId());
break;
case UIResourceRequest::UI_RESOURCE_INVALID_REQUEST:
NOTREACHED();
break;
}
}
ui_resource_request_queue_.clear();
// If all UI resource evictions were not recreated by processing this queue,
// then another commit is required.
if (layer_tree_host_impl_->EvictedUIResourcesExist())
layer_tree_host_impl_->SetNeedsCommit();
}
void LayerTreeImpl::RegisterPictureLayerImpl(PictureLayerImpl* layer) {
DCHECK(std::find(picture_layers_.begin(), picture_layers_.end(), layer) ==
picture_layers_.end());
picture_layers_.push_back(layer);
}
void LayerTreeImpl::UnregisterPictureLayerImpl(PictureLayerImpl* layer) {
std::vector<PictureLayerImpl*>::iterator it =
std::find(picture_layers_.begin(), picture_layers_.end(), layer);
DCHECK(it != picture_layers_.end());
picture_layers_.erase(it);
}
void LayerTreeImpl::RegisterScrollbar(ScrollbarLayerImplBase* scrollbar_layer) {
if (scrollbar_layer->ScrollLayerId() == Layer::INVALID_ID)
return;
scrollbar_map_.insert(std::pair<int, int>(scrollbar_layer->ScrollLayerId(),
scrollbar_layer->id()));
if (IsActiveTree() && scrollbar_layer->is_overlay_scrollbar())
layer_tree_host_impl_->RegisterScrollbarAnimationController(
scrollbar_layer->ScrollLayerId());
DidUpdateScrollState(scrollbar_layer->ScrollLayerId());
}
void LayerTreeImpl::UnregisterScrollbar(
ScrollbarLayerImplBase* scrollbar_layer) {
int scroll_layer_id = scrollbar_layer->ScrollLayerId();
if (scroll_layer_id == Layer::INVALID_ID)
return;
auto scrollbar_range = scrollbar_map_.equal_range(scroll_layer_id);
for (auto i = scrollbar_range.first; i != scrollbar_range.second; ++i)
if (i->second == scrollbar_layer->id()) {
scrollbar_map_.erase(i);
break;
}
if (IsActiveTree() && scrollbar_map_.count(scroll_layer_id) == 0)
layer_tree_host_impl_->UnregisterScrollbarAnimationController(
scroll_layer_id);
}
ScrollbarSet LayerTreeImpl::ScrollbarsFor(int scroll_layer_id) const {
ScrollbarSet scrollbars;
auto scrollbar_range = scrollbar_map_.equal_range(scroll_layer_id);
for (auto i = scrollbar_range.first; i != scrollbar_range.second; ++i)
scrollbars.insert(LayerById(i->second)->ToScrollbarLayer());
return scrollbars;
}
void LayerTreeImpl::RegisterScrollLayer(LayerImpl* layer) {
if (layer->scroll_clip_layer_id() == Layer::INVALID_ID)
return;
clip_scroll_map_.insert(
std::pair<int, int>(layer->scroll_clip_layer_id(), layer->id()));
DidUpdateScrollState(layer->id());
}
void LayerTreeImpl::UnregisterScrollLayer(LayerImpl* layer) {
if (layer->scroll_clip_layer_id() == Layer::INVALID_ID)
return;
clip_scroll_map_.erase(layer->scroll_clip_layer_id());
}
void LayerTreeImpl::AddLayerWithCopyOutputRequest(LayerImpl* layer) {
// Only the active tree needs to know about layers with copy requests, as
// they are aborted if not serviced during draw.
DCHECK(IsActiveTree());
// DCHECK(std::find(layers_with_copy_output_request_.begin(),
// layers_with_copy_output_request_.end(),
// layer) == layers_with_copy_output_request_.end());
// TODO(danakj): Remove this once crash is found crbug.com/309777
for (size_t i = 0; i < layers_with_copy_output_request_.size(); ++i) {
CHECK(layers_with_copy_output_request_[i] != layer)
<< i << " of " << layers_with_copy_output_request_.size();
}
layers_with_copy_output_request_.push_back(layer);
}
void LayerTreeImpl::RemoveLayerWithCopyOutputRequest(LayerImpl* layer) {
// Only the active tree needs to know about layers with copy requests, as
// they are aborted if not serviced during draw.
DCHECK(IsActiveTree());
std::vector<LayerImpl*>::iterator it = std::find(
layers_with_copy_output_request_.begin(),
layers_with_copy_output_request_.end(),
layer);
DCHECK(it != layers_with_copy_output_request_.end());
layers_with_copy_output_request_.erase(it);
// TODO(danakj): Remove this once crash is found crbug.com/309777
for (size_t i = 0; i < layers_with_copy_output_request_.size(); ++i) {
CHECK(layers_with_copy_output_request_[i] != layer)
<< i << " of " << layers_with_copy_output_request_.size();
}
}
void LayerTreeImpl::AddSurfaceLayer(LayerImpl* layer) {
DCHECK(std::find(surface_layers_.begin(), surface_layers_.end(), layer) ==
surface_layers_.end());
surface_layers_.push_back(layer);
}
void LayerTreeImpl::RemoveSurfaceLayer(LayerImpl* layer) {
std::vector<LayerImpl*>::iterator it =
std::find(surface_layers_.begin(), surface_layers_.end(), layer);
DCHECK(it != surface_layers_.end());
surface_layers_.erase(it);
}
const std::vector<LayerImpl*>& LayerTreeImpl::LayersWithCopyOutputRequest()
const {
// Only the active tree needs to know about layers with copy requests, as
// they are aborted if not serviced during draw.
DCHECK(IsActiveTree());
return layers_with_copy_output_request_;
}
template <typename LayerType>
static inline bool LayerClipsSubtree(LayerType* layer) {
return layer->masks_to_bounds() || layer->mask_layer();
}
static bool PointHitsRect(
const gfx::PointF& screen_space_point,
const gfx::Transform& local_space_to_screen_space_transform,
const gfx::Rect& local_space_rect,
float* distance_to_camera) {
// If the transform is not invertible, then assume that this point doesn't hit
// this rect.
gfx::Transform inverse_local_space_to_screen_space(
gfx::Transform::kSkipInitialization);
if (!local_space_to_screen_space_transform.GetInverse(
&inverse_local_space_to_screen_space))
return false;
// Transform the hit test point from screen space to the local space of the
// given rect.
bool clipped = false;
gfx::Point3F planar_point = MathUtil::ProjectPoint3D(
inverse_local_space_to_screen_space, screen_space_point, &clipped);
gfx::PointF hit_test_point_in_local_space =
gfx::PointF(planar_point.x(), planar_point.y());
// If ProjectPoint could not project to a valid value, then we assume that
// this point doesn't hit this rect.
if (clipped)
return false;
if (!gfx::RectF(local_space_rect).Contains(hit_test_point_in_local_space))
return false;
if (distance_to_camera) {
// To compute the distance to the camera, we have to take the planar point
// and pull it back to world space and compute the displacement along the
// z-axis.
gfx::Point3F planar_point_in_screen_space(planar_point);
local_space_to_screen_space_transform.TransformPoint(
&planar_point_in_screen_space);
*distance_to_camera = planar_point_in_screen_space.z();
}
return true;
}
static bool PointHitsRegion(const gfx::PointF& screen_space_point,
const gfx::Transform& screen_space_transform,
const Region& layer_space_region) {
// If the transform is not invertible, then assume that this point doesn't hit
// this region.
gfx::Transform inverse_screen_space_transform(
gfx::Transform::kSkipInitialization);
if (!screen_space_transform.GetInverse(&inverse_screen_space_transform))
return false;
// Transform the hit test point from screen space to the local space of the
// given region.
bool clipped = false;
gfx::PointF hit_test_point_in_layer_space = MathUtil::ProjectPoint(
inverse_screen_space_transform, screen_space_point, &clipped);
// If ProjectPoint could not project to a valid value, then we assume that
// this point doesn't hit this region.
if (clipped)
return false;
return layer_space_region.Contains(
gfx::ToRoundedPoint(hit_test_point_in_layer_space));
}
static const LayerImpl* GetNextClippingLayer(const LayerImpl* layer) {
if (layer->scroll_parent())
return layer->scroll_parent();
if (layer->clip_parent())
return layer->clip_parent();
return layer->parent();
}
static const gfx::Transform SurfaceScreenSpaceTransform(
const LayerImpl* layer,
const TransformTree& transform_tree,
const bool use_property_trees) {
DCHECK(layer->render_surface());
if (!use_property_trees)
return layer->render_surface()->screen_space_transform();
return layer->IsDrawnRenderSurfaceLayerListMember()
? layer->render_surface()->screen_space_transform()
: SurfaceScreenSpaceTransformFromPropertyTrees(
layer->render_surface(), transform_tree);
}
static bool PointIsClippedByAncestorClipNode(
const gfx::PointF& screen_space_point,
const LayerImpl* layer,
const ClipTree& clip_tree,
const TransformTree& transform_tree) {
// We need to visit all ancestor clip nodes to check this. Checking with just
// the combined clip stored at a clip node is not enough because parent
// combined clip can sometimes be smaller than current combined clip. This can
// happen when we have transforms like rotation that inflate the combined
// clip's bounds. Also, the point can be clipped by the content rect of an
// ancestor render surface.
// We first check if the point is clipped by viewport.
const ClipNode* clip_node = clip_tree.Node(1);
gfx::Rect combined_clip_in_target_space =
gfx::ToEnclosingRect(clip_node->data.combined_clip_in_target_space);
if (!PointHitsRect(screen_space_point, gfx::Transform(),
combined_clip_in_target_space, NULL))
return true;
for (const ClipNode* clip_node = clip_tree.Node(layer->clip_tree_index());
clip_node->id > 1; clip_node = clip_tree.parent(clip_node)) {
if (clip_node->data.applies_local_clip) {
const TransformNode* transform_node =
transform_tree.Node(clip_node->data.target_id);
gfx::Rect combined_clip_in_target_space =
gfx::ToEnclosingRect(clip_node->data.combined_clip_in_target_space);
if (!PointHitsRect(screen_space_point, transform_node->data.to_screen,
combined_clip_in_target_space, NULL))
return true;
}
const LayerImpl* clip_node_owner =
layer->layer_tree_impl()->LayerById(clip_node->owner_id);
if (clip_node_owner->render_surface() &&
!PointHitsRect(
screen_space_point,
SurfaceScreenSpaceTransform(clip_node_owner, transform_tree,
true /*use_property_trees*/),
clip_node_owner->render_surface()->content_rect(), NULL)) {
return true;
}
}
return false;
}
static bool PointIsClippedBySurfaceOrClipRect(
const gfx::PointF& screen_space_point,
const LayerImpl* layer,
const TransformTree& transform_tree,
const ClipTree& clip_tree,
const bool use_property_trees) {
// Walk up the layer tree and hit-test any render_surfaces and any layer
// clip rects that are active.
if (use_property_trees) {
return PointIsClippedByAncestorClipNode(screen_space_point, layer,
clip_tree, transform_tree);
}
for (; layer; layer = GetNextClippingLayer(layer)) {
if (layer->render_surface() &&
!PointHitsRect(screen_space_point,
SurfaceScreenSpaceTransform(layer, transform_tree,
use_property_trees),
layer->render_surface()->content_rect(), NULL)) {
return true;
}
if (LayerClipsSubtree(layer) &&
!PointHitsRect(screen_space_point, layer->ScreenSpaceTransform(),
gfx::Rect(layer->bounds()), NULL)) {
return true;
}
}
// If we have finished walking all ancestors without having already exited,
// then the point is not clipped by any ancestors.
return false;
}
static bool PointHitsLayer(const LayerImpl* layer,
const gfx::PointF& screen_space_point,
float* distance_to_intersection,
const TransformTree& transform_tree,
const ClipTree& clip_tree,
const bool use_property_trees) {
gfx::Rect content_rect(layer->bounds());
if (!PointHitsRect(screen_space_point, layer->ScreenSpaceTransform(),
content_rect, distance_to_intersection))
return false;
// At this point, we think the point does hit the layer, but we need to walk
// up the parents to ensure that the layer was not clipped in such a way
// that the hit point actually should not hit the layer.
if (PointIsClippedBySurfaceOrClipRect(screen_space_point, layer,
transform_tree, clip_tree,
use_property_trees))
return false;
// Skip the HUD layer.
if (layer == layer->layer_tree_impl()->hud_layer())
return false;
return true;
}
struct FindClosestMatchingLayerDataForRecursion {
FindClosestMatchingLayerDataForRecursion()
: closest_match(NULL),
closest_distance(-std::numeric_limits<float>::infinity()) {}
LayerImpl* closest_match;
// Note that the positive z-axis points towards the camera, so bigger means
// closer in this case, counterintuitively.
float closest_distance;
};
template <typename Functor>
static void FindClosestMatchingLayer(
const gfx::PointF& screen_space_point,
LayerImpl* layer,
const Functor& func,
const TransformTree& transform_tree,
const ClipTree& clip_tree,
const bool use_property_trees,
FindClosestMatchingLayerDataForRecursion* data_for_recursion) {
size_t children_size = layer->children().size();
for (size_t i = 0; i < children_size; ++i) {
size_t index = children_size - 1 - i;
FindClosestMatchingLayer(screen_space_point, layer->children()[index].get(),
func, transform_tree, clip_tree,
use_property_trees, data_for_recursion);
}
if (!func(layer))
return;
float distance_to_intersection = 0.f;
bool hit = false;
if (layer->Is3dSorted())
hit = PointHitsLayer(layer, screen_space_point, &distance_to_intersection,
transform_tree, clip_tree, use_property_trees);
else
hit = PointHitsLayer(layer, screen_space_point, nullptr, transform_tree,
clip_tree, use_property_trees);
if (!hit)
return;
bool in_front_of_previous_candidate =
data_for_recursion->closest_match &&
layer->sorting_context_id() ==
data_for_recursion->closest_match->sorting_context_id() &&
distance_to_intersection > data_for_recursion->closest_distance +
std::numeric_limits<float>::epsilon();
if (!data_for_recursion->closest_match || in_front_of_previous_candidate) {
data_for_recursion->closest_distance = distance_to_intersection;
data_for_recursion->closest_match = layer;
}
}
static bool ScrollsAnyDrawnRenderSurfaceLayerListMember(LayerImpl* layer) {
if (!layer->scrollable())
return false;
if (layer->layer_or_descendant_is_drawn())
return true;
if (!layer->scroll_children())
return false;
for (std::set<LayerImpl*>::const_iterator it =
layer->scroll_children()->begin();
it != layer->scroll_children()->end();
++it) {
if ((*it)->layer_or_descendant_is_drawn())
return true;
}
return false;
}
struct FindScrollingLayerFunctor {
bool operator()(LayerImpl* layer) const {
return ScrollsAnyDrawnRenderSurfaceLayerListMember(layer);
}
};
LayerImpl* LayerTreeImpl::FindFirstScrollingLayerThatIsHitByPoint(
const gfx::PointF& screen_space_point) {
FindClosestMatchingLayerDataForRecursion data_for_recursion;
bool use_property_trees =
settings().use_property_trees || settings().verify_property_trees;
FindClosestMatchingLayer(
screen_space_point, root_layer(), FindScrollingLayerFunctor(),
property_trees_.transform_tree, property_trees_.clip_tree,
use_property_trees, &data_for_recursion);
return data_for_recursion.closest_match;
}
struct HitTestVisibleScrollableOrTouchableFunctor {
bool operator()(LayerImpl* layer) const {
return layer->IsDrawnRenderSurfaceLayerListMember() ||
ScrollsAnyDrawnRenderSurfaceLayerListMember(layer) ||
!layer->touch_event_handler_region().IsEmpty() ||
layer->have_wheel_event_handlers();
}
};
LayerImpl* LayerTreeImpl::FindLayerThatIsHitByPoint(
const gfx::PointF& screen_space_point) {
if (!root_layer())
return NULL;
bool update_lcd_text = false;
if (!UpdateDrawProperties(update_lcd_text))
return NULL;
bool use_property_trees =
settings().use_property_trees || settings().verify_property_trees;
FindClosestMatchingLayerDataForRecursion data_for_recursion;
FindClosestMatchingLayer(screen_space_point, root_layer(),
HitTestVisibleScrollableOrTouchableFunctor(),
property_trees_.transform_tree,
property_trees_.clip_tree, use_property_trees,
&data_for_recursion);
return data_for_recursion.closest_match;
}
static bool LayerHasTouchEventHandlersAt(const gfx::PointF& screen_space_point,
LayerImpl* layer_impl,
const TransformTree& transform_tree,
const ClipTree& clip_tree,
const bool use_property_trees) {
if (layer_impl->touch_event_handler_region().IsEmpty())
return false;
if (!PointHitsRegion(screen_space_point, layer_impl->ScreenSpaceTransform(),
layer_impl->touch_event_handler_region()))
return false;
// At this point, we think the point does hit the touch event handler region
// on the layer, but we need to walk up the parents to ensure that the layer
// was not clipped in such a way that the hit point actually should not hit
// the layer.
if (PointIsClippedBySurfaceOrClipRect(screen_space_point, layer_impl,
transform_tree, clip_tree,
use_property_trees))
return false;
return true;
}
struct FindWheelEventLayerFunctor {
bool operator()(LayerImpl* layer) const {
return layer->have_wheel_event_handlers();
}
};
LayerImpl* LayerTreeImpl::FindLayerWithWheelHandlerThatIsHitByPoint(
const gfx::PointF& screen_space_point) {
if (!root_layer())
return NULL;
bool update_lcd_text = false;
if (!UpdateDrawProperties(update_lcd_text))
return NULL;
bool use_property_trees =
settings().use_property_trees || settings().verify_property_trees;
FindWheelEventLayerFunctor func;
FindClosestMatchingLayerDataForRecursion data_for_recursion;
FindClosestMatchingLayer(
screen_space_point, root_layer(), func, property_trees_.transform_tree,
property_trees_.clip_tree, use_property_trees, &data_for_recursion);
return data_for_recursion.closest_match;
}
struct FindTouchEventLayerFunctor {
bool operator()(LayerImpl* layer) const {
return LayerHasTouchEventHandlersAt(screen_space_point, layer,
transform_tree, clip_tree,
use_property_trees);
}
const gfx::PointF screen_space_point;
const TransformTree& transform_tree;
const ClipTree& clip_tree;
const bool use_property_trees;
};
LayerImpl* LayerTreeImpl::FindLayerThatIsHitByPointInTouchHandlerRegion(
const gfx::PointF& screen_space_point) {
if (!root_layer())
return NULL;
bool update_lcd_text = false;
if (!UpdateDrawProperties(update_lcd_text))
return NULL;
bool use_property_trees =
settings().use_property_trees || settings().verify_property_trees;
FindTouchEventLayerFunctor func = {
screen_space_point, property_trees_.transform_tree,
property_trees_.clip_tree, use_property_trees};
FindClosestMatchingLayerDataForRecursion data_for_recursion;
FindClosestMatchingLayer(
screen_space_point, root_layer(), func, property_trees_.transform_tree,
property_trees_.clip_tree, use_property_trees, &data_for_recursion);
return data_for_recursion.closest_match;
}
void LayerTreeImpl::RegisterSelection(const LayerSelection& selection) {
selection_ = selection;
}
static ViewportSelectionBound ComputeViewportSelectionBound(
const LayerSelectionBound& layer_bound,
LayerImpl* layer,
float device_scale_factor,
const TransformTree& transform_tree,
const ClipTree& clip_tree,
const bool use_property_trees) {
ViewportSelectionBound viewport_bound;
viewport_bound.type = layer_bound.type;
if (!layer || layer_bound.type == SELECTION_BOUND_EMPTY)
return viewport_bound;
auto layer_top = gfx::PointF(layer_bound.edge_top);
auto layer_bottom = gfx::PointF(layer_bound.edge_bottom);
gfx::Transform screen_space_transform = layer->ScreenSpaceTransform();
bool clipped = false;
gfx::PointF screen_top =
MathUtil::MapPoint(screen_space_transform, layer_top, &clipped);
gfx::PointF screen_bottom =
MathUtil::MapPoint(screen_space_transform, layer_bottom, &clipped);
// MapPoint can produce points with NaN components (even when no inputs are
// NaN). Since consumers of ViewportSelectionBounds may round |edge_top| or
// |edge_bottom| (and since rounding will crash on NaN), we return an empty
// bound instead.
if (std::isnan(screen_top.x()) || std::isnan(screen_top.y()) ||
std::isnan(screen_bottom.x()) || std::isnan(screen_bottom.y()))
return ViewportSelectionBound();
const float inv_scale = 1.f / device_scale_factor;
viewport_bound.edge_top = gfx::ScalePoint(screen_top, inv_scale);
viewport_bound.edge_bottom = gfx::ScalePoint(screen_bottom, inv_scale);
// The bottom edge point is used for visibility testing as it is the logical
// focal point for bound selection handles (this may change in the future).
// Shifting the visibility point fractionally inward ensures that neighboring
// or logically coincident layers aligned to integral DPI coordinates will not
// spuriously occlude the bound.
gfx::Vector2dF visibility_offset = layer_top - layer_bottom;
visibility_offset.Scale(device_scale_factor / visibility_offset.Length());
gfx::PointF visibility_point = layer_bottom + visibility_offset;
if (visibility_point.x() <= 0)
visibility_point.set_x(visibility_point.x() + device_scale_factor);
visibility_point =
MathUtil::MapPoint(screen_space_transform, visibility_point, &clipped);
float intersect_distance = 0.f;
viewport_bound.visible =
PointHitsLayer(layer, visibility_point, &intersect_distance,
transform_tree, clip_tree, use_property_trees);
return viewport_bound;
}
void LayerTreeImpl::GetViewportSelection(ViewportSelection* selection) {
DCHECK(selection);
bool use_property_trees =
settings().use_property_trees || settings().verify_property_trees;
selection->start = ComputeViewportSelectionBound(
selection_.start,
selection_.start.layer_id ? LayerById(selection_.start.layer_id) : NULL,
device_scale_factor(), property_trees_.transform_tree,
property_trees_.clip_tree, use_property_trees);
selection->is_editable = selection_.is_editable;
selection->is_empty_text_form_control = selection_.is_empty_text_form_control;
if (selection->start.type == SELECTION_BOUND_CENTER ||
selection->start.type == SELECTION_BOUND_EMPTY) {
selection->end = selection->start;
} else {
selection->end = ComputeViewportSelectionBound(
selection_.end,
selection_.end.layer_id ? LayerById(selection_.end.layer_id) : NULL,
device_scale_factor(), property_trees_.transform_tree,
property_trees_.clip_tree, use_property_trees);
}
}
void LayerTreeImpl::InputScrollAnimationFinished() {
// TODO(majidvp): We should pass in the original starting scroll position here
ScrollState scroll_state(0, 0, 0, 0, 0, 0, false, false, false);
layer_tree_host_impl_->ScrollEnd(&scroll_state);
}
bool LayerTreeImpl::SmoothnessTakesPriority() const {
return layer_tree_host_impl_->GetTreePriority() == SMOOTHNESS_TAKES_PRIORITY;
}
VideoFrameControllerClient* LayerTreeImpl::GetVideoFrameControllerClient()
const {
return layer_tree_host_impl_;
}
void LayerTreeImpl::SetPendingPageScaleAnimation(
scoped_ptr<PendingPageScaleAnimation> pending_animation) {
pending_page_scale_animation_ = std::move(pending_animation);
}
scoped_ptr<PendingPageScaleAnimation>
LayerTreeImpl::TakePendingPageScaleAnimation() {
return std::move(pending_page_scale_animation_);
}
bool LayerTreeImpl::IsAnimatingFilterProperty(const LayerImpl* layer) const {
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->IsAnimatingFilterProperty(layer->id(), tree_type)
: false;
}
bool LayerTreeImpl::IsAnimatingOpacityProperty(const LayerImpl* layer) const {
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->IsAnimatingOpacityProperty(layer->id(), tree_type)
: false;
}
bool LayerTreeImpl::IsAnimatingTransformProperty(const LayerImpl* layer) const {
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->IsAnimatingTransformProperty(layer->id(), tree_type)
: false;
}
bool LayerTreeImpl::HasPotentiallyRunningFilterAnimation(
const LayerImpl* layer) const {
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasPotentiallyRunningFilterAnimation(layer->id(),
tree_type)
: false;
}
bool LayerTreeImpl::HasPotentiallyRunningOpacityAnimation(
const LayerImpl* layer) const {
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasPotentiallyRunningOpacityAnimation(layer->id(),
tree_type)
: false;
}
bool LayerTreeImpl::HasPotentiallyRunningTransformAnimation(
const LayerImpl* layer) const {
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasPotentiallyRunningTransformAnimation(layer->id(),
tree_type)
: false;
}
bool LayerTreeImpl::HasAnyAnimationTargetingProperty(
const LayerImpl* layer,
Animation::TargetProperty property) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasAnyAnimationTargetingProperty(layer->id(), property)
: false;
}
bool LayerTreeImpl::FilterIsAnimatingOnImplOnly(const LayerImpl* layer) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->FilterIsAnimatingOnImplOnly(layer->id())
: false;
}
bool LayerTreeImpl::OpacityIsAnimatingOnImplOnly(const LayerImpl* layer) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->OpacityIsAnimatingOnImplOnly(layer->id())
: false;
}
bool LayerTreeImpl::TransformIsAnimatingOnImplOnly(
const LayerImpl* layer) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->TransformIsAnimatingOnImplOnly(layer->id())
: false;
}
bool LayerTreeImpl::AnimationsPreserveAxisAlignment(
const LayerImpl* layer) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->AnimationsPreserveAxisAlignment(layer->id())
: true;
}
bool LayerTreeImpl::HasOnlyTranslationTransforms(const LayerImpl* layer) const {
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasOnlyTranslationTransforms(layer->id(), tree_type)
: true;
}
bool LayerTreeImpl::MaximumTargetScale(const LayerImpl* layer,
float* max_scale) const {
*max_scale = 0.f;
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()->MaximumTargetScale(
layer->id(), tree_type, max_scale)
: true;
}
bool LayerTreeImpl::AnimationStartScale(const LayerImpl* layer,
float* start_scale) const {
*start_scale = 0.f;
LayerTreeType tree_type =
IsActiveTree() ? LayerTreeType::ACTIVE : LayerTreeType::PENDING;
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()->AnimationStartScale(
layer->id(), tree_type, start_scale)
: true;
}
bool LayerTreeImpl::HasFilterAnimationThatInflatesBounds(
const LayerImpl* layer) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasFilterAnimationThatInflatesBounds(layer->id())
: false;
}
bool LayerTreeImpl::HasTransformAnimationThatInflatesBounds(
const LayerImpl* layer) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasTransformAnimationThatInflatesBounds(layer->id())
: false;
}
bool LayerTreeImpl::HasAnimationThatInflatesBounds(
const LayerImpl* layer) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->HasAnimationThatInflatesBounds(layer->id())
: false;
}
bool LayerTreeImpl::FilterAnimationBoundsForBox(const LayerImpl* layer,
const gfx::BoxF& box,
gfx::BoxF* bounds) const {
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->FilterAnimationBoundsForBox(layer->id(), box, bounds)
: false;
}
bool LayerTreeImpl::TransformAnimationBoundsForBox(const LayerImpl* layer,
const gfx::BoxF& box,
gfx::BoxF* bounds) const {
*bounds = gfx::BoxF();
return layer_tree_host_impl_->animation_host()
? layer_tree_host_impl_->animation_host()
->TransformAnimationBoundsForBox(layer->id(), box, bounds)
: true;
}
} // namespace cc