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chromium / chromium / src / refs/tags/57.0.2935.2 / . / cc / layers / layer_unittest.cc
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// 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/layers/layer.h"
#include <stddef.h>
#include "base/threading/thread_task_runner_handle.h"
#include "cc/animation/animation_host.h"
#include "cc/animation/animation_id_provider.h"
#include "cc/animation/keyframed_animation_curve.h"
#include "cc/base/math_util.h"
#include "cc/input/main_thread_scrolling_reason.h"
#include "cc/layers/layer_impl.h"
#include "cc/layers/solid_color_scrollbar_layer.h"
#include "cc/output/copy_output_request.h"
#include "cc/output/copy_output_result.h"
#include "cc/test/animation_test_common.h"
#include "cc/test/fake_impl_task_runner_provider.h"
#include "cc/test/fake_layer_tree_host.h"
#include "cc/test/fake_layer_tree_host_client.h"
#include "cc/test/fake_layer_tree_host_impl.h"
#include "cc/test/geometry_test_utils.h"
#include "cc/test/layer_internals_for_test.h"
#include "cc/test/layer_test_common.h"
#include "cc/test/stub_layer_tree_host_single_thread_client.h"
#include "cc/test/test_task_graph_runner.h"
#include "cc/trees/layer_tree_host.h"
#include "cc/trees/mutable_properties.h"
#include "cc/trees/single_thread_proxy.h"
#include "cc/trees/transform_node.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "third_party/skia/include/core/SkColor.h"
#include "ui/gfx/geometry/point3_f.h"
#include "ui/gfx/geometry/point_f.h"
#include "ui/gfx/geometry/scroll_offset.h"
#include "ui/gfx/geometry/size.h"
#include "ui/gfx/geometry/vector2d_f.h"
#include "ui/gfx/transform.h"
using ::testing::AnyNumber;
using ::testing::AtLeast;
using ::testing::Mock;
using ::testing::StrictMock;
using ::testing::_;
#define EXPECT_SET_NEEDS_FULL_TREE_SYNC(expect, code_to_test) \
do { \
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times((expect)); \
code_to_test; \
Mock::VerifyAndClearExpectations(layer_tree_); \
} while (false)
#define EXECUTE_AND_VERIFY_SUBTREE_CHANGED(code_to_test) \
code_to_test; \
root->GetLayerTree()->BuildPropertyTreesForTesting(); \
EXPECT_TRUE(root->subtree_property_changed()); \
EXPECT_TRUE( \
root->GetLayerTree()->LayerNeedsPushPropertiesForTesting(root.get())); \
EXPECT_TRUE(child->subtree_property_changed()); \
EXPECT_TRUE( \
child->GetLayerTree()->LayerNeedsPushPropertiesForTesting(child.get())); \
EXPECT_TRUE(grand_child->subtree_property_changed()); \
EXPECT_TRUE(grand_child->GetLayerTree()->LayerNeedsPushPropertiesForTesting( \
grand_child.get()));
#define EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(code_to_test) \
code_to_test; \
EXPECT_FALSE(root->subtree_property_changed()); \
EXPECT_FALSE( \
root->GetLayerTree()->LayerNeedsPushPropertiesForTesting(root.get())); \
EXPECT_FALSE(child->subtree_property_changed()); \
EXPECT_FALSE( \
child->GetLayerTree()->LayerNeedsPushPropertiesForTesting(child.get())); \
EXPECT_FALSE(grand_child->subtree_property_changed()); \
EXPECT_FALSE( \
grand_child->GetLayerTree()->LayerNeedsPushPropertiesForTesting( \
grand_child.get()));
namespace cc {
namespace {
class MockLayerTree : public LayerTree {
public:
MockLayerTree(LayerTreeHostInProcess::InitParams* params,
LayerTreeHost* layer_tree_host)
: LayerTree(params->mutator_host, layer_tree_host) {}
~MockLayerTree() override {}
MOCK_METHOD0(SetNeedsFullTreeSync, void());
};
class MockLayerTreeHost : public LayerTreeHostInProcess {
public:
MockLayerTreeHost(LayerTreeHostSingleThreadClient* single_thread_client,
LayerTreeHostInProcess::InitParams* params)
: LayerTreeHostInProcess(
params,
CompositorMode::SINGLE_THREADED,
base::MakeUnique<StrictMock<MockLayerTree>>(params, this)) {
InitializeSingleThreaded(single_thread_client,
base::ThreadTaskRunnerHandle::Get());
}
MOCK_METHOD0(SetNeedsCommit, void());
MOCK_METHOD0(SetNeedsUpdateLayers, void());
};
class LayerTest : public testing::Test {
public:
LayerTest()
: host_impl_(LayerTreeSettings(),
&task_runner_provider_,
&task_graph_runner_) {
timeline_impl_ =
AnimationTimeline::Create(AnimationIdProvider::NextTimelineId());
timeline_impl_->set_is_impl_only(true);
host_impl_.animation_host()->AddAnimationTimeline(timeline_impl_);
}
const LayerTreeSettings& settings() { return settings_; }
scoped_refptr<AnimationTimeline> timeline_impl() { return timeline_impl_; }
protected:
void SetUp() override {
animation_host_ = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
LayerTreeHostInProcess::InitParams params;
params.client = &fake_client_;
params.settings = &settings_;
params.task_graph_runner = &task_graph_runner_;
params.mutator_host = animation_host_.get();
layer_tree_host_.reset(
new StrictMock<MockLayerTreeHost>(&single_thread_client_, &params));
layer_tree_ = static_cast<StrictMock<MockLayerTree>*>(
layer_tree_host_->GetLayerTree());
}
void TearDown() override {
Mock::VerifyAndClearExpectations(layer_tree_host_.get());
Mock::VerifyAndClearExpectations(layer_tree_);
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times(AnyNumber());
parent_ = nullptr;
child1_ = nullptr;
child2_ = nullptr;
child3_ = nullptr;
grand_child1_ = nullptr;
grand_child2_ = nullptr;
grand_child3_ = nullptr;
layer_tree_->SetRootLayer(nullptr);
animation_host_->SetMutatorHostClient(nullptr);
layer_tree_host_ = nullptr;
animation_host_ = nullptr;
layer_tree_ = nullptr;
}
void VerifyTestTreeInitialState() const {
ASSERT_EQ(3U, parent_->children().size());
EXPECT_EQ(child1_, parent_->children()[0]);
EXPECT_EQ(child2_, parent_->children()[1]);
EXPECT_EQ(child3_, parent_->children()[2]);
EXPECT_EQ(parent_.get(), child1_->parent());
EXPECT_EQ(parent_.get(), child2_->parent());
EXPECT_EQ(parent_.get(), child3_->parent());
ASSERT_EQ(2U, child1_->children().size());
EXPECT_EQ(grand_child1_, child1_->children()[0]);
EXPECT_EQ(grand_child2_, child1_->children()[1]);
EXPECT_EQ(child1_.get(), grand_child1_->parent());
EXPECT_EQ(child1_.get(), grand_child2_->parent());
ASSERT_EQ(1U, child2_->children().size());
EXPECT_EQ(grand_child3_, child2_->children()[0]);
EXPECT_EQ(child2_.get(), grand_child3_->parent());
ASSERT_EQ(0U, child3_->children().size());
}
void CreateSimpleTestTree() {
parent_ = Layer::Create();
child1_ = Layer::Create();
child2_ = Layer::Create();
child3_ = Layer::Create();
grand_child1_ = Layer::Create();
grand_child2_ = Layer::Create();
grand_child3_ = Layer::Create();
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times(AnyNumber());
layer_tree_->SetRootLayer(parent_);
parent_->AddChild(child1_);
parent_->AddChild(child2_);
parent_->AddChild(child3_);
child1_->AddChild(grand_child1_);
child1_->AddChild(grand_child2_);
child2_->AddChild(grand_child3_);
Mock::VerifyAndClearExpectations(layer_tree_);
VerifyTestTreeInitialState();
}
FakeImplTaskRunnerProvider task_runner_provider_;
TestTaskGraphRunner task_graph_runner_;
FakeLayerTreeHostImpl host_impl_;
StubLayerTreeHostSingleThreadClient single_thread_client_;
FakeLayerTreeHostClient fake_client_;
std::unique_ptr<StrictMock<MockLayerTreeHost>> layer_tree_host_;
std::unique_ptr<AnimationHost> animation_host_;
StrictMock<MockLayerTree>* layer_tree_;
scoped_refptr<Layer> parent_;
scoped_refptr<Layer> child1_;
scoped_refptr<Layer> child2_;
scoped_refptr<Layer> child3_;
scoped_refptr<Layer> grand_child1_;
scoped_refptr<Layer> grand_child2_;
scoped_refptr<Layer> grand_child3_;
scoped_refptr<AnimationTimeline> timeline_impl_;
LayerTreeSettings settings_;
};
TEST_F(LayerTest, BasicCreateAndDestroy) {
scoped_refptr<Layer> test_layer = Layer::Create();
ASSERT_TRUE(test_layer.get());
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(0);
test_layer->SetLayerTreeHost(layer_tree_host_.get());
Mock::VerifyAndClearExpectations(layer_tree_host_.get());
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(0);
test_layer->SetLayerTreeHost(nullptr);
}
TEST_F(LayerTest, LayerPropertyChangedForSubtree) {
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times(AtLeast(1));
scoped_refptr<Layer> root = Layer::Create();
scoped_refptr<Layer> child = Layer::Create();
scoped_refptr<Layer> child2 = Layer::Create();
scoped_refptr<Layer> grand_child = Layer::Create();
scoped_refptr<Layer> dummy_layer1 = Layer::Create();
layer_tree_->SetRootLayer(root);
root->AddChild(child);
root->AddChild(child2);
child->AddChild(grand_child);
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(AtLeast(1));
child->SetForceRenderSurfaceForTesting(true);
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(AtLeast(1));
child2->SetScrollParent(grand_child.get());
SkBlendMode arbitrary_blend_mode = SkBlendMode::kMultiply;
std::unique_ptr<LayerImpl> root_impl =
LayerImpl::Create(host_impl_.active_tree(), root->id());
std::unique_ptr<LayerImpl> child_impl =
LayerImpl::Create(host_impl_.active_tree(), child->id());
std::unique_ptr<LayerImpl> child2_impl =
LayerImpl::Create(host_impl_.active_tree(), child2->id());
std::unique_ptr<LayerImpl> grand_child_impl =
LayerImpl::Create(host_impl_.active_tree(), grand_child->id());
std::unique_ptr<LayerImpl> dummy_layer1_impl =
LayerImpl::Create(host_impl_.active_tree(), dummy_layer1->id());
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetMaskLayer(dummy_layer1.get()));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get());
dummy_layer1->PushPropertiesTo(dummy_layer1_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetMasksToBounds(true));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetContentsOpaque(true));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetShouldFlattenTransform(false));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->Set3dSortingContextId(1));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetDoubleSided(false));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetHideLayerAndSubtree(true));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetBlendMode(arbitrary_blend_mode));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
// Should be a different size than previous call, to ensure it marks tree
// changed.
gfx::Size arbitrary_size = gfx::Size(111, 222);
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetBounds(arbitrary_size));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
FilterOperations arbitrary_filters;
arbitrary_filters.Append(FilterOperation::CreateOpacityFilter(0.5f));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(root->SetFilters(arbitrary_filters));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
EXECUTE_AND_VERIFY_SUBTREE_CHANGED(
root->SetBackgroundFilters(arbitrary_filters));
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get()));
gfx::PointF arbitrary_point_f = gfx::PointF(0.125f, 0.25f);
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
root->SetPosition(arbitrary_point_f);
TransformNode* node = layer_tree_->property_trees()->transform_tree.Node(
root->transform_tree_index());
EXPECT_TRUE(node->transform_changed);
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get());
layer_tree_->property_trees()->ResetAllChangeTracking());
EXPECT_FALSE(node->transform_changed);
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
child->SetPosition(arbitrary_point_f);
node = layer_tree_->property_trees()->transform_tree.Node(
child->transform_tree_index());
EXPECT_TRUE(node->transform_changed);
// child2 is not in the subtree of child, but its scroll parent is. So, its
// to_screen will be effected by change in position of child2.
layer_tree_->property_trees()->transform_tree.UpdateTransforms(
child2->transform_tree_index());
node = layer_tree_->property_trees()->transform_tree.Node(
child2->transform_tree_index());
EXPECT_TRUE(node->transform_changed);
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
child->PushPropertiesTo(child_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get());
layer_tree_->property_trees()->ResetAllChangeTracking());
node = layer_tree_->property_trees()->transform_tree.Node(
child->transform_tree_index());
EXPECT_FALSE(node->transform_changed);
gfx::Point3F arbitrary_point_3f = gfx::Point3F(0.125f, 0.25f, 0.f);
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
root->SetTransformOrigin(arbitrary_point_3f);
node = layer_tree_->property_trees()->transform_tree.Node(
root->transform_tree_index());
EXPECT_TRUE(node->transform_changed);
EXECUTE_AND_VERIFY_SUBTREE_CHANGES_RESET(
root->PushPropertiesTo(root_impl.get());
child->PushPropertiesTo(child_impl.get());
child2->PushPropertiesTo(child2_impl.get());
grand_child->PushPropertiesTo(grand_child_impl.get());
layer_tree_->property_trees()->ResetAllChangeTracking());
gfx::Transform arbitrary_transform;
arbitrary_transform.Scale3d(0.1f, 0.2f, 0.3f);
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(1);
root->SetTransform(arbitrary_transform);
node = layer_tree_->property_trees()->transform_tree.Node(
root->transform_tree_index());
EXPECT_TRUE(node->transform_changed);
}
TEST_F(LayerTest, AddAndRemoveChild) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child = Layer::Create();
// Upon creation, layers should not have children or parent.
ASSERT_EQ(0U, parent->children().size());
EXPECT_FALSE(child->parent());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(parent));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->AddChild(child));
ASSERT_EQ(1U, parent->children().size());
EXPECT_EQ(child.get(), parent->children()[0]);
EXPECT_EQ(parent.get(), child->parent());
EXPECT_EQ(parent.get(), child->RootLayer());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(AtLeast(1), child->RemoveFromParent());
}
TEST_F(LayerTest, AddSameChildTwice) {
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times(AtLeast(1));
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child = Layer::Create();
layer_tree_->SetRootLayer(parent);
ASSERT_EQ(0u, parent->children().size());
parent->AddChild(child);
ASSERT_EQ(1u, parent->children().size());
EXPECT_EQ(parent.get(), child->parent());
parent->AddChild(child);
ASSERT_EQ(1u, parent->children().size());
EXPECT_EQ(parent.get(), child->parent());
}
TEST_F(LayerTest, InsertChild) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child1 = Layer::Create();
scoped_refptr<Layer> child2 = Layer::Create();
scoped_refptr<Layer> child3 = Layer::Create();
scoped_refptr<Layer> child4 = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(parent));
ASSERT_EQ(0U, parent->children().size());
// Case 1: inserting to empty list.
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child3, 0));
ASSERT_EQ(1U, parent->children().size());
EXPECT_EQ(child3, parent->children()[0]);
EXPECT_EQ(parent.get(), child3->parent());
// Case 2: inserting to beginning of list
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child1, 0));
ASSERT_EQ(2U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
EXPECT_EQ(child3, parent->children()[1]);
EXPECT_EQ(parent.get(), child1->parent());
// Case 3: inserting to middle of list
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child2, 1));
ASSERT_EQ(3U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
EXPECT_EQ(child2, parent->children()[1]);
EXPECT_EQ(child3, parent->children()[2]);
EXPECT_EQ(parent.get(), child2->parent());
// Case 4: inserting to end of list
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child4, 3));
ASSERT_EQ(4U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
EXPECT_EQ(child2, parent->children()[1]);
EXPECT_EQ(child3, parent->children()[2]);
EXPECT_EQ(child4, parent->children()[3]);
EXPECT_EQ(parent.get(), child4->parent());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(nullptr));
}
TEST_F(LayerTest, InsertChildPastEndOfList) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child1 = Layer::Create();
scoped_refptr<Layer> child2 = Layer::Create();
ASSERT_EQ(0U, parent->children().size());
// insert to an out-of-bounds index
parent->InsertChild(child1, 53);
ASSERT_EQ(1U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
// insert another child to out-of-bounds, when list is not already empty.
parent->InsertChild(child2, 2459);
ASSERT_EQ(2U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
EXPECT_EQ(child2, parent->children()[1]);
}
TEST_F(LayerTest, InsertSameChildTwice) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child1 = Layer::Create();
scoped_refptr<Layer> child2 = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(parent));
ASSERT_EQ(0U, parent->children().size());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child1, 0));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child2, 1));
ASSERT_EQ(2U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
EXPECT_EQ(child2, parent->children()[1]);
// Inserting the same child again should cause the child to be removed and
// re-inserted at the new location.
EXPECT_SET_NEEDS_FULL_TREE_SYNC(AtLeast(1), parent->InsertChild(child1, 1));
// child1 should now be at the end of the list.
ASSERT_EQ(2U, parent->children().size());
EXPECT_EQ(child2, parent->children()[0]);
EXPECT_EQ(child1, parent->children()[1]);
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(nullptr));
}
TEST_F(LayerTest, ReplaceChildWithNewChild) {
CreateSimpleTestTree();
scoped_refptr<Layer> child4 = Layer::Create();
EXPECT_FALSE(child4->parent());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(
AtLeast(1), parent_->ReplaceChild(child2_.get(), child4));
EXPECT_FALSE(parent_->NeedsDisplayForTesting());
EXPECT_FALSE(child1_->NeedsDisplayForTesting());
EXPECT_FALSE(child2_->NeedsDisplayForTesting());
EXPECT_FALSE(child3_->NeedsDisplayForTesting());
EXPECT_FALSE(child4->NeedsDisplayForTesting());
ASSERT_EQ(static_cast<size_t>(3), parent_->children().size());
EXPECT_EQ(child1_, parent_->children()[0]);
EXPECT_EQ(child4, parent_->children()[1]);
EXPECT_EQ(child3_, parent_->children()[2]);
EXPECT_EQ(parent_.get(), child4->parent());
EXPECT_FALSE(child2_->parent());
}
TEST_F(LayerTest, ReplaceChildWithNewChildThatHasOtherParent) {
CreateSimpleTestTree();
// create another simple tree with test_layer and child4.
scoped_refptr<Layer> test_layer = Layer::Create();
scoped_refptr<Layer> child4 = Layer::Create();
test_layer->AddChild(child4);
ASSERT_EQ(1U, test_layer->children().size());
EXPECT_EQ(child4, test_layer->children()[0]);
EXPECT_EQ(test_layer.get(), child4->parent());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(
AtLeast(1), parent_->ReplaceChild(child2_.get(), child4));
ASSERT_EQ(3U, parent_->children().size());
EXPECT_EQ(child1_, parent_->children()[0]);
EXPECT_EQ(child4, parent_->children()[1]);
EXPECT_EQ(child3_, parent_->children()[2]);
EXPECT_EQ(parent_.get(), child4->parent());
// test_layer should no longer have child4,
// and child2 should no longer have a parent.
ASSERT_EQ(0U, test_layer->children().size());
EXPECT_FALSE(child2_->parent());
}
TEST_F(LayerTest, DeleteRemovedScrollParent) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child1 = Layer::Create();
scoped_refptr<Layer> child2 = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(parent));
ASSERT_EQ(0U, parent->children().size());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child1, 0));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child2, 1));
ASSERT_EQ(2U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
EXPECT_EQ(child2, parent->children()[1]);
EXPECT_SET_NEEDS_COMMIT(2, child1->SetScrollParent(child2.get()));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, child2->RemoveFromParent());
child1->ResetNeedsPushPropertiesForTesting();
EXPECT_SET_NEEDS_COMMIT(1, child2 = nullptr);
EXPECT_TRUE(layer_tree_->LayerNeedsPushPropertiesForTesting(child1.get()));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(nullptr));
}
TEST_F(LayerTest, DeleteRemovedScrollChild) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child1 = Layer::Create();
scoped_refptr<Layer> child2 = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(parent));
ASSERT_EQ(0U, parent->children().size());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child1, 0));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, parent->InsertChild(child2, 1));
ASSERT_EQ(2U, parent->children().size());
EXPECT_EQ(child1, parent->children()[0]);
EXPECT_EQ(child2, parent->children()[1]);
EXPECT_SET_NEEDS_COMMIT(2, child1->SetScrollParent(child2.get()));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, child1->RemoveFromParent());
child2->ResetNeedsPushPropertiesForTesting();
EXPECT_SET_NEEDS_COMMIT(1, child1 = nullptr);
EXPECT_TRUE(layer_tree_->LayerNeedsPushPropertiesForTesting(child2.get()));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(nullptr));
}
TEST_F(LayerTest, ReplaceChildWithSameChild) {
CreateSimpleTestTree();
// SetNeedsFullTreeSync / SetNeedsCommit should not be called because its the
// same child.
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(0);
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times(0);
parent_->ReplaceChild(child2_.get(), child2_);
VerifyTestTreeInitialState();
}
TEST_F(LayerTest, RemoveAllChildren) {
CreateSimpleTestTree();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(AtLeast(3), parent_->RemoveAllChildren());
ASSERT_EQ(0U, parent_->children().size());
EXPECT_FALSE(child1_->parent());
EXPECT_FALSE(child2_->parent());
EXPECT_FALSE(child3_->parent());
}
TEST_F(LayerTest, SetChildren) {
scoped_refptr<Layer> old_parent = Layer::Create();
scoped_refptr<Layer> new_parent = Layer::Create();
scoped_refptr<Layer> child1 = Layer::Create();
scoped_refptr<Layer> child2 = Layer::Create();
LayerList new_children;
new_children.push_back(child1);
new_children.push_back(child2);
// Set up and verify initial test conditions: child1 has a parent, child2 has
// no parent.
old_parent->AddChild(child1);
ASSERT_EQ(0U, new_parent->children().size());
EXPECT_EQ(old_parent.get(), child1->parent());
EXPECT_FALSE(child2->parent());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(new_parent));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(
AtLeast(1), new_parent->SetChildren(new_children));
ASSERT_EQ(2U, new_parent->children().size());
EXPECT_EQ(new_parent.get(), child1->parent());
EXPECT_EQ(new_parent.get(), child2->parent());
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(nullptr));
}
TEST_F(LayerTest, HasAncestor) {
scoped_refptr<Layer> parent = Layer::Create();
EXPECT_FALSE(parent->HasAncestor(parent.get()));
scoped_refptr<Layer> child = Layer::Create();
parent->AddChild(child);
EXPECT_FALSE(child->HasAncestor(child.get()));
EXPECT_TRUE(child->HasAncestor(parent.get()));
EXPECT_FALSE(parent->HasAncestor(child.get()));
scoped_refptr<Layer> child_child = Layer::Create();
child->AddChild(child_child);
EXPECT_FALSE(child_child->HasAncestor(child_child.get()));
EXPECT_TRUE(child_child->HasAncestor(parent.get()));
EXPECT_TRUE(child_child->HasAncestor(child.get()));
EXPECT_FALSE(parent->HasAncestor(child.get()));
EXPECT_FALSE(parent->HasAncestor(child_child.get()));
}
TEST_F(LayerTest, GetRootLayerAfterTreeManipulations) {
CreateSimpleTestTree();
// For this test we don't care about SetNeedsFullTreeSync calls.
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times(AnyNumber());
scoped_refptr<Layer> child4 = Layer::Create();
EXPECT_EQ(parent_.get(), parent_->RootLayer());
EXPECT_EQ(parent_.get(), child1_->RootLayer());
EXPECT_EQ(parent_.get(), child2_->RootLayer());
EXPECT_EQ(parent_.get(), child3_->RootLayer());
EXPECT_EQ(child4.get(), child4->RootLayer());
EXPECT_EQ(parent_.get(), grand_child1_->RootLayer());
EXPECT_EQ(parent_.get(), grand_child2_->RootLayer());
EXPECT_EQ(parent_.get(), grand_child3_->RootLayer());
child1_->RemoveFromParent();
// |child1| and its children, grand_child1 and grand_child2 are now on a
// separate subtree.
EXPECT_EQ(parent_.get(), parent_->RootLayer());
EXPECT_EQ(child1_.get(), child1_->RootLayer());
EXPECT_EQ(parent_.get(), child2_->RootLayer());
EXPECT_EQ(parent_.get(), child3_->RootLayer());
EXPECT_EQ(child4.get(), child4->RootLayer());
EXPECT_EQ(child1_.get(), grand_child1_->RootLayer());
EXPECT_EQ(child1_.get(), grand_child2_->RootLayer());
EXPECT_EQ(parent_.get(), grand_child3_->RootLayer());
grand_child3_->AddChild(child4);
EXPECT_EQ(parent_.get(), parent_->RootLayer());
EXPECT_EQ(child1_.get(), child1_->RootLayer());
EXPECT_EQ(parent_.get(), child2_->RootLayer());
EXPECT_EQ(parent_.get(), child3_->RootLayer());
EXPECT_EQ(parent_.get(), child4->RootLayer());
EXPECT_EQ(child1_.get(), grand_child1_->RootLayer());
EXPECT_EQ(child1_.get(), grand_child2_->RootLayer());
EXPECT_EQ(parent_.get(), grand_child3_->RootLayer());
child2_->ReplaceChild(grand_child3_.get(), child1_);
// |grand_child3| gets orphaned and the child1 subtree gets planted back into
// the tree under child2.
EXPECT_EQ(parent_.get(), parent_->RootLayer());
EXPECT_EQ(parent_.get(), child1_->RootLayer());
EXPECT_EQ(parent_.get(), child2_->RootLayer());
EXPECT_EQ(parent_.get(), child3_->RootLayer());
EXPECT_EQ(grand_child3_.get(), child4->RootLayer());
EXPECT_EQ(parent_.get(), grand_child1_->RootLayer());
EXPECT_EQ(parent_.get(), grand_child2_->RootLayer());
EXPECT_EQ(grand_child3_.get(), grand_child3_->RootLayer());
}
TEST_F(LayerTest, CheckSetNeedsDisplayCausesCorrectBehavior) {
// The semantics for SetNeedsDisplay which are tested here:
// 1. sets NeedsDisplay flag appropriately.
// 2. indirectly calls SetNeedsUpdate, exactly once for each call to
// SetNeedsDisplay.
scoped_refptr<Layer> test_layer = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(test_layer));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetIsDrawable(true));
gfx::Size test_bounds = gfx::Size(501, 508);
gfx::Rect dirty_rect = gfx::Rect(10, 15, 1, 2);
gfx::Rect out_of_bounds_dirty_rect = gfx::Rect(400, 405, 500, 502);
// Before anything, test_layer should not be dirty.
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
// This is just initialization, but SetNeedsCommit behavior is verified anyway
// to avoid warnings.
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetBounds(test_bounds));
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
// The real test begins here.
test_layer->ResetNeedsDisplayForTesting();
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
// Case 1: Layer should accept dirty rects that go beyond its bounds.
test_layer->ResetNeedsDisplayForTesting();
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
EXPECT_SET_NEEDS_UPDATE(
1, test_layer->SetNeedsDisplayRect(out_of_bounds_dirty_rect));
EXPECT_TRUE(test_layer->NeedsDisplayForTesting());
test_layer->ResetNeedsDisplayForTesting();
// Case 2: SetNeedsDisplay() without the dirty rect arg.
test_layer->ResetNeedsDisplayForTesting();
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
EXPECT_SET_NEEDS_UPDATE(1, test_layer->SetNeedsDisplay());
EXPECT_TRUE(test_layer->NeedsDisplayForTesting());
test_layer->ResetNeedsDisplayForTesting();
// Case 3: SetNeedsDisplay() with an empty rect.
test_layer->ResetNeedsDisplayForTesting();
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
EXPECT_SET_NEEDS_COMMIT(0, test_layer->SetNeedsDisplayRect(gfx::Rect()));
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
// Case 4: SetNeedsDisplay() with a non-drawable layer
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetIsDrawable(false));
test_layer->ResetNeedsDisplayForTesting();
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
EXPECT_SET_NEEDS_UPDATE(0, test_layer->SetNeedsDisplayRect(dirty_rect));
EXPECT_TRUE(test_layer->NeedsDisplayForTesting());
}
TEST_F(LayerTest, TestSettingMainThreadScrollingReason) {
scoped_refptr<Layer> test_layer = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(test_layer));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetIsDrawable(true));
// sanity check of initial test condition
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
uint32_t reasons = 0, reasons_to_clear = 0, reasons_after_clearing = 0;
reasons |= MainThreadScrollingReason::kNonFastScrollableRegion;
reasons |= MainThreadScrollingReason::kContinuingMainThreadScroll;
reasons |= MainThreadScrollingReason::kScrollbarScrolling;
reasons_to_clear |= MainThreadScrollingReason::kContinuingMainThreadScroll;
reasons_to_clear |= MainThreadScrollingReason::kThreadedScrollingDisabled;
reasons_after_clearing |= MainThreadScrollingReason::kNonFastScrollableRegion;
reasons_after_clearing |= MainThreadScrollingReason::kScrollbarScrolling;
// Check that the reasons are added correctly.
EXPECT_SET_NEEDS_COMMIT(
1, test_layer->AddMainThreadScrollingReasons(
MainThreadScrollingReason::kNonFastScrollableRegion));
EXPECT_SET_NEEDS_COMMIT(
1, test_layer->AddMainThreadScrollingReasons(
MainThreadScrollingReason::kContinuingMainThreadScroll));
EXPECT_SET_NEEDS_COMMIT(1,
test_layer->AddMainThreadScrollingReasons(
MainThreadScrollingReason::kScrollbarScrolling));
EXPECT_EQ(reasons, test_layer->main_thread_scrolling_reasons());
// Check that the reasons can be selectively cleared.
EXPECT_SET_NEEDS_COMMIT(
1, test_layer->ClearMainThreadScrollingReasons(reasons_to_clear));
EXPECT_EQ(reasons_after_clearing,
test_layer->main_thread_scrolling_reasons());
// Check that clearing non-set reasons doesn't set needs commit.
reasons_to_clear = 0;
reasons_to_clear |= MainThreadScrollingReason::kThreadedScrollingDisabled;
reasons_to_clear |= MainThreadScrollingReason::kNoScrollingLayer;
EXPECT_SET_NEEDS_COMMIT(
0, test_layer->ClearMainThreadScrollingReasons(reasons_to_clear));
EXPECT_EQ(reasons_after_clearing,
test_layer->main_thread_scrolling_reasons());
// Check that adding an existing condition doesn't set needs commit.
EXPECT_SET_NEEDS_COMMIT(
0, test_layer->AddMainThreadScrollingReasons(
MainThreadScrollingReason::kNonFastScrollableRegion));
}
TEST_F(LayerTest, CheckPropertyChangeCausesCorrectBehavior) {
scoped_refptr<Layer> test_layer = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(test_layer));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetIsDrawable(true));
scoped_refptr<Layer> dummy_layer1 = Layer::Create();
// sanity check of initial test condition
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
// Next, test properties that should call SetNeedsCommit (but not
// SetNeedsDisplay). All properties need to be set to new values in order for
// SetNeedsCommit to be called.
EXPECT_SET_NEEDS_COMMIT(
1, test_layer->SetTransformOrigin(gfx::Point3F(1.23f, 4.56f, 0.f)));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetBackgroundColor(SK_ColorLTGRAY));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetMasksToBounds(true));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetOpacity(0.5f));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetBlendMode(SkBlendMode::kHue));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetIsRootForIsolatedGroup(true));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetContentsOpaque(true));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetPosition(gfx::PointF(4.f, 9.f)));
// We can use any layer pointer here since we aren't syncing for real.
EXPECT_SET_NEEDS_COMMIT(1,
test_layer->SetScrollClipLayerId(test_layer->id()));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetUserScrollable(true, false));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetScrollOffset(
gfx::ScrollOffset(10, 10)));
EXPECT_SET_NEEDS_COMMIT(
1, test_layer->AddMainThreadScrollingReasons(
MainThreadScrollingReason::kNonFastScrollableRegion));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetNonFastScrollableRegion(
Region(gfx::Rect(1, 1, 2, 2))));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetTransform(
gfx::Transform(0.0, 0.0, 0.0, 0.0, 0.0, 0.0)));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetDoubleSided(false));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetTouchEventHandlerRegion(
gfx::Rect(10, 10)));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetForceRenderSurfaceForTesting(true));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetHideLayerAndSubtree(true));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetElementId(ElementId(2, 0)));
EXPECT_SET_NEEDS_COMMIT(
1, test_layer->SetMutableProperties(MutableProperty::kTransform));
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, test_layer->SetMaskLayer(
dummy_layer1.get()));
// The above tests should not have caused a change to the needs_display flag.
EXPECT_FALSE(test_layer->NeedsDisplayForTesting());
// As layers are removed from the tree, they will cause a tree sync.
EXPECT_CALL(*layer_tree_, SetNeedsFullTreeSync()).Times((AnyNumber()));
}
TEST_F(LayerTest, PushPropertiesAccumulatesUpdateRect) {
scoped_refptr<Layer> test_layer = Layer::Create();
std::unique_ptr<LayerImpl> impl_layer =
LayerImpl::Create(host_impl_.active_tree(), 1);
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(test_layer));
host_impl_.active_tree()->SetRootLayerForTesting(std::move(impl_layer));
host_impl_.active_tree()->BuildLayerListForTesting();
LayerImpl* impl_layer_ptr = host_impl_.active_tree()->LayerById(1);
test_layer->SetNeedsDisplayRect(gfx::Rect(5, 5));
test_layer->PushPropertiesTo(impl_layer_ptr);
EXPECT_FLOAT_RECT_EQ(gfx::RectF(0.f, 0.f, 5.f, 5.f),
impl_layer_ptr->update_rect());
// The LayerImpl's update_rect() should be accumulated here, since we did not
// do anything to clear it.
test_layer->SetNeedsDisplayRect(gfx::Rect(10, 10, 5, 5));
test_layer->PushPropertiesTo(impl_layer_ptr);
EXPECT_FLOAT_RECT_EQ(gfx::RectF(0.f, 0.f, 15.f, 15.f),
impl_layer_ptr->update_rect());
// If we do clear the LayerImpl side, then the next update_rect() should be
// fresh without accumulation.
host_impl_.active_tree()->ResetAllChangeTracking();
test_layer->SetNeedsDisplayRect(gfx::Rect(10, 10, 5, 5));
test_layer->PushPropertiesTo(impl_layer_ptr);
EXPECT_FLOAT_RECT_EQ(gfx::RectF(10.f, 10.f, 5.f, 5.f),
impl_layer_ptr->update_rect());
}
TEST_F(LayerTest, PushPropertiesCausesLayerPropertyChangedForTransform) {
scoped_refptr<Layer> test_layer = Layer::Create();
std::unique_ptr<LayerImpl> impl_layer =
LayerImpl::Create(host_impl_.active_tree(), 1);
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(test_layer));
gfx::Transform transform;
transform.Rotate(45.0);
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetTransform(transform));
EXPECT_FALSE(impl_layer->LayerPropertyChanged());
test_layer->PushPropertiesTo(impl_layer.get());
EXPECT_TRUE(impl_layer->LayerPropertyChanged());
}
TEST_F(LayerTest, PushPropertiesCausesLayerPropertyChangedForOpacity) {
scoped_refptr<Layer> test_layer = Layer::Create();
std::unique_ptr<LayerImpl> impl_layer =
LayerImpl::Create(host_impl_.active_tree(), 1);
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(test_layer));
EXPECT_SET_NEEDS_COMMIT(1, test_layer->SetOpacity(0.5f));
EXPECT_FALSE(impl_layer->LayerPropertyChanged());
test_layer->PushPropertiesTo(impl_layer.get());
EXPECT_TRUE(impl_layer->LayerPropertyChanged());
}
TEST_F(LayerTest, MaskHasParent) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child = Layer::Create();
scoped_refptr<Layer> mask = Layer::Create();
scoped_refptr<Layer> mask_replacement = Layer::Create();
parent->AddChild(child);
child->SetMaskLayer(mask.get());
EXPECT_EQ(parent.get(), child->parent());
EXPECT_EQ(child.get(), mask->parent());
child->SetMaskLayer(mask_replacement.get());
EXPECT_EQ(nullptr, mask->parent());
EXPECT_EQ(child.get(), mask_replacement->parent());
}
class LayerTreeHostFactory {
public:
std::unique_ptr<LayerTreeHost> Create(MutatorHost* mutator_host) {
return Create(LayerTreeSettings(), mutator_host);
}
std::unique_ptr<LayerTreeHost> Create(LayerTreeSettings settings,
MutatorHost* mutator_host) {
LayerTreeHostInProcess::InitParams params;
params.client = &client_;
params.task_graph_runner = &task_graph_runner_;
params.settings = &settings;
params.main_task_runner = base::ThreadTaskRunnerHandle::Get();
params.mutator_host = mutator_host;
return LayerTreeHostInProcess::CreateSingleThreaded(&single_thread_client_,
&params);
}
private:
FakeLayerTreeHostClient client_;
StubLayerTreeHostSingleThreadClient single_thread_client_;
TestTaskGraphRunner task_graph_runner_;
};
void AssertLayerTreeHostMatchesForSubtree(Layer* layer, LayerTreeHost* host) {
EXPECT_EQ(host, layer->GetLayerTreeHostForTesting());
for (size_t i = 0; i < layer->children().size(); ++i)
AssertLayerTreeHostMatchesForSubtree(layer->children()[i].get(), host);
if (layer->mask_layer())
AssertLayerTreeHostMatchesForSubtree(layer->mask_layer(), host);
}
class LayerLayerTreeHostTest : public testing::Test {};
TEST_F(LayerLayerTreeHostTest, EnteringTree) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child = Layer::Create();
scoped_refptr<Layer> mask = Layer::Create();
// Set up a detached tree of layers. The host pointer should be nil for these
// layers.
parent->AddChild(child);
child->SetMaskLayer(mask.get());
AssertLayerTreeHostMatchesForSubtree(parent.get(), nullptr);
LayerTreeHostFactory factory;
auto animation_host = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> layer_tree_host =
factory.Create(animation_host.get());
LayerTree* layer_tree = layer_tree_host->GetLayerTree();
// Setting the root layer should set the host pointer for all layers in the
// tree.
layer_tree->SetRootLayer(parent.get());
AssertLayerTreeHostMatchesForSubtree(parent.get(), layer_tree_host.get());
// Clearing the root layer should also clear out the host pointers for all
// layers in the tree.
layer_tree->SetRootLayer(nullptr);
AssertLayerTreeHostMatchesForSubtree(parent.get(), nullptr);
}
TEST_F(LayerLayerTreeHostTest, AddingLayerSubtree) {
scoped_refptr<Layer> parent = Layer::Create();
LayerTreeHostFactory factory;
auto animation_host = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> layer_tree_host =
factory.Create(animation_host.get());
LayerTree* layer_tree = layer_tree_host->GetLayerTree();
layer_tree->SetRootLayer(parent.get());
EXPECT_EQ(parent->GetLayerTreeHostForTesting(), layer_tree_host.get());
// Adding a subtree to a layer already associated with a host should set the
// host pointer on all layers in that subtree.
scoped_refptr<Layer> child = Layer::Create();
scoped_refptr<Layer> grand_child = Layer::Create();
child->AddChild(grand_child);
// Masks should pick up the new host too.
scoped_refptr<Layer> child_mask = Layer::Create();
child->SetMaskLayer(child_mask.get());
parent->AddChild(child);
AssertLayerTreeHostMatchesForSubtree(parent.get(), layer_tree_host.get());
layer_tree->SetRootLayer(nullptr);
}
TEST_F(LayerLayerTreeHostTest, ChangeHost) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> child = Layer::Create();
scoped_refptr<Layer> mask = Layer::Create();
// Same setup as the previous test.
parent->AddChild(child);
child->SetMaskLayer(mask.get());
LayerTreeHostFactory factory;
auto animation_host1 = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> first_layer_tree_host =
factory.Create(animation_host1.get());
first_layer_tree_host->GetLayerTree()->SetRootLayer(parent.get());
AssertLayerTreeHostMatchesForSubtree(parent.get(),
first_layer_tree_host.get());
// Now re-root the tree to a new host (simulating what we do on a context lost
// event). This should update the host pointers for all layers in the tree.
auto animation_host2 = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> second_layer_tree_host =
factory.Create(animation_host2.get());
second_layer_tree_host->GetLayerTree()->SetRootLayer(parent.get());
AssertLayerTreeHostMatchesForSubtree(parent.get(),
second_layer_tree_host.get());
second_layer_tree_host->GetLayerTree()->SetRootLayer(nullptr);
}
TEST_F(LayerLayerTreeHostTest, ChangeHostInSubtree) {
scoped_refptr<Layer> first_parent = Layer::Create();
scoped_refptr<Layer> first_child = Layer::Create();
scoped_refptr<Layer> second_parent = Layer::Create();
scoped_refptr<Layer> second_child = Layer::Create();
scoped_refptr<Layer> second_grand_child = Layer::Create();
// First put all children under the first parent and set the first host.
first_parent->AddChild(first_child);
second_child->AddChild(second_grand_child);
first_parent->AddChild(second_child);
LayerTreeHostFactory factory;
auto animation_host1 = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> first_layer_tree_host =
factory.Create(animation_host1.get());
first_layer_tree_host->GetLayerTree()->SetRootLayer(first_parent.get());
AssertLayerTreeHostMatchesForSubtree(first_parent.get(),
first_layer_tree_host.get());
// Now reparent the subtree starting at second_child to a layer in a different
// tree.
auto animation_host2 = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> second_layer_tree_host =
factory.Create(animation_host2.get());
second_layer_tree_host->GetLayerTree()->SetRootLayer(second_parent.get());
second_parent->AddChild(second_child);
// The moved layer and its children should point to the new host.
EXPECT_EQ(second_layer_tree_host.get(),
second_child->GetLayerTreeHostForTesting());
EXPECT_EQ(second_layer_tree_host.get(),
second_grand_child->GetLayerTreeHostForTesting());
// Test over, cleanup time.
first_layer_tree_host->GetLayerTree()->SetRootLayer(nullptr);
second_layer_tree_host->GetLayerTree()->SetRootLayer(nullptr);
}
TEST_F(LayerLayerTreeHostTest, ReplaceMaskLayer) {
scoped_refptr<Layer> parent = Layer::Create();
scoped_refptr<Layer> mask = Layer::Create();
scoped_refptr<Layer> mask_child = Layer::Create();
scoped_refptr<Layer> mask_replacement = Layer::Create();
parent->SetMaskLayer(mask.get());
mask->AddChild(mask_child);
LayerTreeHostFactory factory;
auto animation_host = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> layer_tree_host =
factory.Create(animation_host.get());
layer_tree_host->GetLayerTree()->SetRootLayer(parent.get());
AssertLayerTreeHostMatchesForSubtree(parent.get(), layer_tree_host.get());
// Replacing the mask should clear out the old mask's subtree's host pointers.
parent->SetMaskLayer(mask_replacement.get());
EXPECT_EQ(nullptr, mask->GetLayerTreeHostForTesting());
EXPECT_EQ(nullptr, mask_child->GetLayerTreeHostForTesting());
// Test over, cleanup time.
layer_tree_host->GetLayerTree()->SetRootLayer(nullptr);
}
TEST_F(LayerLayerTreeHostTest, DestroyHostWithNonNullRootLayer) {
scoped_refptr<Layer> root = Layer::Create();
scoped_refptr<Layer> child = Layer::Create();
root->AddChild(child);
LayerTreeHostFactory factory;
auto animation_host = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> layer_tree_host =
factory.Create(animation_host.get());
layer_tree_host->GetLayerTree()->SetRootLayer(root);
}
TEST_F(LayerTest, SafeOpaqueBackgroundColor) {
LayerTreeHostFactory factory;
auto animation_host = AnimationHost::CreateForTesting(ThreadInstance::MAIN);
std::unique_ptr<LayerTreeHost> layer_tree_host =
factory.Create(animation_host.get());
LayerTree* layer_tree = layer_tree_host->GetLayerTree();
scoped_refptr<Layer> layer = Layer::Create();
layer_tree->SetRootLayer(layer);
for (int contents_opaque = 0; contents_opaque < 2; ++contents_opaque) {
for (int layer_opaque = 0; layer_opaque < 2; ++layer_opaque) {
for (int host_opaque = 0; host_opaque < 2; ++host_opaque) {
layer->SetContentsOpaque(!!contents_opaque);
layer->SetBackgroundColor(layer_opaque ? SK_ColorRED
: SK_ColorTRANSPARENT);
layer_tree->set_background_color(host_opaque ? SK_ColorRED
: SK_ColorTRANSPARENT);
layer_tree->property_trees()->needs_rebuild = true;
layer_tree_host->GetLayerTree()->BuildPropertyTreesForTesting();
SkColor safe_color = layer->SafeOpaqueBackgroundColor();
if (contents_opaque) {
EXPECT_EQ(SkColorGetA(safe_color), 255u)
<< "Flags: " << contents_opaque << ", " << layer_opaque << ", "
<< host_opaque << "\n";
} else {
EXPECT_NE(SkColorGetA(safe_color), 255u)
<< "Flags: " << contents_opaque << ", " << layer_opaque << ", "
<< host_opaque << "\n";
}
}
}
}
}
class DrawsContentChangeLayer : public Layer {
public:
static scoped_refptr<DrawsContentChangeLayer> Create() {
return make_scoped_refptr(new DrawsContentChangeLayer());
}
void SetLayerTreeHost(LayerTreeHost* host) override {
Layer::SetLayerTreeHost(host);
SetFakeDrawsContent(!fake_draws_content_);
}
bool HasDrawableContent() const override {
return fake_draws_content_ && Layer::HasDrawableContent();
}
void SetFakeDrawsContent(bool fake_draws_content) {
fake_draws_content_ = fake_draws_content;
UpdateDrawsContent(HasDrawableContent());
}
private:
DrawsContentChangeLayer() : fake_draws_content_(false) {}
~DrawsContentChangeLayer() override {}
bool fake_draws_content_;
};
TEST_F(LayerTest, DrawsContentChangedInSetLayerTreeHost) {
scoped_refptr<Layer> root_layer = Layer::Create();
scoped_refptr<DrawsContentChangeLayer> becomes_not_draws_content =
DrawsContentChangeLayer::Create();
scoped_refptr<DrawsContentChangeLayer> becomes_draws_content =
DrawsContentChangeLayer::Create();
root_layer->SetIsDrawable(true);
becomes_not_draws_content->SetIsDrawable(true);
becomes_not_draws_content->SetFakeDrawsContent(true);
EXPECT_EQ(0, root_layer->NumDescendantsThatDrawContent());
root_layer->AddChild(becomes_not_draws_content);
EXPECT_EQ(0, root_layer->NumDescendantsThatDrawContent());
becomes_draws_content->SetIsDrawable(true);
root_layer->AddChild(becomes_draws_content);
EXPECT_EQ(1, root_layer->NumDescendantsThatDrawContent());
}
void ReceiveCopyOutputResult(int* result_count,
std::unique_ptr<CopyOutputResult> result) {
++(*result_count);
}
TEST_F(LayerTest, DedupesCopyOutputRequestsBySource) {
scoped_refptr<Layer> layer = Layer::Create();
int result_count = 0;
// Create identical requests without the source being set, and expect the
// layer does not abort either one.
std::unique_ptr<CopyOutputRequest> request = CopyOutputRequest::CreateRequest(
base::Bind(&ReceiveCopyOutputResult, &result_count));
layer->RequestCopyOfOutput(std::move(request));
EXPECT_EQ(0, result_count);
request = CopyOutputRequest::CreateRequest(
base::Bind(&ReceiveCopyOutputResult, &result_count));
layer->RequestCopyOfOutput(std::move(request));
EXPECT_EQ(0, result_count);
// When the layer is destroyed, expect both requests to be aborted.
layer = nullptr;
EXPECT_EQ(2, result_count);
layer = Layer::Create();
result_count = 0;
// Create identical requests, but this time the source is being set. Expect
// the first request from |this| source aborts immediately when the second
// request from |this| source is made.
int did_receive_first_result_from_this_source = 0;
request = CopyOutputRequest::CreateRequest(base::Bind(
&ReceiveCopyOutputResult, &did_receive_first_result_from_this_source));
request->set_source(this);
layer->RequestCopyOfOutput(std::move(request));
EXPECT_EQ(0, did_receive_first_result_from_this_source);
// Make a request from a different source.
int did_receive_result_from_different_source = 0;
request = CopyOutputRequest::CreateRequest(base::Bind(
&ReceiveCopyOutputResult, &did_receive_result_from_different_source));
request->set_source(reinterpret_cast<void*>(0xdeadbee0));
layer->RequestCopyOfOutput(std::move(request));
EXPECT_EQ(0, did_receive_result_from_different_source);
// Make a request without specifying the source.
int did_receive_result_from_anonymous_source = 0;
request = CopyOutputRequest::CreateRequest(base::Bind(
&ReceiveCopyOutputResult, &did_receive_result_from_anonymous_source));
layer->RequestCopyOfOutput(std::move(request));
EXPECT_EQ(0, did_receive_result_from_anonymous_source);
// Make the second request from |this| source.
int did_receive_second_result_from_this_source = 0;
request = CopyOutputRequest::CreateRequest(base::Bind(
&ReceiveCopyOutputResult, &did_receive_second_result_from_this_source));
request->set_source(this);
layer->RequestCopyOfOutput(
std::move(request)); // First request to be aborted.
EXPECT_EQ(1, did_receive_first_result_from_this_source);
EXPECT_EQ(0, did_receive_result_from_different_source);
EXPECT_EQ(0, did_receive_result_from_anonymous_source);
EXPECT_EQ(0, did_receive_second_result_from_this_source);
// When the layer is destroyed, the other three requests should be aborted.
layer = nullptr;
EXPECT_EQ(1, did_receive_first_result_from_this_source);
EXPECT_EQ(1, did_receive_result_from_different_source);
EXPECT_EQ(1, did_receive_result_from_anonymous_source);
EXPECT_EQ(1, did_receive_second_result_from_this_source);
}
TEST_F(LayerTest, AnimationSchedulesLayerUpdate) {
scoped_refptr<Layer> layer = Layer::Create();
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(layer));
LayerInternalsForTest layer_internals(layer.get());
EXPECT_CALL(*layer_tree_host_, SetNeedsUpdateLayers()).Times(1);
layer_internals.OnOpacityAnimated(0.5f);
Mock::VerifyAndClearExpectations(layer_tree_host_.get());
EXPECT_CALL(*layer_tree_host_, SetNeedsUpdateLayers()).Times(1);
gfx::Transform transform;
transform.Rotate(45.0);
layer_internals.OnTransformAnimated(transform);
Mock::VerifyAndClearExpectations(layer_tree_host_.get());
// Scroll offset animation should not schedule a layer update since it is
// handled similarly to normal compositor scroll updates.
EXPECT_CALL(*layer_tree_host_, SetNeedsUpdateLayers()).Times(0);
layer_internals.OnScrollOffsetAnimated(gfx::ScrollOffset(10, 10));
Mock::VerifyAndClearExpectations(layer_tree_host_.get());
}
TEST_F(LayerTest, ElementIdAndMutablePropertiesArePushed) {
scoped_refptr<Layer> test_layer = Layer::Create();
std::unique_ptr<LayerImpl> impl_layer =
LayerImpl::Create(host_impl_.active_tree(), 1);
EXPECT_SET_NEEDS_FULL_TREE_SYNC(1, layer_tree_->SetRootLayer(test_layer));
EXPECT_CALL(*layer_tree_host_, SetNeedsCommit()).Times(2);
test_layer->SetElementId(ElementId(2, 0));
test_layer->SetMutableProperties(MutableProperty::kTransform);
EXPECT_FALSE(impl_layer->element_id());
EXPECT_EQ(MutableProperty::kNone, impl_layer->mutable_properties());
test_layer->PushPropertiesTo(impl_layer.get());
EXPECT_EQ(ElementId(2, 0), impl_layer->element_id());
EXPECT_EQ(MutableProperty::kTransform, impl_layer->mutable_properties());
}
} // namespace
} // namespace cc