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chromium / chromium / src / 4cb34dff88a64907c46583171d101125b2481748 / . / ui / compositor / layer_unittest.cc
blob: cb90ecf41b464a2ea1a0d62dfdcd812d1e7784ad [file] [log] [blame]
// Copyright (c) 2012 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 "ui/compositor/layer.h"
#include <stddef.h>
#include <memory>
#include <utility>
#include <vector>
#include "base/bind.h"
#include "base/compiler_specific.h"
#include "base/files/file_path.h"
#include "base/files/file_util.h"
#include "base/json/json_reader.h"
#include "base/macros.h"
#include "base/path_service.h"
#include "base/run_loop.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/strings/utf_string_conversions.h"
#include "base/test/task_environment.h"
#include "base/time/time.h"
#include "base/trace_event/trace_event.h"
#include "build/build_config.h"
#include "cc/animation/animation_events.h"
#include "cc/animation/animation_host.h"
#include "cc/animation/keyframe_effect.h"
#include "cc/animation/single_keyframe_effect_animation.h"
#include "cc/layers/layer.h"
#include "cc/layers/mirror_layer.h"
#include "cc/test/pixel_comparator.h"
#include "cc/test/pixel_test_utils.h"
#include "components/viz/common/frame_sinks/copy_output_request.h"
#include "components/viz/common/frame_sinks/copy_output_result.h"
#include "components/viz/common/resources/transferable_resource.h"
#include "components/viz/common/surfaces/parent_local_surface_id_allocator.h"
#include "components/viz/common/surfaces/surface_id.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "third_party/khronos/GLES2/gl2.h"
#include "ui/compositor/compositor_observer.h"
#include "ui/compositor/dip_util.h"
#include "ui/compositor/layer_animation_element.h"
#include "ui/compositor/layer_animation_observer.h"
#include "ui/compositor/layer_animation_sequence.h"
#include "ui/compositor/layer_animator.h"
#include "ui/compositor/paint_context.h"
#include "ui/compositor/paint_recorder.h"
#include "ui/compositor/scoped_animation_duration_scale_mode.h"
#include "ui/compositor/scoped_layer_animation_settings.h"
#include "ui/compositor/test/draw_waiter_for_test.h"
#include "ui/compositor/test/layer_animator_test_controller.h"
#include "ui/compositor/test/test_compositor_host.h"
#include "ui/compositor/test/test_context_factories.h"
#include "ui/compositor/test/test_layers.h"
#include "ui/gfx/animation/tween.h"
#include "ui/gfx/canvas.h"
#include "ui/gfx/codec/png_codec.h"
#include "ui/gfx/font_list.h"
#include "ui/gfx/interpolated_transform.h"
#include "ui/gfx/skia_util.h"
using cc::MatchesPNGFile;
using cc::WritePNGFile;
namespace ui {
namespace {
// There are three test classes in here that configure the Compositor and
// Layer's slightly differently:
// - LayerWithNullDelegateTest uses NullLayerDelegate as the LayerDelegate. This
// is typically the base class you want to use.
// - LayerWithDelegateTest uses LayerDelegate on the delegates.
// - LayerWithRealCompositorTest when a real compositor is required for testing.
// - Slow because they bring up a window and run the real compositor. This
// is typically not what you want.
class ColoredLayer : public Layer, public LayerDelegate {
public:
explicit ColoredLayer(SkColor color)
: Layer(LAYER_TEXTURED),
color_(color) {
set_delegate(this);
}
~ColoredLayer() override {}
// Overridden from LayerDelegate:
void OnPaintLayer(const ui::PaintContext& context) override {
ui::PaintRecorder recorder(context, size());
recorder.canvas()->DrawColor(color_);
}
void OnDeviceScaleFactorChanged(float old_device_scale_factor,
float new_device_scale_factor) override {}
private:
SkColor color_;
};
// Param specifies whether to use SkiaRenderer or not
class LayerWithRealCompositorTest : public testing::TestWithParam<bool> {
public:
LayerWithRealCompositorTest()
: task_environment_(base::test::TaskEnvironment::MainThreadType::UI) {
gfx::FontList::SetDefaultFontDescription("Segoe UI, 15px");
}
~LayerWithRealCompositorTest() override {}
// Overridden from testing::Test:
void SetUp() override {
ASSERT_TRUE(base::PathService::Get(base::DIR_SOURCE_ROOT, &test_data_dir_));
test_data_dir_ = test_data_dir_.Append(FILE_PATH_LITERAL("ui"))
.Append(FILE_PATH_LITERAL("gfx"))
.Append(FILE_PATH_LITERAL("test"))
.Append(FILE_PATH_LITERAL("data"))
.Append(FILE_PATH_LITERAL("compositor"));
ASSERT_TRUE(base::PathExists(test_data_dir_));
const bool enable_pixel_output = true;
context_factories_ =
std::make_unique<TestContextFactories>(enable_pixel_output, GetParam());
const gfx::Rect host_bounds(10, 10, 500, 500);
compositor_host_.reset(TestCompositorHost::Create(
host_bounds, context_factories_->GetContextFactory(),
context_factories_->GetContextFactoryPrivate()));
compositor_host_->Show();
}
void TearDown() override {
ResetCompositor();
context_factories_.reset();
}
Compositor* GetCompositor() { return compositor_host_->GetCompositor(); }
void ResetCompositor() {
compositor_host_.reset();
}
std::unique_ptr<Layer> CreateLayer(LayerType type) {
return std::make_unique<Layer>(type);
}
std::unique_ptr<Layer> CreateColorLayer(SkColor color,
const gfx::Rect& bounds) {
auto layer = std::make_unique<ColoredLayer>(color);
layer->SetBounds(bounds);
return layer;
}
std::unique_ptr<Layer> CreateNoTextureLayer(const gfx::Rect& bounds) {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_NOT_DRAWN);
layer->SetBounds(bounds);
return layer;
}
void DrawTree(Layer* root) {
GetCompositor()->SetRootLayer(root);
GetCompositor()->ScheduleDraw();
WaitForSwap();
}
void ReadPixels(SkBitmap* bitmap) {
ReadPixels(bitmap, gfx::Rect(GetCompositor()->size()));
}
void ReadPixels(SkBitmap* bitmap, gfx::Rect source_rect) {
scoped_refptr<ReadbackHolder> holder(new ReadbackHolder);
std::unique_ptr<viz::CopyOutputRequest> request =
std::make_unique<viz::CopyOutputRequest>(
viz::CopyOutputRequest::ResultFormat::RGBA_BITMAP,
base::BindOnce(&ReadbackHolder::OutputRequestCallback, holder));
request->set_area(source_rect);
GetCompositor()->root_layer()->RequestCopyOfOutput(std::move(request));
// Wait for copy response. This needs to wait as the compositor could
// be in the middle of a draw right now, and the commit with the
// copy output request may not be done on the first draw.
for (int i = 0; i < 2; i++) {
GetCompositor()->ScheduleFullRedraw();
WaitForDraw();
}
// Waits for the callback to finish run and return result.
holder->WaitForReadback();
*bitmap = holder->result();
}
void WaitForDraw() {
ui::DrawWaiterForTest::WaitForCompositingStarted(GetCompositor());
}
void WaitForSwap() {
ui::DrawWaiterForTest::WaitForCompositingEnded(GetCompositor());
}
void WaitForCommit() {
ui::DrawWaiterForTest::WaitForCommit(GetCompositor());
}
// Invalidates the entire contents of the layer.
void SchedulePaintForLayer(Layer* layer) {
layer->SchedulePaint(
gfx::Rect(0, 0, layer->bounds().width(), layer->bounds().height()));
}
const base::FilePath& test_data_dir() const { return test_data_dir_; }
private:
class ReadbackHolder : public base::RefCountedThreadSafe<ReadbackHolder> {
public:
ReadbackHolder() : run_loop_(std::make_unique<base::RunLoop>()) {}
void OutputRequestCallback(std::unique_ptr<viz::CopyOutputResult> result) {
if (result->IsEmpty())
result_.reset();
else
result_ = std::make_unique<SkBitmap>(result->AsSkBitmap());
run_loop_->Quit();
}
void WaitForReadback() { run_loop_->Run(); }
const SkBitmap& result() const { return *result_; }
private:
friend class base::RefCountedThreadSafe<ReadbackHolder>;
virtual ~ReadbackHolder() {}
std::unique_ptr<SkBitmap> result_;
std::unique_ptr<base::RunLoop> run_loop_;
};
base::test::TaskEnvironment task_environment_;
std::unique_ptr<TestContextFactories> context_factories_;
std::unique_ptr<TestCompositorHost> compositor_host_;
// The root directory for test files.
base::FilePath test_data_dir_;
DISALLOW_COPY_AND_ASSIGN(LayerWithRealCompositorTest);
};
// LayerDelegate that paints colors to the layer.
class TestLayerDelegate : public LayerDelegate {
public:
TestLayerDelegate() { reset(); }
~TestLayerDelegate() override {}
void AddColor(SkColor color) {
colors_.push_back(color);
}
int color_index() const { return color_index_; }
float device_scale_factor() const {
return device_scale_factor_;
}
void set_layer_bounds(const gfx::Rect& layer_bounds) {
layer_bounds_ = layer_bounds;
}
// Overridden from LayerDelegate:
void OnPaintLayer(const ui::PaintContext& context) override {
ui::PaintRecorder recorder(context, layer_bounds_.size());
recorder.canvas()->DrawColor(colors_[color_index_]);
color_index_ = (color_index_ + 1) % static_cast<int>(colors_.size());
}
void OnDeviceScaleFactorChanged(float old_device_scale_factor,
float new_device_scale_factor) override {
device_scale_factor_ = new_device_scale_factor;
}
MOCK_METHOD2(OnLayerBoundsChanged,
void(const gfx::Rect&, PropertyChangeReason));
MOCK_METHOD2(OnLayerTransformed,
void(const gfx::Transform&, PropertyChangeReason));
MOCK_METHOD1(OnLayerOpacityChanged, void(PropertyChangeReason));
MOCK_METHOD0(OnLayerAlphaShapeChanged, void());
void reset() {
color_index_ = 0;
device_scale_factor_ = 0.0f;
}
private:
std::vector<SkColor> colors_;
int color_index_;
float device_scale_factor_;
gfx::Rect layer_bounds_;
DISALLOW_COPY_AND_ASSIGN(TestLayerDelegate);
};
// LayerDelegate that verifies that a layer was asked to update its canvas.
class DrawTreeLayerDelegate : public LayerDelegate {
public:
DrawTreeLayerDelegate(const gfx::Rect& layer_bounds)
: painted_(false), layer_bounds_(layer_bounds) {}
~DrawTreeLayerDelegate() override {}
void Reset() {
painted_ = false;
}
bool painted() const { return painted_; }
private:
// Overridden from LayerDelegate:
void OnPaintLayer(const ui::PaintContext& context) override {
painted_ = true;
ui::PaintRecorder recorder(context, layer_bounds_.size());
recorder.canvas()->DrawColor(SK_ColorWHITE);
}
void OnDeviceScaleFactorChanged(float old_device_scale_factor,
float new_device_scale_factor) override {}
bool painted_;
const gfx::Rect layer_bounds_;
DISALLOW_COPY_AND_ASSIGN(DrawTreeLayerDelegate);
};
// The simplest possible layer delegate. Does nothing.
class NullLayerDelegate : public LayerDelegate {
public:
NullLayerDelegate() {}
~NullLayerDelegate() override {}
gfx::Rect invalidation() const { return invalidation_; }
private:
gfx::Rect invalidation_;
// Overridden from LayerDelegate:
void OnPaintLayer(const ui::PaintContext& context) override {
invalidation_ = context.InvalidationForTesting();
}
void OnDeviceScaleFactorChanged(float old_device_scale_factor,
float new_device_scale_factor) override {}
DISALLOW_COPY_AND_ASSIGN(NullLayerDelegate);
};
// Remembers if it has been notified.
class TestCompositorObserver : public CompositorObserver {
public:
TestCompositorObserver() = default;
bool committed() const { return committed_; }
bool notified() const { return started_ && ended_; }
void Reset() {
committed_ = false;
started_ = false;
ended_ = false;
}
private:
void OnCompositingDidCommit(Compositor* compositor) override {
committed_ = true;
}
void OnCompositingStarted(Compositor* compositor,
base::TimeTicks start_time) override {
started_ = true;
}
void OnCompositingEnded(Compositor* compositor) override { ended_ = true; }
bool committed_ = false;
bool started_ = false;
bool ended_ = false;
DISALLOW_COPY_AND_ASSIGN(TestCompositorObserver);
};
class TestCompositorAnimationObserver : public CompositorAnimationObserver {
public:
explicit TestCompositorAnimationObserver(ui::Compositor* compositor)
: compositor_(compositor),
animation_step_count_(0),
shutdown_(false) {
DCHECK(compositor_);
compositor_->AddAnimationObserver(this);
}
~TestCompositorAnimationObserver() override {
if (compositor_)
compositor_->RemoveAnimationObserver(this);
}
size_t animation_step_count() const { return animation_step_count_; }
bool shutdown() const { return shutdown_; }
private:
void OnAnimationStep(base::TimeTicks timestamp) override {
++animation_step_count_;
}
void OnCompositingShuttingDown(Compositor* compositor) override {
DCHECK_EQ(compositor_, compositor);
compositor_->RemoveAnimationObserver(this);
compositor_ = nullptr;
shutdown_ = true;
}
ui::Compositor* compositor_;
size_t animation_step_count_;
bool shutdown_;
DISALLOW_COPY_AND_ASSIGN(TestCompositorAnimationObserver);
};
} // namespace
INSTANTIATE_TEST_SUITE_P(All, LayerWithRealCompositorTest, ::testing::Bool());
TEST_P(LayerWithRealCompositorTest, Draw) {
std::unique_ptr<Layer> layer =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 50, 50));
DrawTree(layer.get());
}
// Create this hierarchy:
// L1 - red
// +-- L2 - blue
// | +-- L3 - yellow
// +-- L4 - magenta
//
TEST_P(LayerWithRealCompositorTest, Hierarchy) {
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> l2 =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(10, 10, 350, 350));
std::unique_ptr<Layer> l3 =
CreateColorLayer(SK_ColorYELLOW, gfx::Rect(5, 5, 25, 25));
std::unique_ptr<Layer> l4 =
CreateColorLayer(SK_ColorMAGENTA, gfx::Rect(300, 300, 100, 100));
l1->Add(l2.get());
l1->Add(l4.get());
l2->Add(l3.get());
DrawTree(l1.get());
}
class LayerWithDelegateTest : public testing::Test {
public:
LayerWithDelegateTest()
: task_environment_(base::test::TaskEnvironment::MainThreadType::UI) {}
~LayerWithDelegateTest() override {}
// Overridden from testing::Test:
void SetUp() override {
const bool enable_pixel_output = false;
context_factories_ =
std::make_unique<TestContextFactories>(enable_pixel_output);
const gfx::Rect host_bounds(1000, 1000);
compositor_host_.reset(TestCompositorHost::Create(
host_bounds, context_factories_->GetContextFactory(),
context_factories_->GetContextFactoryPrivate()));
compositor_host_->Show();
}
void TearDown() override {
compositor_host_.reset();
context_factories_.reset();
}
Compositor* compositor() { return compositor_host_->GetCompositor(); }
virtual std::unique_ptr<Layer> CreateLayer(LayerType type) {
return std::make_unique<Layer>(type);
}
std::unique_ptr<Layer> CreateColorLayer(SkColor color,
const gfx::Rect& bounds) {
auto layer = std::make_unique<ColoredLayer>(color);
layer->SetBounds(bounds);
return layer;
}
virtual std::unique_ptr<Layer> CreateNoTextureLayer(const gfx::Rect& bounds) {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_NOT_DRAWN);
layer->SetBounds(bounds);
return layer;
}
void DrawTree(Layer* root) {
compositor()->SetRootLayer(root);
Draw();
}
// Invalidates the entire contents of the layer.
void SchedulePaintForLayer(Layer* layer) {
layer->SchedulePaint(
gfx::Rect(0, 0, layer->bounds().width(), layer->bounds().height()));
}
// Invokes DrawTree on the compositor.
void Draw() {
compositor()->ScheduleDraw();
WaitForDraw();
}
void WaitForDraw() {
DrawWaiterForTest::WaitForCompositingStarted(compositor());
}
void WaitForCommit() {
DrawWaiterForTest::WaitForCommit(compositor());
}
private:
base::test::TaskEnvironment task_environment_;
std::unique_ptr<TestContextFactories> context_factories_;
std::unique_ptr<TestCompositorHost> compositor_host_;
DISALLOW_COPY_AND_ASSIGN(LayerWithDelegateTest);
};
void ReturnMailbox(bool* run, const gpu::SyncToken& sync_token, bool is_lost) {
*run = true;
}
TEST(LayerStandaloneTest, ReleaseMailboxOnDestruction) {
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
bool callback_run = false;
constexpr gfx::Size size(64, 64);
auto resource = viz::TransferableResource::MakeGL(
gpu::Mailbox::Generate(), GL_LINEAR, GL_TEXTURE_2D, gpu::SyncToken(),
size, false /* is_overlay_candidate */);
layer->SetTransferableResource(
resource,
viz::SingleReleaseCallback::Create(
base::BindOnce(ReturnMailbox, &callback_run)),
gfx::Size(10, 10));
EXPECT_FALSE(callback_run);
layer.reset();
EXPECT_TRUE(callback_run);
}
// L1
// +-- L2
TEST_F(LayerWithDelegateTest, ConvertPointToLayer_Simple) {
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> l2 =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(10, 10, 350, 350));
l1->Add(l2.get());
DrawTree(l1.get());
gfx::PointF point1_in_l2_coords(5, 5);
Layer::ConvertPointToLayer(l2.get(), l1.get(), &point1_in_l2_coords);
gfx::PointF point1_in_l1_coords(15, 15);
EXPECT_EQ(point1_in_l1_coords, point1_in_l2_coords);
gfx::PointF point2_in_l1_coords(5, 5);
Layer::ConvertPointToLayer(l1.get(), l2.get(), &point2_in_l1_coords);
gfx::PointF point2_in_l2_coords(-5, -5);
EXPECT_EQ(point2_in_l2_coords, point2_in_l1_coords);
}
// L1
// +-- L2
// +-- L3
TEST_F(LayerWithDelegateTest, ConvertPointToLayer_Medium) {
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> l2 =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(10, 10, 350, 350));
std::unique_ptr<Layer> l3 =
CreateColorLayer(SK_ColorYELLOW, gfx::Rect(10, 10, 100, 100));
l1->Add(l2.get());
l2->Add(l3.get());
DrawTree(l1.get());
gfx::PointF point1_in_l3_coords(5, 5);
Layer::ConvertPointToLayer(l3.get(), l1.get(), &point1_in_l3_coords);
gfx::PointF point1_in_l1_coords(25, 25);
EXPECT_EQ(point1_in_l1_coords, point1_in_l3_coords);
gfx::PointF point2_in_l1_coords(5, 5);
Layer::ConvertPointToLayer(l1.get(), l3.get(), &point2_in_l1_coords);
gfx::PointF point2_in_l3_coords(-15, -15);
EXPECT_EQ(point2_in_l3_coords, point2_in_l1_coords);
}
TEST_P(LayerWithRealCompositorTest, Delegate) {
// This test makes sure that whenever paint happens at a layer, its layer
// delegate gets the paint, which in this test update its color and
// |color_index|.
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorBLACK, gfx::Rect(20, 20, 400, 400));
GetCompositor()->SetRootLayer(l1.get());
WaitForDraw();
TestLayerDelegate delegate;
l1->set_delegate(&delegate);
delegate.set_layer_bounds(l1->bounds());
delegate.AddColor(SK_ColorWHITE);
delegate.AddColor(SK_ColorYELLOW);
delegate.AddColor(SK_ColorGREEN);
l1->SchedulePaint(gfx::Rect(0, 0, 400, 400));
WaitForDraw();
// Test that paint happened at layer delegate.
EXPECT_EQ(1, delegate.color_index());
l1->SchedulePaint(gfx::Rect(10, 10, 200, 200));
WaitForDraw();
// Test that paint happened at layer delegate.
EXPECT_EQ(2, delegate.color_index());
l1->SchedulePaint(gfx::Rect(5, 5, 50, 50));
WaitForDraw();
// Test that paint happened at layer delegate.
EXPECT_EQ(0, delegate.color_index());
}
TEST_P(LayerWithRealCompositorTest, DrawTree) {
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> l2 =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(10, 10, 350, 350));
std::unique_ptr<Layer> l3 =
CreateColorLayer(SK_ColorYELLOW, gfx::Rect(10, 10, 100, 100));
l1->Add(l2.get());
l2->Add(l3.get());
GetCompositor()->SetRootLayer(l1.get());
WaitForDraw();
DrawTreeLayerDelegate d1(l1->bounds());
l1->set_delegate(&d1);
DrawTreeLayerDelegate d2(l2->bounds());
l2->set_delegate(&d2);
DrawTreeLayerDelegate d3(l3->bounds());
l3->set_delegate(&d3);
l2->SchedulePaint(gfx::Rect(5, 5, 5, 5));
WaitForDraw();
EXPECT_FALSE(d1.painted());
EXPECT_TRUE(d2.painted());
EXPECT_FALSE(d3.painted());
}
// Tests that scheduling paint on a layer with a mask updates the mask.
TEST_P(LayerWithRealCompositorTest, SchedulePaintUpdatesMask) {
std::unique_ptr<Layer> layer =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> mask_layer = CreateLayer(ui::LAYER_TEXTURED);
mask_layer->SetBounds(gfx::Rect(layer->GetTargetBounds().size()));
layer->SetMaskLayer(mask_layer.get());
GetCompositor()->SetRootLayer(layer.get());
WaitForDraw();
DrawTreeLayerDelegate d1(layer->bounds());
layer->set_delegate(&d1);
DrawTreeLayerDelegate d2(mask_layer->bounds());
mask_layer->set_delegate(&d2);
layer->SchedulePaint(gfx::Rect(5, 5, 5, 5));
WaitForDraw();
EXPECT_TRUE(d1.painted());
EXPECT_TRUE(d2.painted());
}
// Tests no-texture Layers.
// Create this hierarchy:
// L1 - red
// +-- L2 - NO TEXTURE
// | +-- L3 - yellow
// +-- L4 - magenta
//
TEST_P(LayerWithRealCompositorTest, HierarchyNoTexture) {
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> l2 = CreateNoTextureLayer(gfx::Rect(10, 10, 350, 350));
std::unique_ptr<Layer> l3 =
CreateColorLayer(SK_ColorYELLOW, gfx::Rect(5, 5, 25, 25));
std::unique_ptr<Layer> l4 =
CreateColorLayer(SK_ColorMAGENTA, gfx::Rect(300, 300, 100, 100));
l1->Add(l2.get());
l1->Add(l4.get());
l2->Add(l3.get());
GetCompositor()->SetRootLayer(l1.get());
WaitForDraw();
DrawTreeLayerDelegate d2(l2->bounds());
l2->set_delegate(&d2);
DrawTreeLayerDelegate d3(l3->bounds());
l3->set_delegate(&d3);
l2->SchedulePaint(gfx::Rect(5, 5, 5, 5));
l3->SchedulePaint(gfx::Rect(5, 5, 5, 5));
WaitForDraw();
// |d2| should not have received a paint notification since it has no texture.
EXPECT_FALSE(d2.painted());
// |d3| should have received a paint notification.
EXPECT_TRUE(d3.painted());
}
TEST_F(LayerWithDelegateTest, Cloning) {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_SOLID_COLOR);
gfx::Transform transform;
transform.Scale(2, 1);
transform.Translate(10, 5);
layer->SetTransform(transform);
layer->SetColor(SK_ColorRED);
layer->SetLayerInverted(true);
layer->AddCacheRenderSurfaceRequest();
layer->AddTrilinearFilteringRequest();
layer->SetRoundedCornerRadius({1, 2, 4, 5});
layer->SetIsFastRoundedCorner(true);
auto clone = layer->Clone();
// Cloning preserves layer state.
EXPECT_EQ(transform, clone->GetTargetTransform());
EXPECT_EQ(SK_ColorRED, clone->background_color());
EXPECT_EQ(SK_ColorRED, clone->GetTargetColor());
EXPECT_TRUE(clone->layer_inverted());
// Cloning should not preserve cache_render_surface flag.
EXPECT_NE(layer->cc_layer_for_testing()->cache_render_surface(),
clone->cc_layer_for_testing()->cache_render_surface());
// Cloning should not preserve trilinear_filtering flag.
EXPECT_NE(layer->cc_layer_for_testing()->trilinear_filtering(),
clone->cc_layer_for_testing()->trilinear_filtering());
EXPECT_EQ(layer->rounded_corner_radii(), clone->rounded_corner_radii());
EXPECT_EQ(layer->is_fast_rounded_corner(), clone->is_fast_rounded_corner());
layer->SetTransform(gfx::Transform());
layer->SetColor(SK_ColorGREEN);
layer->SetLayerInverted(false);
layer->SetIsFastRoundedCorner(false);
layer->SetRoundedCornerRadius({3, 6, 9, 12});
// The clone is an independent copy, so state changes do not propagate.
EXPECT_EQ(transform, clone->GetTargetTransform());
EXPECT_EQ(SK_ColorRED, clone->background_color());
EXPECT_EQ(SK_ColorRED, clone->GetTargetColor());
EXPECT_TRUE(clone->layer_inverted());
EXPECT_FALSE(layer->is_fast_rounded_corner());
EXPECT_TRUE(clone->is_fast_rounded_corner());
EXPECT_NE(layer->rounded_corner_radii(), clone->rounded_corner_radii());
constexpr SkColor kTransparent = SK_ColorTRANSPARENT;
layer->SetColor(kTransparent);
layer->SetFillsBoundsOpaquely(false);
// Color and opaqueness targets should be preserved during cloning, even after
// switching away from solid color content.
layer->SwitchCCLayerForTest();
clone = layer->Clone();
// The clone is a copy of the latest state.
EXPECT_TRUE(clone->GetTargetTransform().IsIdentity());
EXPECT_EQ(kTransparent, clone->background_color());
EXPECT_EQ(kTransparent, clone->GetTargetColor());
EXPECT_FALSE(clone->layer_inverted());
EXPECT_FALSE(clone->fills_bounds_opaquely());
// A solid color layer with transparent color can be marked as opaque. The
// clone should retain this state.
layer = CreateLayer(LAYER_SOLID_COLOR);
layer->SetColor(kTransparent);
layer->SetFillsBoundsOpaquely(true);
clone = layer->Clone();
EXPECT_TRUE(clone->GetTargetTransform().IsIdentity());
EXPECT_EQ(kTransparent, clone->background_color());
EXPECT_EQ(kTransparent, clone->GetTargetColor());
EXPECT_FALSE(clone->layer_inverted());
EXPECT_TRUE(clone->fills_bounds_opaquely());
layer = CreateLayer(LAYER_SOLID_COLOR);
layer->SetVisible(true);
layer->SetOpacity(1.0f);
layer->SetColor(SK_ColorRED);
ScopedLayerAnimationSettings settings(layer->GetAnimator());
layer->SetVisible(false);
layer->SetOpacity(0.0f);
layer->SetColor(SK_ColorGREEN);
EXPECT_TRUE(layer->visible());
EXPECT_EQ(1.0f, layer->opacity());
EXPECT_EQ(SK_ColorRED, layer->background_color());
clone = layer->Clone();
// Cloning copies animation targets.
EXPECT_FALSE(clone->visible());
EXPECT_EQ(0.0f, clone->opacity());
EXPECT_EQ(SK_ColorGREEN, clone->background_color());
}
TEST_F(LayerWithDelegateTest, Mirroring) {
std::unique_ptr<Layer> root = CreateNoTextureLayer(gfx::Rect(0, 0, 100, 100));
std::unique_ptr<Layer> child = CreateLayer(LAYER_TEXTURED);
const gfx::Rect bounds(0, 0, 50, 50);
child->SetBounds(bounds);
child->SetVisible(true);
DrawTreeLayerDelegate delegate(child->bounds());
child->set_delegate(&delegate);
const auto mirror1 = child->Mirror();
// Bounds and visibility are preserved.
EXPECT_EQ(bounds, mirror1->bounds());
EXPECT_TRUE(mirror1->visible());
root->Add(child.get());
root->Add(mirror1.get());
DrawTree(root.get());
EXPECT_TRUE(delegate.painted());
delegate.Reset();
// Both layers should be clean.
EXPECT_TRUE(child->damaged_region_for_testing().IsEmpty());
EXPECT_TRUE(mirror1->damaged_region_for_testing().IsEmpty());
const gfx::Rect damaged_rect(10, 10, 20, 20);
EXPECT_TRUE(child->SchedulePaint(damaged_rect));
EXPECT_EQ(damaged_rect, child->damaged_region_for_testing().bounds());
DrawTree(root.get());
EXPECT_TRUE(delegate.painted());
delegate.Reset();
// Damage should be propagated to the mirror.
EXPECT_EQ(damaged_rect, mirror1->damaged_region_for_testing().bounds());
EXPECT_TRUE(child->damaged_region_for_testing().IsEmpty());
DrawTree(root.get());
EXPECT_TRUE(delegate.painted());
// Mirror should be clean.
EXPECT_TRUE(mirror1->damaged_region_for_testing().IsEmpty());
const auto mirror2 = child->Mirror();
root->Add(mirror2.get());
// Bounds are not synchronized by default.
const gfx::Rect new_bounds(10, 10, 10, 10);
child->SetBounds(new_bounds);
EXPECT_EQ(bounds, mirror1->bounds());
EXPECT_EQ(bounds, mirror2->bounds());
child->SetBounds(bounds);
// Bounds should be synchronized only for the mirror layer that requested it.
mirror1->set_sync_bounds_with_source(true);
child->SetBounds(new_bounds);
EXPECT_EQ(new_bounds, mirror1->bounds());
EXPECT_EQ(bounds, mirror2->bounds());
// Check for rounded corner mirror behavior
EXPECT_TRUE(mirror1->rounded_corner_radii().IsEmpty());
EXPECT_FALSE(mirror1->is_fast_rounded_corner());
constexpr gfx::RoundedCornersF kCornerRadii(2, 3, 4, 5);
child->SetRoundedCornerRadius(kCornerRadii);
child->SetIsFastRoundedCorner(true);
EXPECT_EQ(kCornerRadii, mirror1->rounded_corner_radii());
EXPECT_TRUE(mirror1->is_fast_rounded_corner());
}
// Tests for SurfaceLayer cloning and mirroring. This tests certain properties
// are preserved.
TEST_F(LayerWithDelegateTest, SurfaceLayerCloneAndMirror) {
const viz::FrameSinkId arbitrary_frame_sink(1, 1);
viz::ParentLocalSurfaceIdAllocator allocator;
std::unique_ptr<Layer> layer = CreateLayer(LAYER_SOLID_COLOR);
allocator.GenerateId();
viz::LocalSurfaceId local_surface_id =
allocator.GetCurrentLocalSurfaceIdAllocation().local_surface_id();
viz::SurfaceId surface_id_one(arbitrary_frame_sink, local_surface_id);
layer->SetShowSurface(surface_id_one, gfx::Size(10, 10), SK_ColorWHITE,
cc::DeadlinePolicy::UseDefaultDeadline(), false);
EXPECT_FALSE(layer->StretchContentToFillBounds());
auto clone = layer->Clone();
EXPECT_FALSE(clone->StretchContentToFillBounds());
auto mirror = layer->Mirror();
EXPECT_FALSE(mirror->StretchContentToFillBounds());
allocator.GenerateId();
local_surface_id =
allocator.GetCurrentLocalSurfaceIdAllocation().local_surface_id();
viz::SurfaceId surface_id_two(arbitrary_frame_sink, local_surface_id);
layer->SetShowSurface(surface_id_two, gfx::Size(10, 10), SK_ColorWHITE,
cc::DeadlinePolicy::UseDefaultDeadline(), true);
EXPECT_TRUE(layer->StretchContentToFillBounds());
clone = layer->Clone();
EXPECT_TRUE(clone->StretchContentToFillBounds());
mirror = layer->Mirror();
EXPECT_TRUE(mirror->StretchContentToFillBounds());
}
class LayerWithNullDelegateTest : public LayerWithDelegateTest {
public:
LayerWithNullDelegateTest() {}
~LayerWithNullDelegateTest() override {}
void SetUp() override {
LayerWithDelegateTest::SetUp();
default_layer_delegate_ = std::make_unique<NullLayerDelegate>();
}
std::unique_ptr<Layer> CreateLayer(LayerType type) override {
auto layer = std::make_unique<Layer>(type);
layer->set_delegate(default_layer_delegate_.get());
return layer;
}
std::unique_ptr<Layer> CreateTextureRootLayer(const gfx::Rect& bounds) {
std::unique_ptr<Layer> layer = CreateTextureLayer(bounds);
compositor()->SetRootLayer(layer.get());
return layer;
}
std::unique_ptr<Layer> CreateTextureLayer(const gfx::Rect& bounds) {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_TEXTURED);
layer->SetBounds(bounds);
return layer;
}
std::unique_ptr<Layer> CreateNoTextureLayer(
const gfx::Rect& bounds) override {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_NOT_DRAWN);
layer->SetBounds(bounds);
return layer;
}
gfx::Rect LastInvalidation() const {
return default_layer_delegate_->invalidation();
}
private:
std::unique_ptr<NullLayerDelegate> default_layer_delegate_;
DISALLOW_COPY_AND_ASSIGN(LayerWithNullDelegateTest);
};
TEST_F(LayerWithNullDelegateTest, SwitchLayerPreservesCCLayerState) {
std::unique_ptr<Layer> l1 = CreateLayer(LAYER_SOLID_COLOR);
l1->SetFillsBoundsOpaquely(true);
l1->SetVisible(false);
l1->SetBounds(gfx::Rect(4, 5));
constexpr gfx::RoundedCornersF kCornerRadii(1, 2, 3, 4);
l1->SetRoundedCornerRadius(kCornerRadii);
l1->SetIsFastRoundedCorner(true);
EXPECT_EQ(gfx::Point3F(), l1->cc_layer_for_testing()->transform_origin());
EXPECT_TRUE(l1->cc_layer_for_testing()->DrawsContent());
EXPECT_TRUE(l1->cc_layer_for_testing()->contents_opaque());
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_EQ(gfx::Size(4, 5), l1->cc_layer_for_testing()->bounds());
EXPECT_TRUE(l1->cc_layer_for_testing()->HasRoundedCorner());
EXPECT_EQ(l1->cc_layer_for_testing()->corner_radii(), kCornerRadii);
EXPECT_TRUE(l1->cc_layer_for_testing()->is_fast_rounded_corner());
cc::Layer* before_layer = l1->cc_layer_for_testing();
bool callback1_run = false;
constexpr gfx::Size size(64, 64);
auto resource = viz::TransferableResource::MakeGL(
gpu::Mailbox::Generate(), GL_LINEAR, GL_TEXTURE_2D, gpu::SyncToken(),
size, false /* is_overlay_candidate */);
l1->SetTransferableResource(resource,
viz::SingleReleaseCallback::Create(base::BindOnce(
ReturnMailbox, &callback1_run)),
gfx::Size(10, 10));
EXPECT_NE(before_layer, l1->cc_layer_for_testing());
EXPECT_EQ(gfx::Point3F(), l1->cc_layer_for_testing()->transform_origin());
EXPECT_TRUE(l1->cc_layer_for_testing()->DrawsContent());
EXPECT_TRUE(l1->cc_layer_for_testing()->contents_opaque());
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_EQ(gfx::Size(4, 5), l1->cc_layer_for_testing()->bounds());
EXPECT_TRUE(l1->cc_layer_for_testing()->HasRoundedCorner());
EXPECT_EQ(l1->cc_layer_for_testing()->corner_radii(), kCornerRadii);
EXPECT_TRUE(l1->cc_layer_for_testing()->is_fast_rounded_corner());
EXPECT_FALSE(callback1_run);
bool callback2_run = false;
resource = viz::TransferableResource::MakeGL(
gpu::Mailbox::Generate(), GL_LINEAR, GL_TEXTURE_2D, gpu::SyncToken(),
size, false /* is_overlay_candidate */);
l1->SetTransferableResource(resource,
viz::SingleReleaseCallback::Create(base::BindOnce(
ReturnMailbox, &callback2_run)),
gfx::Size(10, 10));
EXPECT_TRUE(callback1_run);
EXPECT_FALSE(callback2_run);
// Show solid color instead.
l1->SetShowSolidColorContent();
EXPECT_EQ(gfx::Point3F(), l1->cc_layer_for_testing()->transform_origin());
EXPECT_TRUE(l1->cc_layer_for_testing()->DrawsContent());
EXPECT_TRUE(l1->cc_layer_for_testing()->contents_opaque());
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_EQ(gfx::Size(4, 5), l1->cc_layer_for_testing()->bounds());
EXPECT_TRUE(l1->cc_layer_for_testing()->HasRoundedCorner());
EXPECT_EQ(l1->cc_layer_for_testing()->corner_radii(), kCornerRadii);
EXPECT_TRUE(l1->cc_layer_for_testing()->is_fast_rounded_corner());
EXPECT_TRUE(callback2_run);
before_layer = l1->cc_layer_for_testing();
// Back to a texture, without changing the bounds of the layer or the texture.
bool callback3_run = false;
resource = viz::TransferableResource::MakeGL(
gpu::Mailbox::Generate(), GL_LINEAR, GL_TEXTURE_2D, gpu::SyncToken(),
size, false /* is_overlay_candidate */);
l1->SetTransferableResource(resource,
viz::SingleReleaseCallback::Create(base::BindOnce(
ReturnMailbox, &callback3_run)),
gfx::Size(10, 10));
EXPECT_NE(before_layer, l1->cc_layer_for_testing());
EXPECT_EQ(gfx::Point3F(), l1->cc_layer_for_testing()->transform_origin());
EXPECT_TRUE(l1->cc_layer_for_testing()->DrawsContent());
EXPECT_TRUE(l1->cc_layer_for_testing()->contents_opaque());
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_EQ(gfx::Size(4, 5), l1->cc_layer_for_testing()->bounds());
EXPECT_TRUE(l1->cc_layer_for_testing()->HasRoundedCorner());
EXPECT_EQ(l1->cc_layer_for_testing()->corner_radii(), kCornerRadii);
EXPECT_TRUE(l1->cc_layer_for_testing()->is_fast_rounded_corner());
EXPECT_FALSE(callback3_run);
// Release the on |l1| mailbox to clean up the test.
l1->SetShowSolidColorContent();
}
// Various visible/drawn assertions.
TEST_F(LayerWithNullDelegateTest, Visibility) {
auto l1 = std::make_unique<Layer>(LAYER_TEXTURED);
auto l2 = std::make_unique<Layer>(LAYER_TEXTURED);
auto l3 = std::make_unique<Layer>(LAYER_TEXTURED);
l1->Add(l2.get());
l2->Add(l3.get());
NullLayerDelegate delegate;
l1->set_delegate(&delegate);
l2->set_delegate(&delegate);
l3->set_delegate(&delegate);
// Layers should initially be drawn.
EXPECT_TRUE(l1->IsDrawn());
EXPECT_TRUE(l2->IsDrawn());
EXPECT_TRUE(l3->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l3->cc_layer_for_testing()->hide_layer_and_subtree());
compositor()->SetRootLayer(l1.get());
Draw();
l1->SetVisible(false);
EXPECT_FALSE(l1->IsDrawn());
EXPECT_FALSE(l2->IsDrawn());
EXPECT_FALSE(l3->IsDrawn());
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l3->cc_layer_for_testing()->hide_layer_and_subtree());
l3->SetVisible(false);
EXPECT_FALSE(l1->IsDrawn());
EXPECT_FALSE(l2->IsDrawn());
EXPECT_FALSE(l3->IsDrawn());
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l3->cc_layer_for_testing()->hide_layer_and_subtree());
l1->SetVisible(true);
EXPECT_TRUE(l1->IsDrawn());
EXPECT_TRUE(l2->IsDrawn());
EXPECT_FALSE(l3->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l3->cc_layer_for_testing()->hide_layer_and_subtree());
}
// Various visible/drawn assertions.
TEST_F(LayerWithNullDelegateTest, MirroringVisibility) {
auto l1 = std::make_unique<Layer>(LAYER_TEXTURED);
auto l2 = std::make_unique<Layer>(LAYER_TEXTURED);
std::unique_ptr<Layer> l2_mirror = l2->Mirror();
l1->Add(l2.get());
l1->Add(l2_mirror.get());
NullLayerDelegate delegate;
l1->set_delegate(&delegate);
l2->set_delegate(&delegate);
l2_mirror->set_delegate(&delegate);
// Layers should initially be drawn.
EXPECT_TRUE(l1->IsDrawn());
EXPECT_TRUE(l2->IsDrawn());
EXPECT_TRUE(l2_mirror->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
compositor()->SetRootLayer(l1.get());
Draw();
// Hiding the root layer should hide that specific layer and its subtree.
l1->SetVisible(false);
// Since the entire subtree is hidden, no layer should be drawn.
EXPECT_FALSE(l1->IsDrawn());
EXPECT_FALSE(l2->IsDrawn());
EXPECT_FALSE(l2_mirror->IsDrawn());
// The visibitily property for the subtree is rooted at |l1|.
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
// Hiding |l2| should also set the visibility on its mirror layer. In this
// case the visibility of |l2| will be mirrored by |l2_mirror|.
l2->SetVisible(false);
// None of the layers are drawn since the visibility is false at every node.
EXPECT_FALSE(l1->IsDrawn());
EXPECT_FALSE(l2->IsDrawn());
EXPECT_FALSE(l2_mirror->IsDrawn());
// Visibility property is set on every node and hence their subtree is also
// hidden.
EXPECT_TRUE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
// Setting visibility on the root layer should make that layer visible and its
// subtree ready for visibility.
l1->SetVisible(true);
EXPECT_TRUE(l1->IsDrawn());
EXPECT_FALSE(l2->IsDrawn());
EXPECT_FALSE(l2_mirror->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
// Setting visibility on the mirrored layer should not effect its source
// layer.
l2_mirror->SetVisible(true);
EXPECT_TRUE(l1->IsDrawn());
EXPECT_FALSE(l2->IsDrawn());
EXPECT_TRUE(l2_mirror->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
// Setting visibility on the source layer should keep the mirror layer in
// sync and not cause any invalid state.
l2->SetVisible(true);
EXPECT_TRUE(l1->IsDrawn());
EXPECT_TRUE(l2->IsDrawn());
EXPECT_TRUE(l2_mirror->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
// Setting visibility on the mirrored layer should not effect its source
// layer.
l2_mirror->SetVisible(false);
EXPECT_TRUE(l1->IsDrawn());
EXPECT_TRUE(l2->IsDrawn());
EXPECT_FALSE(l2_mirror->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
// Setting source layer's visibility to true should update the mirror layer
// even if the source layer did not change in the process.
l2->SetVisible(true);
EXPECT_TRUE(l1->IsDrawn());
EXPECT_TRUE(l2->IsDrawn());
EXPECT_TRUE(l2_mirror->IsDrawn());
EXPECT_FALSE(l1->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_FALSE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
// Disable visibility sync on the mirrored layer. Changes in |l2|'s visibility
// shouldn't affect the visibility of |l2_mirror|.
l2_mirror->set_sync_visibility_with_source(false);
l2->SetVisible(false);
EXPECT_FALSE(l2->IsDrawn());
EXPECT_TRUE(l2->cc_layer_for_testing()->hide_layer_and_subtree());
EXPECT_TRUE(l2_mirror->IsDrawn());
EXPECT_FALSE(l2_mirror->cc_layer_for_testing()->hide_layer_and_subtree());
}
TEST_F(LayerWithDelegateTest, RoundedCorner) {
gfx::Rect layer_bounds(10, 20, 100, 100);
constexpr gfx::RoundedCornersF kRadii(5, 10, 15, 20);
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
NullLayerDelegate delegate;
layer->set_delegate(&delegate);
layer->SetVisible(true);
layer->SetBounds(layer_bounds);
layer->SetMasksToBounds(true);
compositor()->SetRootLayer(layer.get());
Draw();
EXPECT_TRUE(layer->rounded_corner_radii().IsEmpty());
// Setting a rounded corner radius should set an rrect with bounds same as the
// layer.
layer->SetRoundedCornerRadius(kRadii);
EXPECT_EQ(kRadii, layer->rounded_corner_radii());
}
// Checks that stacking-related methods behave as advertised.
TEST_F(LayerWithNullDelegateTest, Stacking) {
auto root = std::make_unique<Layer>(LAYER_NOT_DRAWN);
auto l1 = std::make_unique<Layer>(LAYER_TEXTURED);
auto l2 = std::make_unique<Layer>(LAYER_TEXTURED);
auto l3 = std::make_unique<Layer>(LAYER_TEXTURED);
l1->set_name("1");
l2->set_name("2");
l3->set_name("3");
root->Add(l3.get());
root->Add(l2.get());
root->Add(l1.get());
// Layers' children are stored in bottom-to-top order.
EXPECT_EQ("3 2 1", test::ChildLayerNamesAsString(*root.get()));
root->StackAtTop(l3.get());
EXPECT_EQ("2 1 3", test::ChildLayerNamesAsString(*root.get()));
root->StackAtTop(l1.get());
EXPECT_EQ("2 3 1", test::ChildLayerNamesAsString(*root.get()));
root->StackAtTop(l1.get());
EXPECT_EQ("2 3 1", test::ChildLayerNamesAsString(*root.get()));
root->StackAbove(l2.get(), l3.get());
EXPECT_EQ("3 2 1", test::ChildLayerNamesAsString(*root.get()));
root->StackAbove(l1.get(), l3.get());
EXPECT_EQ("3 1 2", test::ChildLayerNamesAsString(*root.get()));
root->StackAbove(l2.get(), l1.get());
EXPECT_EQ("3 1 2", test::ChildLayerNamesAsString(*root.get()));
root->StackAtBottom(l2.get());
EXPECT_EQ("2 3 1", test::ChildLayerNamesAsString(*root.get()));
root->StackAtBottom(l3.get());
EXPECT_EQ("3 2 1", test::ChildLayerNamesAsString(*root.get()));
root->StackAtBottom(l3.get());
EXPECT_EQ("3 2 1", test::ChildLayerNamesAsString(*root.get()));
root->StackBelow(l2.get(), l3.get());
EXPECT_EQ("2 3 1", test::ChildLayerNamesAsString(*root.get()));
root->StackBelow(l1.get(), l3.get());
EXPECT_EQ("2 1 3", test::ChildLayerNamesAsString(*root.get()));
root->StackBelow(l3.get(), l2.get());
EXPECT_EQ("3 2 1", test::ChildLayerNamesAsString(*root.get()));
root->StackBelow(l3.get(), l2.get());
EXPECT_EQ("3 2 1", test::ChildLayerNamesAsString(*root.get()));
root->StackBelow(l3.get(), l1.get());
EXPECT_EQ("2 3 1", test::ChildLayerNamesAsString(*root.get()));
std::vector<Layer*> child_bottom_stack;
child_bottom_stack.emplace_back(l1.get());
root->StackChildrenAtBottom(child_bottom_stack);
EXPECT_EQ("1 2 3", test::ChildLayerNamesAsString(*root.get()));
child_bottom_stack.clear();
child_bottom_stack.emplace_back(l3.get());
child_bottom_stack.emplace_back(l2.get());
root->StackChildrenAtBottom(child_bottom_stack);
EXPECT_EQ("3 2 1", test::ChildLayerNamesAsString(*root.get()));
child_bottom_stack.clear();
child_bottom_stack.emplace_back(l2.get());
child_bottom_stack.emplace_back(l1.get());
root->StackChildrenAtBottom(child_bottom_stack);
EXPECT_EQ("2 1 3", test::ChildLayerNamesAsString(*root.get()));
child_bottom_stack.clear();
child_bottom_stack.emplace_back(l3.get());
child_bottom_stack.emplace_back(l1.get());
child_bottom_stack.emplace_back(l2.get());
root->StackChildrenAtBottom(child_bottom_stack);
EXPECT_EQ("3 1 2", test::ChildLayerNamesAsString(*root.get()));
child_bottom_stack.clear();
root->StackChildrenAtBottom(child_bottom_stack);
EXPECT_EQ("3 1 2", test::ChildLayerNamesAsString(*root.get()));
}
// Verifies SetBounds triggers the appropriate painting/drawing.
TEST_F(LayerWithNullDelegateTest, SetBoundsSchedulesPaint) {
std::unique_ptr<Layer> l1 = CreateTextureLayer(gfx::Rect(0, 0, 200, 200));
compositor()->SetRootLayer(l1.get());
Draw();
l1->SetBounds(gfx::Rect(5, 5, 200, 200));
// The CompositorDelegate (us) should have been told to draw for a move.
WaitForDraw();
l1->SetBounds(gfx::Rect(5, 5, 100, 100));
// The CompositorDelegate (us) should have been told to draw for a resize.
WaitForDraw();
}
// Checks that the damage rect for a TextureLayer is empty after a commit.
TEST_F(LayerWithNullDelegateTest, EmptyDamagedRect) {
base::RunLoop run_loop;
viz::ReleaseCallback callback = base::BindOnce(
[](base::RunLoop* run_loop, const gpu::SyncToken& sync_token,
bool is_lost) { run_loop->Quit(); },
base::Unretained(&run_loop));
std::unique_ptr<Layer> root = CreateLayer(LAYER_SOLID_COLOR);
constexpr gfx::Size size(64, 64);
auto resource = viz::TransferableResource::MakeGL(
gpu::Mailbox::Generate(), GL_LINEAR, GL_TEXTURE_2D, gpu::SyncToken(),
size, false /* is_overlay_candidate */);
root->SetTransferableResource(
resource, viz::SingleReleaseCallback::Create(std::move(callback)),
gfx::Size(10, 10));
compositor()->SetRootLayer(root.get());
root->SetBounds(gfx::Rect(0, 0, 10, 10));
root->SetVisible(true);
WaitForCommit();
gfx::Rect damaged_rect(0, 0, 5, 5);
root->SchedulePaint(damaged_rect);
EXPECT_EQ(damaged_rect, root->damaged_region_for_testing().bounds());
WaitForCommit();
EXPECT_TRUE(root->damaged_region_for_testing().IsEmpty());
// The texture mailbox has a reference from an in-flight texture layer.
// We clear the texture mailbox from the root layer and draw a new frame
// to ensure that the texture mailbox is released.
root->SetShowSolidColorContent();
Draw();
// Wait for texture mailbox release to avoid DCHECKs.
run_loop.Run();
}
// Tests that in deferred paint request, the layer damage will be accumulated.
TEST_F(LayerWithNullDelegateTest, UpdateDamageInDeferredPaint) {
gfx::Rect bound(gfx::Rect(500, 500));
std::unique_ptr<Layer> root = CreateTextureRootLayer(bound);
EXPECT_EQ(bound, root->damaged_region_for_testing());
WaitForCommit();
EXPECT_EQ(gfx::Rect(), root->damaged_region_for_testing());
EXPECT_EQ(bound, LastInvalidation());
// Deferring paint.
root->AddDeferredPaintRequest();
// During deferring paint request, invalid_rect will not be set to
// cc_layer_->inputs_->update_rect, and the paint_region is empty.
gfx::Rect bound1(gfx::Rect(100, 100));
root->SchedulePaint(bound1);
EXPECT_EQ(bound1, root->damaged_region_for_testing());
root->SendDamagedRects();
EXPECT_EQ(gfx::Rect(), root->cc_layer_for_testing()->update_rect());
root->PaintContentsToDisplayList(
cc::ContentLayerClient::PAINTING_BEHAVIOR_NORMAL);
EXPECT_EQ(gfx::Rect(), LastInvalidation());
// During deferring paint request, a new invalid_rect will be accumulated.
gfx::Rect bound2(gfx::Rect(100, 200, 100, 100));
gfx::Rect bound_union(bound1);
bound_union.Union(bound2);
root->SchedulePaint(bound2);
EXPECT_EQ(bound_union, root->damaged_region_for_testing().bounds());
root->SendDamagedRects();
EXPECT_EQ(gfx::Rect(), root->cc_layer_for_testing()->update_rect());
root->PaintContentsToDisplayList(
cc::ContentLayerClient::PAINTING_BEHAVIOR_NORMAL);
EXPECT_EQ(gfx::Rect(), LastInvalidation());
// Remove deferring paint request.
root->RemoveDeferredPaintRequest();
// The invalidation region should be accumulated invalid_rect during deferred
// paint, i.e. union of bound1 and bound2.
root->SendDamagedRects();
EXPECT_EQ(bound_union, root->cc_layer_for_testing()->update_rect());
root->PaintContentsToDisplayList(
cc::ContentLayerClient::PAINTING_BEHAVIOR_NORMAL);
EXPECT_EQ(bound_union, LastInvalidation());
}
// Tests that Layer::SendDamagedRects() always recurses into its mask layer, if
// present, even if it shouldn't send its damaged regions itself.
TEST_F(LayerWithNullDelegateTest, AlwaysSendsMaskDamagedRects) {
gfx::Rect bound(gfx::Rect(2, 2));
std::unique_ptr<Layer> mask = CreateTextureLayer(bound);
std::unique_ptr<Layer> root = CreateTextureRootLayer(bound);
root->SetMaskLayer(mask.get());
WaitForCommit();
EXPECT_EQ(root->damaged_region_for_testing().bounds(), gfx::Rect());
EXPECT_EQ(mask->damaged_region_for_testing().bounds(), gfx::Rect());
const gfx::Rect invalid_rect(gfx::Size(1, 1));
mask->SchedulePaint(invalid_rect);
EXPECT_EQ(mask->damaged_region_for_testing().bounds(), invalid_rect);
root->SendDamagedRects();
EXPECT_EQ(mask->damaged_region_for_testing().bounds(), gfx::Rect());
}
// Verifies that when a layer is reflecting other layers, mirror counts of
// reflected layers are updated properly.
TEST_F(LayerWithNullDelegateTest, SetShowReflectedLayerSubtree) {
std::unique_ptr<Layer> reflected_layer_1 = CreateLayer(LAYER_SOLID_COLOR);
auto* reflected_layer_1_cc = reflected_layer_1->cc_layer_for_testing();
std::unique_ptr<Layer> reflected_layer_2 = CreateLayer(LAYER_SOLID_COLOR);
auto* reflected_layer_2_cc = reflected_layer_2->cc_layer_for_testing();
std::unique_ptr<Layer> reflecting_layer = CreateLayer(LAYER_SOLID_COLOR);
// Originally, mirror counts should be zero.
auto* reflecting_layer_cc = reflecting_layer->mirror_layer_for_testing();
EXPECT_EQ(nullptr, reflecting_layer_cc);
EXPECT_EQ(0, reflected_layer_1_cc->mirror_count());
EXPECT_EQ(0, reflected_layer_2_cc->mirror_count());
// Mirror the first layer. Its mirror count should be increased.
reflecting_layer->SetShowReflectedLayerSubtree(reflected_layer_1.get());
reflecting_layer_cc = reflecting_layer->mirror_layer_for_testing();
ASSERT_NE(nullptr, reflecting_layer_cc);
EXPECT_EQ(reflecting_layer->cc_layer_for_testing(), reflecting_layer_cc);
EXPECT_EQ(reflected_layer_1_cc, reflecting_layer_cc->mirrored_layer());
EXPECT_EQ(1, reflected_layer_1_cc->mirror_count());
EXPECT_EQ(0, reflected_layer_2_cc->mirror_count());
// Mirror the second layer. Its mirror count should be increased, but mirror
// count for the first mirrored layer should be set back to zero.
reflecting_layer->SetShowReflectedLayerSubtree(reflected_layer_2.get());
reflecting_layer_cc = reflecting_layer->mirror_layer_for_testing();
ASSERT_NE(nullptr, reflecting_layer_cc);
EXPECT_EQ(reflecting_layer->cc_layer_for_testing(), reflecting_layer_cc);
EXPECT_EQ(reflected_layer_2_cc, reflecting_layer_cc->mirrored_layer());
EXPECT_EQ(0, reflected_layer_1_cc->mirror_count());
EXPECT_EQ(1, reflected_layer_2_cc->mirror_count());
// Un-mirror the layer. All mirror counts should be set to zero.
reflecting_layer->SetShowSolidColorContent();
reflecting_layer_cc = reflecting_layer->mirror_layer_for_testing();
EXPECT_EQ(nullptr, reflecting_layer_cc);
EXPECT_EQ(0, reflected_layer_1_cc->mirror_count());
EXPECT_EQ(0, reflected_layer_2_cc->mirror_count());
}
// Verifies that when a layer is reflecting another layer, its size matches the
// size of the reflected layer.
TEST_F(LayerWithNullDelegateTest, SetShowReflectedLayerSubtreeBounds) {
const gfx::Rect reflected_bounds(0, 0, 50, 50);
const gfx::Rect reflecting_bounds(0, 50, 10, 10);
std::unique_ptr<Layer> reflected_layer = CreateLayer(LAYER_SOLID_COLOR);
reflected_layer->SetBounds(reflected_bounds);
std::unique_ptr<Layer> reflecting_layer = CreateLayer(LAYER_SOLID_COLOR);
reflecting_layer->SetBounds(reflecting_bounds);
EXPECT_EQ(reflecting_bounds, reflecting_layer->bounds());
reflecting_layer->SetShowReflectedLayerSubtree(reflected_layer.get());
EXPECT_EQ(reflecting_bounds.origin(), reflecting_layer->bounds().origin());
EXPECT_EQ(reflected_bounds.size(), reflecting_layer->bounds().size());
const gfx::Rect new_reflected_bounds(10, 10, 30, 30);
reflected_layer->SetBounds(new_reflected_bounds);
EXPECT_EQ(reflecting_bounds.origin(), reflecting_layer->bounds().origin());
EXPECT_EQ(new_reflected_bounds.size(), reflecting_layer->bounds().size());
// No crashes on reflected layer bounds change after the reflecting layer is
// released.
reflecting_layer = nullptr;
reflected_layer->SetBounds(reflected_bounds);
EXPECT_EQ(reflected_bounds, reflected_layer->bounds());
}
void ExpectRgba(int x, int y, SkColor expected_color, SkColor actual_color) {
EXPECT_EQ(expected_color, actual_color)
<< "Pixel error at x=" << x << " y=" << y << "; "
<< "actual RGBA=("
<< SkColorGetR(actual_color) << ","
<< SkColorGetG(actual_color) << ","
<< SkColorGetB(actual_color) << ","
<< SkColorGetA(actual_color) << "); "
<< "expected RGBA=("
<< SkColorGetR(expected_color) << ","
<< SkColorGetG(expected_color) << ","
<< SkColorGetB(expected_color) << ","
<< SkColorGetA(expected_color) << ")";
}
// Checks that pixels are actually drawn to the screen with a read back.
TEST_P(LayerWithRealCompositorTest, DrawPixels) {
gfx::Size viewport_size = GetCompositor()->size();
// The window should be some non-trivial size but may not be exactly
// 500x500 on all platforms/bots.
EXPECT_GE(viewport_size.width(), 200);
EXPECT_GE(viewport_size.height(), 200);
int blue_height = 10;
std::unique_ptr<Layer> layer =
CreateColorLayer(SK_ColorRED, gfx::Rect(viewport_size));
std::unique_ptr<Layer> layer2 = CreateColorLayer(
SK_ColorBLUE, gfx::Rect(0, 0, viewport_size.width(), blue_height));
layer->Add(layer2.get());
DrawTree(layer.get());
SkBitmap bitmap;
ReadPixels(&bitmap, gfx::Rect(viewport_size));
ASSERT_FALSE(bitmap.empty());
for (int x = 0; x < viewport_size.width(); x++) {
for (int y = 0; y < viewport_size.height(); y++) {
SkColor actual_color = bitmap.getColor(x, y);
SkColor expected_color = y < blue_height ? SK_ColorBLUE : SK_ColorRED;
ExpectRgba(x, y, expected_color, actual_color);
}
}
}
// Checks that drawing a layer with transparent pixels is blended correctly
// with the lower layer.
TEST_P(LayerWithRealCompositorTest, DrawAlphaBlendedPixels) {
gfx::Size viewport_size = GetCompositor()->size();
int test_size = 200;
EXPECT_GE(viewport_size.width(), test_size);
EXPECT_GE(viewport_size.height(), test_size);
// Blue with a wee bit of transparency.
SkColor blue_with_alpha = SkColorSetARGB(40, 10, 20, 200);
SkColor blend_color = SkColorSetARGB(255, 216, 3, 32);
std::unique_ptr<Layer> background_layer =
CreateColorLayer(SK_ColorRED, gfx::Rect(viewport_size));
std::unique_ptr<Layer> foreground_layer =
CreateColorLayer(blue_with_alpha, gfx::Rect(viewport_size));
// This must be set to false for layers with alpha to be blended correctly.
foreground_layer->SetFillsBoundsOpaquely(false);
background_layer->Add(foreground_layer.get());
DrawTree(background_layer.get());
SkBitmap bitmap;
ReadPixels(&bitmap, gfx::Rect(viewport_size));
ASSERT_FALSE(bitmap.empty());
SkBitmap original_bitmap;
original_bitmap.allocPixels(bitmap.info());
original_bitmap.eraseColor(blend_color);
cc::FuzzyPixelOffByOneComparator comparator(false);
EXPECT_TRUE(comparator.Compare(bitmap, original_bitmap));
}
// Checks that using the AlphaShape filter applied to a layer with
// transparency, alpha-blends properly with the layer below.
TEST_P(LayerWithRealCompositorTest, DrawAlphaThresholdFilterPixels) {
gfx::Size viewport_size = GetCompositor()->size();
int test_size = 200;
EXPECT_GE(viewport_size.width(), test_size);
EXPECT_GE(viewport_size.height(), test_size);
int blue_height = 10;
SkColor blue_with_alpha = SkColorSetARGB(40, 0, 0, 255);
SkColor blend_color = SkColorSetARGB(255, 215, 0, 40);
std::unique_ptr<Layer> background_layer =
CreateColorLayer(SK_ColorRED, gfx::Rect(viewport_size));
std::unique_ptr<Layer> foreground_layer =
CreateColorLayer(blue_with_alpha, gfx::Rect(viewport_size));
// Add a shape to restrict the visible part of the layer.
auto shape = std::make_unique<Layer::ShapeRects>();
shape->emplace_back(0, 0, viewport_size.width(), blue_height);
foreground_layer->SetAlphaShape(std::move(shape));
foreground_layer->SetFillsBoundsOpaquely(false);
background_layer->Add(foreground_layer.get());
DrawTree(background_layer.get());
SkBitmap bitmap;
ReadPixels(&bitmap, gfx::Rect(viewport_size));
ASSERT_FALSE(bitmap.empty());
for (int x = 0; x < test_size; x++) {
for (int y = 0; y < test_size; y++) {
SkColor actual_color = bitmap.getColor(x, y);
ExpectRgba(x, y, actual_color,
y < blue_height ? blend_color : SK_ColorRED);
}
}
}
// Checks the logic around Compositor::SetRootLayer and Layer::SetCompositor.
TEST_P(LayerWithRealCompositorTest, SetRootLayer) {
Compositor* compositor = GetCompositor();
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> l2 =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(10, 10, 350, 350));
EXPECT_EQ(NULL, l1->GetCompositor());
EXPECT_EQ(NULL, l2->GetCompositor());
compositor->SetRootLayer(l1.get());
EXPECT_EQ(compositor, l1->GetCompositor());
l1->Add(l2.get());
EXPECT_EQ(compositor, l2->GetCompositor());
l1->Remove(l2.get());
EXPECT_EQ(NULL, l2->GetCompositor());
l1->Add(l2.get());
EXPECT_EQ(compositor, l2->GetCompositor());
compositor->SetRootLayer(NULL);
EXPECT_EQ(NULL, l1->GetCompositor());
EXPECT_EQ(NULL, l2->GetCompositor());
}
// Checks that compositor observers are notified when:
// - DrawTree is called,
// - After ScheduleDraw is called, or
// - Whenever SetBounds, SetOpacity or SetTransform are called.
// TODO(vollick): could be reorganized into compositor_unittest.cc
// Flaky on Windows. See https://crbug.com/784563.
// Flaky on Linux tsan. See https://crbug.com/834026.
#if defined(OS_WIN) || defined(OS_LINUX)
#define MAYBE_CompositorObservers DISABLED_CompositorObservers
#else
#define MAYBE_CompositorObservers CompositorObservers
#endif
TEST_P(LayerWithRealCompositorTest, MAYBE_CompositorObservers) {
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorRED, gfx::Rect(20, 20, 400, 400));
std::unique_ptr<Layer> l2 =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(10, 10, 350, 350));
l1->Add(l2.get());
TestCompositorObserver observer;
GetCompositor()->AddObserver(&observer);
// Explicitly called DrawTree should cause the observers to be notified.
// NOTE: this call to DrawTree sets l1 to be the compositor's root layer.
DrawTree(l1.get());
EXPECT_TRUE(observer.notified());
// ScheduleDraw without any visible change should cause a commit.
observer.Reset();
l1->ScheduleDraw();
WaitForCommit();
EXPECT_TRUE(observer.committed());
// Moving, but not resizing, a layer should alert the observers.
observer.Reset();
l2->SetBounds(gfx::Rect(0, 0, 350, 350));
WaitForSwap();
EXPECT_TRUE(observer.notified());
// So should resizing a layer.
observer.Reset();
l2->SetBounds(gfx::Rect(0, 0, 400, 400));
WaitForSwap();
EXPECT_TRUE(observer.notified());
// Opacity changes should alert the observers.
observer.Reset();
l2->SetOpacity(0.5f);
WaitForSwap();
EXPECT_TRUE(observer.notified());
// So should setting the opacity back.
observer.Reset();
l2->SetOpacity(1.0f);
WaitForSwap();
EXPECT_TRUE(observer.notified());
// Setting the transform of a layer should alert the observers.
observer.Reset();
gfx::Transform transform;
transform.Translate(200.0, 200.0);
transform.Rotate(90.0);
transform.Translate(-200.0, -200.0);
l2->SetTransform(transform);
WaitForSwap();
EXPECT_TRUE(observer.notified());
GetCompositor()->RemoveObserver(&observer);
// Opacity changes should no longer alert the removed observer.
observer.Reset();
l2->SetOpacity(0.5f);
WaitForSwap();
EXPECT_FALSE(observer.notified());
}
// Checks that modifying the hierarchy correctly affects final composite.
TEST_P(LayerWithRealCompositorTest, ModifyHierarchy) {
viz::ParentLocalSurfaceIdAllocator allocator;
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(50, 50), allocator.GetCurrentLocalSurfaceIdAllocation());
// l0
// +-l11
// | +-l21
// +-l12
std::unique_ptr<Layer> l0 =
CreateColorLayer(SK_ColorRED, gfx::Rect(0, 0, 50, 50));
std::unique_ptr<Layer> l11 =
CreateColorLayer(SK_ColorGREEN, gfx::Rect(0, 0, 25, 25));
std::unique_ptr<Layer> l21 =
CreateColorLayer(SK_ColorMAGENTA, gfx::Rect(0, 0, 15, 15));
std::unique_ptr<Layer> l12 =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(10, 10, 25, 25));
base::FilePath ref_img1 = test_data_dir().AppendASCII("ModifyHierarchy1.png");
base::FilePath ref_img2 = test_data_dir().AppendASCII("ModifyHierarchy2.png");
SkBitmap bitmap;
l0->Add(l11.get());
l11->Add(l21.get());
l0->Add(l12.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
// WritePNGFile(bitmap, ref_img1);
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img1, cc::ExactPixelComparator(true)));
l0->StackAtTop(l11.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
// WritePNGFile(bitmap, ref_img2);
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img2, cc::ExactPixelComparator(true)));
// should restore to original configuration
l0->StackAbove(l12.get(), l11.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img1, cc::ExactPixelComparator(true)));
// l11 back to front
l0->StackAtTop(l11.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img2, cc::ExactPixelComparator(true)));
// should restore to original configuration
l0->StackAbove(l12.get(), l11.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img1, cc::ExactPixelComparator(true)));
// l11 back to front
l0->StackAbove(l11.get(), l12.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img2, cc::ExactPixelComparator(true)));
}
// Checks that basic background blur is working.
TEST_P(LayerWithRealCompositorTest, BackgroundBlur) {
viz::ParentLocalSurfaceIdAllocator allocator;
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(200, 200),
allocator.GetCurrentLocalSurfaceIdAllocation());
// l0
// +-l1
// +-l2
std::unique_ptr<Layer> l0 =
CreateColorLayer(SK_ColorRED, gfx::Rect(0, 0, 200, 200));
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorGREEN, gfx::Rect(100, 100, 100, 100));
SkColor blue_with_alpha = SkColorSetARGB(40, 10, 20, 200);
std::unique_ptr<Layer> l2 =
CreateColorLayer(blue_with_alpha, gfx::Rect(50, 50, 100, 100));
l2->SetFillsBoundsOpaquely(false);
l2->SetBackgroundBlur(15);
base::FilePath ref_img1 = test_data_dir().AppendASCII("BackgroundBlur1.png");
base::FilePath ref_img2 = test_data_dir().AppendASCII("BackgroundBlur2.png");
SkBitmap bitmap;
// 25% of image can have up to a difference of 3.
cc::FuzzyPixelComparator fuzzy_comparator(true, 25.f, 0.0f, 3.f, 3, 0);
l0->Add(l1.get());
l0->Add(l2.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
// WritePNGFile(bitmap, ref_img1, false);
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img1, fuzzy_comparator));
l0->StackAtTop(l1.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
// WritePNGFile(bitmap, ref_img2, false);
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img2, fuzzy_comparator));
}
// Checks that background blur bounds rect gets properly updated when device
// scale changes.
TEST_P(LayerWithRealCompositorTest, BackgroundBlurChangeDeviceScale) {
viz::ParentLocalSurfaceIdAllocator allocator;
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(200, 200),
allocator.GetCurrentLocalSurfaceIdAllocation());
// l0
// +-l1
// +-l2
std::unique_ptr<Layer> l0 =
CreateColorLayer(SK_ColorRED, gfx::Rect(0, 0, 200, 200));
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorGREEN, gfx::Rect(100, 100, 100, 100));
SkColor blue_with_alpha = SkColorSetARGB(40, 10, 20, 200);
std::unique_ptr<Layer> l2 =
CreateColorLayer(blue_with_alpha, gfx::Rect(50, 50, 100, 100));
l2->SetFillsBoundsOpaquely(false);
l2->SetBackgroundBlur(15);
base::FilePath ref_img1 = test_data_dir().AppendASCII("BackgroundBlur1.png");
base::FilePath ref_img2 =
test_data_dir().AppendASCII("BackgroundBlur1_zoom.png");
SkBitmap bitmap;
// 25% of image can have up to a difference of 3.
cc::FuzzyPixelComparator fuzzy_comparator(true, 25.f, 0.0f, 3.f, 3, 0);
l0->Add(l1.get());
l0->Add(l2.get());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
// See LayerWithRealCompositorTest.BackgroundBlur test to rewrite this
// baseline.
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img1, fuzzy_comparator));
allocator.GenerateId();
// Now change the scale, and make sure the bounds are still correct.
GetCompositor()->SetScaleAndSize(
2.0f, gfx::Size(200, 200),
allocator.GetCurrentLocalSurfaceIdAllocation());
DrawTree(l0.get());
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
// WritePNGFile(bitmap, ref_img2, false);
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img2, fuzzy_comparator));
}
// Opacity is rendered correctly.
// Checks that modifying the hierarchy correctly affects final composite.
TEST_P(LayerWithRealCompositorTest, Opacity) {
viz::ParentLocalSurfaceIdAllocator allocator;
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(50, 50), allocator.GetCurrentLocalSurfaceIdAllocation());
// l0
// +-l11
std::unique_ptr<Layer> l0 =
CreateColorLayer(SK_ColorRED, gfx::Rect(0, 0, 50, 50));
std::unique_ptr<Layer> l11 =
CreateColorLayer(SK_ColorGREEN, gfx::Rect(0, 0, 25, 25));
base::FilePath ref_img = test_data_dir().AppendASCII("Opacity.png");
l11->SetOpacity(0.75);
l0->Add(l11.get());
DrawTree(l0.get());
SkBitmap bitmap;
ReadPixels(&bitmap);
ASSERT_FALSE(bitmap.empty());
// WritePNGFile(bitmap, ref_img);
EXPECT_TRUE(MatchesPNGFile(bitmap, ref_img, cc::ExactPixelComparator(true)));
}
namespace {
class SchedulePaintLayerDelegate : public LayerDelegate {
public:
SchedulePaintLayerDelegate() : paint_count_(0), layer_(NULL) {}
~SchedulePaintLayerDelegate() override {}
void set_layer(Layer* layer) {
layer_ = layer;
layer_->set_delegate(this);
}
void SetSchedulePaintRect(const gfx::Rect& rect) {
schedule_paint_rect_ = rect;
}
int GetPaintCountAndClear() {
int value = paint_count_;
paint_count_ = 0;
return value;
}
const gfx::Rect& last_clip_rect() const { return last_clip_rect_; }
private:
// Overridden from LayerDelegate:
void OnPaintLayer(const ui::PaintContext& context) override {
paint_count_++;
if (!schedule_paint_rect_.IsEmpty()) {
layer_->SchedulePaint(schedule_paint_rect_);
schedule_paint_rect_ = gfx::Rect();
}
last_clip_rect_ = context.InvalidationForTesting();
}
void OnDeviceScaleFactorChanged(float old_device_scale_factor,
float new_device_scale_factor) override {}
int paint_count_;
Layer* layer_;
gfx::Rect schedule_paint_rect_;
gfx::Rect last_clip_rect_;
DISALLOW_COPY_AND_ASSIGN(SchedulePaintLayerDelegate);
};
} // namespace
// Verifies that if SchedulePaint is invoked during painting the layer is still
// marked dirty.
TEST_F(LayerWithDelegateTest, SchedulePaintFromOnPaintLayer) {
std::unique_ptr<Layer> root =
CreateColorLayer(SK_ColorRED, gfx::Rect(0, 0, 500, 500));
SchedulePaintLayerDelegate child_delegate;
std::unique_ptr<Layer> child =
CreateColorLayer(SK_ColorBLUE, gfx::Rect(0, 0, 200, 200));
child_delegate.set_layer(child.get());
root->Add(child.get());
SchedulePaintForLayer(root.get());
DrawTree(root.get());
child->SchedulePaint(gfx::Rect(0, 0, 20, 20));
EXPECT_EQ(1, child_delegate.GetPaintCountAndClear());
// Set a rect so that when OnPaintLayer() is invoked SchedulePaint is invoked
// again.
child_delegate.SetSchedulePaintRect(gfx::Rect(10, 10, 30, 30));
WaitForCommit();
EXPECT_EQ(1, child_delegate.GetPaintCountAndClear());
// Because SchedulePaint() was invoked from OnPaintLayer() |child| should
// still need to be painted.
WaitForCommit();
EXPECT_EQ(1, child_delegate.GetPaintCountAndClear());
EXPECT_TRUE(child_delegate.last_clip_rect().Contains(
gfx::Rect(10, 10, 30, 30)));
}
TEST_P(LayerWithRealCompositorTest, ScaleUpDown) {
std::unique_ptr<Layer> root =
CreateColorLayer(SK_ColorWHITE, gfx::Rect(10, 20, 200, 220));
TestLayerDelegate root_delegate;
root_delegate.AddColor(SK_ColorWHITE);
root->set_delegate(&root_delegate);
root_delegate.set_layer_bounds(root->bounds());
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorWHITE, gfx::Rect(10, 20, 140, 180));
TestLayerDelegate l1_delegate;
l1_delegate.AddColor(SK_ColorWHITE);
l1->set_delegate(&l1_delegate);
l1_delegate.set_layer_bounds(l1->bounds());
viz::ParentLocalSurfaceIdAllocator allocator;
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(500, 500),
allocator.GetCurrentLocalSurfaceIdAllocation());
GetCompositor()->SetRootLayer(root.get());
root->Add(l1.get());
WaitForDraw();
EXPECT_EQ("10,20 200x220", root->bounds().ToString());
EXPECT_EQ("10,20 140x180", l1->bounds().ToString());
gfx::Size cc_bounds_size = root->cc_layer_for_testing()->bounds();
EXPECT_EQ("200x220", cc_bounds_size.ToString());
cc_bounds_size = l1->cc_layer_for_testing()->bounds();
EXPECT_EQ("140x180", cc_bounds_size.ToString());
// No scale change, so no scale notification.
EXPECT_EQ(0.0f, root_delegate.device_scale_factor());
EXPECT_EQ(0.0f, l1_delegate.device_scale_factor());
// Scale up to 2.0. Changing scale doesn't change the bounds in DIP.
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
2.0f, gfx::Size(500, 500),
allocator.GetCurrentLocalSurfaceIdAllocation());
EXPECT_EQ("10,20 200x220", root->bounds().ToString());
EXPECT_EQ("10,20 140x180", l1->bounds().ToString());
// CC layer should still match the UI layer bounds.
cc_bounds_size = root->cc_layer_for_testing()->bounds();
EXPECT_EQ("200x220", cc_bounds_size.ToString());
cc_bounds_size = l1->cc_layer_for_testing()->bounds();
EXPECT_EQ("140x180", cc_bounds_size.ToString());
// New scale factor must have been notified. Make sure painting happens at
// right scale.
EXPECT_EQ(2.0f, root_delegate.device_scale_factor());
EXPECT_EQ(2.0f, l1_delegate.device_scale_factor());
// Scale down back to 1.0f.
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(500, 500),
allocator.GetCurrentLocalSurfaceIdAllocation());
EXPECT_EQ("10,20 200x220", root->bounds().ToString());
EXPECT_EQ("10,20 140x180", l1->bounds().ToString());
// CC layer should still match the UI layer bounds.
cc_bounds_size = root->cc_layer_for_testing()->bounds();
EXPECT_EQ("200x220", cc_bounds_size.ToString());
cc_bounds_size = l1->cc_layer_for_testing()->bounds();
EXPECT_EQ("140x180", cc_bounds_size.ToString());
// New scale factor must have been notified. Make sure painting happens at
// right scale.
EXPECT_EQ(1.0f, root_delegate.device_scale_factor());
EXPECT_EQ(1.0f, l1_delegate.device_scale_factor());
root_delegate.reset();
l1_delegate.reset();
// Just changing the size shouldn't notify the scale change nor
// trigger repaint.
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(1000, 1000),
allocator.GetCurrentLocalSurfaceIdAllocation());
// No scale change, so no scale notification.
EXPECT_EQ(0.0f, root_delegate.device_scale_factor());
EXPECT_EQ(0.0f, l1_delegate.device_scale_factor());
}
TEST_P(LayerWithRealCompositorTest, ScaleReparent) {
viz::ParentLocalSurfaceIdAllocator allocator;
allocator.GenerateId();
std::unique_ptr<Layer> root =
CreateColorLayer(SK_ColorWHITE, gfx::Rect(10, 20, 200, 220));
std::unique_ptr<Layer> l1 =
CreateColorLayer(SK_ColorWHITE, gfx::Rect(10, 20, 140, 180));
TestLayerDelegate l1_delegate;
l1_delegate.AddColor(SK_ColorWHITE);
l1->set_delegate(&l1_delegate);
l1_delegate.set_layer_bounds(l1->bounds());
GetCompositor()->SetScaleAndSize(
1.0f, gfx::Size(500, 500),
allocator.GetCurrentLocalSurfaceIdAllocation());
GetCompositor()->SetRootLayer(root.get());
root->Add(l1.get());
EXPECT_EQ("10,20 140x180", l1->bounds().ToString());
gfx::Size cc_bounds_size = l1->cc_layer_for_testing()->bounds();
EXPECT_EQ("140x180", cc_bounds_size.ToString());
EXPECT_EQ(0.0f, l1_delegate.device_scale_factor());
// Remove l1 from root and change the scale.
root->Remove(l1.get());
EXPECT_EQ(NULL, l1->parent());
EXPECT_EQ(NULL, l1->GetCompositor());
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
2.0f, gfx::Size(500, 500),
allocator.GetCurrentLocalSurfaceIdAllocation());
// Sanity check on root and l1.
EXPECT_EQ("10,20 200x220", root->bounds().ToString());
cc_bounds_size = l1->cc_layer_for_testing()->bounds();
EXPECT_EQ("140x180", cc_bounds_size.ToString());
root->Add(l1.get());
EXPECT_EQ("10,20 140x180", l1->bounds().ToString());
cc_bounds_size = l1->cc_layer_for_testing()->bounds();
EXPECT_EQ("140x180", cc_bounds_size.ToString());
EXPECT_EQ(2.0f, l1_delegate.device_scale_factor());
}
// Verifies that when changing bounds on a layer that is invisible, and then
// made visible, the right thing happens:
// - if just a move, then no painting should happen.
// - if a resize, the layer should be repainted.
TEST_F(LayerWithDelegateTest, SetBoundsWhenInvisible) {
std::unique_ptr<Layer> root =
CreateNoTextureLayer(gfx::Rect(0, 0, 1000, 1000));
std::unique_ptr<Layer> child = CreateLayer(LAYER_TEXTURED);
child->SetBounds(gfx::Rect(0, 0, 500, 500));
DrawTreeLayerDelegate delegate(child->bounds());
child->set_delegate(&delegate);
root->Add(child.get());
// Paint once for initial damage.
child->SetVisible(true);
DrawTree(root.get());
// Reset into invisible state.
child->SetVisible(false);
DrawTree(root.get());
delegate.Reset();
// Move layer.
child->SetBounds(gfx::Rect(200, 200, 500, 500));
child->SetVisible(true);
DrawTree(root.get());
EXPECT_FALSE(delegate.painted());
// Reset into invisible state.
child->SetVisible(false);
DrawTree(root.get());
delegate.Reset();
// Resize layer.
child->SetBounds(gfx::Rect(200, 200, 400, 400));
child->SetVisible(true);
DrawTree(root.get());
EXPECT_TRUE(delegate.painted());
}
TEST_F(LayerWithDelegateTest, ExternalContent) {
std::unique_ptr<Layer> root =
CreateNoTextureLayer(gfx::Rect(0, 0, 1000, 1000));
std::unique_ptr<Layer> child = CreateLayer(LAYER_SOLID_COLOR);
child->SetBounds(gfx::Rect(0, 0, 10, 10));
child->SetVisible(true);
root->Add(child.get());
// The layer is already showing solid color content, so the cc layer won't
// change.
scoped_refptr<cc::Layer> before = child->cc_layer_for_testing();
child->SetShowSolidColorContent();
EXPECT_TRUE(child->cc_layer_for_testing());
EXPECT_EQ(before.get(), child->cc_layer_for_testing());
// Showing surface content changes the underlying cc layer.
viz::FrameSinkId frame_sink_id(1u, 1u);
viz::ParentLocalSurfaceIdAllocator allocator;
before = child->cc_layer_for_testing();
allocator.GenerateId();
child->SetShowSurface(
viz::SurfaceId(
frame_sink_id,
allocator.GetCurrentLocalSurfaceIdAllocation().local_surface_id()),
gfx::Size(10, 10), SK_ColorWHITE,
cc::DeadlinePolicy::UseDefaultDeadline(), false);
scoped_refptr<cc::Layer> after = child->cc_layer_for_testing();
const auto* surface = static_cast<cc::SurfaceLayer*>(after.get());
EXPECT_TRUE(after.get());
EXPECT_NE(before.get(), after.get());
EXPECT_EQ(base::nullopt, surface->deadline_in_frames());
allocator.GenerateId();
child->SetShowSurface(
viz::SurfaceId(
frame_sink_id,
allocator.GetCurrentLocalSurfaceIdAllocation().local_surface_id()),
gfx::Size(10, 10), SK_ColorWHITE,
cc::DeadlinePolicy::UseSpecifiedDeadline(4u), false);
EXPECT_EQ(4u, surface->deadline_in_frames());
}
TEST_F(LayerWithDelegateTest, ExternalContentMirroring) {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_SOLID_COLOR);
viz::SurfaceId surface_id(
viz::FrameSinkId(0, 1),
viz::LocalSurfaceId(2, base::UnguessableToken::Create()));
layer->SetShowSurface(surface_id, gfx::Size(10, 10), SK_ColorWHITE,
cc::DeadlinePolicy::UseDefaultDeadline(), false);
const auto mirror = layer->Mirror();
auto* const cc_layer = mirror->cc_layer_for_testing();
const auto* surface = static_cast<cc::SurfaceLayer*>(cc_layer);
// Mirroring preserves surface state.
EXPECT_EQ(surface_id, surface->surface_id());
surface_id =
viz::SurfaceId(viz::FrameSinkId(1, 2),
viz::LocalSurfaceId(3, base::UnguessableToken::Create()));
layer->SetShowSurface(surface_id, gfx::Size(20, 20), SK_ColorWHITE,
cc::DeadlinePolicy::UseDefaultDeadline(), false);
// The mirror should continue to use the same cc_layer.
EXPECT_EQ(cc_layer, mirror->cc_layer_for_testing());
layer->SetShowSurface(surface_id, gfx::Size(20, 20), SK_ColorWHITE,
cc::DeadlinePolicy::UseDefaultDeadline(), false);
// Surface updates propagate to the mirror.
EXPECT_EQ(surface_id, surface->surface_id());
}
TEST_F(LayerWithDelegateTest, TransferableResourceMirroring) {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_SOLID_COLOR);
constexpr gfx::Size size(64, 64);
auto resource = viz::TransferableResource::MakeGL(
gpu::Mailbox::Generate(), GL_LINEAR, GL_TEXTURE_2D, gpu::SyncToken(),
size, false /* is_overlay_candidate */);
bool release_callback_run = false;
layer->SetTransferableResource(
resource,
viz::SingleReleaseCallback::Create(
base::BindOnce(ReturnMailbox, &release_callback_run)),
gfx::Size(10, 10));
EXPECT_FALSE(release_callback_run);
EXPECT_TRUE(layer->has_external_content());
auto mirror = layer->Mirror();
EXPECT_TRUE(mirror->has_external_content());
// Clearing the resource on a mirror layer should not release the source layer
// resource.
mirror.reset();
EXPECT_FALSE(release_callback_run);
mirror = layer->Mirror();
EXPECT_TRUE(mirror->has_external_content());
// Clearing the transferable resource on the source layer should clear it from
// the mirror layer as well.
layer->SetShowSolidColorContent();
EXPECT_TRUE(release_callback_run);
EXPECT_FALSE(layer->has_external_content());
EXPECT_FALSE(mirror->has_external_content());
resource = viz::TransferableResource::MakeGL(
gpu::Mailbox::Generate(), GL_LINEAR, GL_TEXTURE_2D, gpu::SyncToken(),
size, false /* is_overlay_candidate */);
release_callback_run = false;
// Setting a transferable resource on the source layer should set it on the
// mirror layers as well.
layer->SetTransferableResource(
resource,
viz::SingleReleaseCallback::Create(
base::BindOnce(ReturnMailbox, &release_callback_run)),
gfx::Size(10, 10));
EXPECT_FALSE(release_callback_run);
EXPECT_TRUE(layer->has_external_content());
EXPECT_TRUE(mirror->has_external_content());
layer.reset();
}
// Verifies that layer filters still attached after changing implementation
// layer.
TEST_F(LayerWithDelegateTest, LayerFiltersSurvival) {
std::unique_ptr<Layer> layer = CreateLayer(LAYER_TEXTURED);
layer->SetBounds(gfx::Rect(0, 0, 10, 10));
EXPECT_TRUE(layer->cc_layer_for_testing());
EXPECT_EQ(0u, layer->cc_layer_for_testing()->filters().size());
layer->SetLayerGrayscale(0.5f);
EXPECT_EQ(layer->layer_grayscale(), 0.5f);
EXPECT_EQ(1u, layer->cc_layer_for_testing()->filters().size());
// Showing surface content changes the underlying cc layer.
scoped_refptr<cc::Layer> before = layer->cc_layer_for_testing();
layer->SetShowSurface(viz::SurfaceId(), gfx::Size(10, 10), SK_ColorWHITE,
cc::DeadlinePolicy::UseDefaultDeadline(), false);
EXPECT_EQ(layer->layer_grayscale(), 0.5f);
EXPECT_TRUE(layer->cc_layer_for_testing());
EXPECT_NE(before.get(), layer->cc_layer_for_testing());
EXPECT_EQ(1u, layer->cc_layer_for_testing()->filters().size());
}
// Tests Layer::AddThreadedAnimation and Layer::RemoveThreadedAnimation.
TEST_P(LayerWithRealCompositorTest, AddRemoveThreadedAnimations) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> l1 = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> l2 = CreateLayer(LAYER_TEXTURED);
l1->SetAnimator(LayerAnimator::CreateImplicitAnimator());
l2->SetAnimator(LayerAnimator::CreateImplicitAnimator());
auto* animation1 = l1->GetAnimator()->GetAnimationForTesting();
auto* animation2 = l2->GetAnimator()->GetAnimationForTesting();
EXPECT_FALSE(animation1->keyframe_effect()->has_any_keyframe_model());
// Trigger a threaded animation.
l1->SetOpacity(0.5f);
EXPECT_TRUE(animation1->keyframe_effect()->has_any_keyframe_model());
// Ensure we can remove a pending threaded animation.
l1->GetAnimator()->StopAnimating();
EXPECT_FALSE(animation1->keyframe_effect()->has_any_keyframe_model());
// Trigger another threaded animation.
l1->SetOpacity(0.2f);
EXPECT_TRUE(animation1->keyframe_effect()->has_any_keyframe_model());
root->Add(l1.get());
GetCompositor()->SetRootLayer(root.get());
// Now l1 is part of a tree.
EXPECT_TRUE(animation1->keyframe_effect()->has_any_keyframe_model());
l1->SetOpacity(0.1f);
// IMMEDIATELY_SET_NEW_TARGET is a default preemption strategy for conflicting
// animations.
EXPECT_FALSE(animation1->keyframe_effect()->has_any_keyframe_model());
// Adding a layer to an existing tree.
l2->SetOpacity(0.5f);
EXPECT_TRUE(animation2->keyframe_effect()->has_any_keyframe_model());
l1->Add(l2.get());
EXPECT_TRUE(animation2->keyframe_effect()->has_any_keyframe_model());
}
// Tests that in-progress threaded animations complete when a Layer's
// cc::Layer changes.
TEST_P(LayerWithRealCompositorTest, SwitchCCLayerAnimations) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> l1 = CreateLayer(LAYER_TEXTURED);
GetCompositor()->SetRootLayer(root.get());
root->Add(l1.get());
l1->SetAnimator(LayerAnimator::CreateImplicitAnimator());
EXPECT_FLOAT_EQ(l1->opacity(), 1.0f);
// Trigger a threaded animation.
l1->SetOpacity(0.5f);
// Change l1's cc::Layer.
l1->SwitchCCLayerForTest();
// Ensure that the opacity animation completed.
EXPECT_FLOAT_EQ(l1->opacity(), 0.5f);
}
// Tests that when a LAYER_SOLID_COLOR has its CC layer switched, that
// opaqueness and color set while not animating, are maintained.
TEST_P(LayerWithRealCompositorTest, SwitchCCLayerSolidColorNotAnimating) {
SkColor transparent = SK_ColorTRANSPARENT;
std::unique_ptr<Layer> root = CreateLayer(LAYER_SOLID_COLOR);
GetCompositor()->SetRootLayer(root.get());
root->SetFillsBoundsOpaquely(false);
root->SetColor(transparent);
EXPECT_FALSE(root->fills_bounds_opaquely());
EXPECT_FALSE(
root->GetAnimator()->IsAnimatingProperty(LayerAnimationElement::COLOR));
EXPECT_EQ(transparent, root->background_color());
EXPECT_EQ(transparent, root->GetTargetColor());
// Changing the underlying layer should not affect targets.
root->SwitchCCLayerForTest();
EXPECT_FALSE(root->fills_bounds_opaquely());
EXPECT_FALSE(
root->GetAnimator()->IsAnimatingProperty(LayerAnimationElement::COLOR));
EXPECT_EQ(transparent, root->background_color());
EXPECT_EQ(transparent, root->GetTargetColor());
}
// Tests that when a LAYER_SOLID_COLOR has its CC layer switched during an
// animation of its opaquness and color, that both the current values, and the
// targets are maintained.
TEST_P(LayerWithRealCompositorTest, SwitchCCLayerSolidColorWhileAnimating) {
SkColor transparent = SK_ColorTRANSPARENT;
std::unique_ptr<Layer> root = CreateLayer(LAYER_SOLID_COLOR);
GetCompositor()->SetRootLayer(root.get());
root->SetColor(SK_ColorBLACK);
EXPECT_TRUE(root->fills_bounds_opaquely());
EXPECT_EQ(SK_ColorBLACK, root->GetTargetColor());
auto long_duration_animation =
std::make_unique<ui::ScopedAnimationDurationScaleMode>(
ui::ScopedAnimationDurationScaleMode::SLOW_DURATION);
{
ui::ScopedLayerAnimationSettings animation(root->GetAnimator());
animation.SetTransitionDuration(base::TimeDelta::FromMilliseconds(1000));
root->SetFillsBoundsOpaquely(false);
root->SetColor(transparent);
}
EXPECT_TRUE(root->fills_bounds_opaquely());
EXPECT_TRUE(
root->GetAnimator()->IsAnimatingProperty(LayerAnimationElement::COLOR));
EXPECT_EQ(SK_ColorBLACK, root->background_color());
EXPECT_EQ(transparent, root->GetTargetColor());
// Changing the underlying layer should not affect targets.
root->SwitchCCLayerForTest();
EXPECT_TRUE(root->fills_bounds_opaquely());
EXPECT_TRUE(
root->GetAnimator()->IsAnimatingProperty(LayerAnimationElement::COLOR));
EXPECT_EQ(SK_ColorBLACK, root->background_color());
EXPECT_EQ(transparent, root->GetTargetColor());
// End all animations.
root->GetAnimator()->StopAnimating();
EXPECT_FALSE(root->fills_bounds_opaquely());
EXPECT_FALSE(
root->GetAnimator()->IsAnimatingProperty(LayerAnimationElement::COLOR));
EXPECT_EQ(transparent, root->background_color());
EXPECT_EQ(transparent, root->GetTargetColor());
}
// Tests that when a layer with cache_render_surface flag has its CC layer
// switched, that the cache_render_surface flag is maintained.
TEST_P(LayerWithRealCompositorTest, SwitchCCLayerCacheRenderSurface) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> l1 = CreateLayer(LAYER_TEXTURED);
GetCompositor()->SetRootLayer(root.get());
root->Add(l1.get());
l1->AddCacheRenderSurfaceRequest();
// Change l1's cc::Layer.
l1->SwitchCCLayerForTest();
// Ensure that the cache_render_surface flag is maintained.
EXPECT_TRUE(l1->cc_layer_for_testing()->cache_render_surface());
}
// Tests that when a layer with trilinear_filtering flag has its CC layer
// switched, that the trilinear_filtering flag is maintained.
TEST_P(LayerWithRealCompositorTest, SwitchCCLayerTrilinearFiltering) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> l1 = CreateLayer(LAYER_TEXTURED);
GetCompositor()->SetRootLayer(root.get());
root->Add(l1.get());
l1->AddTrilinearFilteringRequest();
// Change l1's cc::Layer.
l1->SwitchCCLayerForTest();
// Ensure that the trilinear_filtering flag is maintained.
EXPECT_TRUE(l1->cc_layer_for_testing()->trilinear_filtering());
}
// Tests that when a layer with masks_to_bounds flag has its CC layer switched,
// that the masks_to_bounds flag is maintained.
TEST_P(LayerWithRealCompositorTest, SwitchCCLayerMasksToBounds) {
std::unique_ptr<Layer> root(CreateLayer(LAYER_TEXTURED));
std::unique_ptr<Layer> l1(CreateLayer(LAYER_TEXTURED));
GetCompositor()->SetRootLayer(root.get());
root->Add(l1.get());
l1->SetMasksToBounds(true);
EXPECT_TRUE(l1->cc_layer_for_testing()->masks_to_bounds());
// Change l1's cc::Layer.
l1->SwitchCCLayerForTest();
// Ensure that the trilinear_filtering flag is maintained.
EXPECT_TRUE(l1->cc_layer_for_testing()->masks_to_bounds());
}
// An animation observer that deletes the layer when the animation ends.
class TestAnimationObserver : public ImplicitAnimationObserver {
public:
TestAnimationObserver() = default;
Layer* layer() const { return layer_.get(); }
void SetLayer(std::unique_ptr<Layer> layer) { layer_ = std::move(layer); }
// ui::ImplicitAnimationObserver overrides:
void OnImplicitAnimationsCompleted() override {}
protected:
void OnLayerAnimationEnded(LayerAnimationSequence* sequence) override {
layer_.reset();
}
private:
std::unique_ptr<Layer> layer_;
DISALLOW_COPY_AND_ASSIGN(TestAnimationObserver);
};
// Triggerring a OnDeviceScaleFactorChanged while a layer is undergoing
// transform animation, may cause a crash. This is because the layer may be
// deleted by the animation observer leading to a seg fault.
TEST_P(LayerWithRealCompositorTest, DeletingLayerDuringScaleFactorChange) {
TestAnimationObserver animation_observer;
std::unique_ptr<Layer> root = CreateLayer(LAYER_SOLID_COLOR);
animation_observer.SetLayer(CreateLayer(LAYER_SOLID_COLOR));
Layer* layer_to_delete = animation_observer.layer();
GetCompositor()->SetRootLayer(root.get());
root->Add(layer_to_delete);
EXPECT_EQ(gfx::Transform(), layer_to_delete->GetTargetTransform());
gfx::Transform transform;
transform.Scale(2, 1);
transform.Translate(10, 5);
auto long_duration_animation =
std::make_unique<ui::ScopedAnimationDurationScaleMode>(
ui::ScopedAnimationDurationScaleMode::SLOW_DURATION);
{
ui::ScopedLayerAnimationSettings animation(layer_to_delete->GetAnimator());
animation.AddObserver(&animation_observer);
animation.SetTransitionDuration(base::TimeDelta::FromMilliseconds(1000));
layer_to_delete->SetTransform(transform);
}
// This call should not crash.
root->OnDeviceScaleFactorChanged(2.f);
animation_observer.SetLayer(CreateLayer(LAYER_SOLID_COLOR));
layer_to_delete = animation_observer.layer();
std::unique_ptr<Layer> child = CreateLayer(LAYER_SOLID_COLOR);
root->Add(layer_to_delete);
layer_to_delete->Add(child.get());
long_duration_animation =
std::make_unique<ui::ScopedAnimationDurationScaleMode>(
ui::ScopedAnimationDurationScaleMode::SLOW_DURATION);
{
ui::ScopedLayerAnimationSettings animation(layer_to_delete->GetAnimator());
animation.AddObserver(&animation_observer);
animation.SetTransitionDuration(base::TimeDelta::FromMilliseconds(1000));
layer_to_delete->SetTransform(transform);
}
// This call should not crash.
root->OnDeviceScaleFactorChanged(1.5f);
animation_observer.SetLayer(CreateLayer(LAYER_SOLID_COLOR));
layer_to_delete = animation_observer.layer();
std::unique_ptr<Layer> child2 = CreateLayer(LAYER_SOLID_COLOR);
root->Add(layer_to_delete);
layer_to_delete->Add(child.get());
layer_to_delete->Add(child2.get());
long_duration_animation =
std::make_unique<ui::ScopedAnimationDurationScaleMode>(
ui::ScopedAnimationDurationScaleMode::SLOW_DURATION);
{
ui::ScopedLayerAnimationSettings animation(child->GetAnimator());
animation.AddObserver(&animation_observer);
animation.SetTransitionDuration(base::TimeDelta::FromMilliseconds(1000));
child->SetTransform(transform);
}
// This call should not crash.
root->OnDeviceScaleFactorChanged(2.f);
}
// Tests that the animators in the layer tree is added to the
// animator-collection when the root-layer is set to the compositor.
TEST_F(LayerWithDelegateTest, RootLayerAnimatorsInCompositor) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_SOLID_COLOR);
std::unique_ptr<Layer> child =
CreateColorLayer(SK_ColorRED, gfx::Rect(10, 10));
child->SetAnimator(LayerAnimator::CreateImplicitAnimator());
child->SetOpacity(0.5f);
root->Add(child.get());
EXPECT_FALSE(compositor()->layer_animator_collection()->HasActiveAnimators());
compositor()->SetRootLayer(root.get());
EXPECT_TRUE(compositor()->layer_animator_collection()->HasActiveAnimators());
}
// Tests that adding/removing a layer adds/removes the animator from its entire
// subtree from the compositor's animator-collection.
TEST_F(LayerWithDelegateTest, AddRemoveLayerUpdatesAnimatorsFromSubtree) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> child = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> grandchild =
CreateColorLayer(SK_ColorRED, gfx::Rect(10, 10));
root->Add(child.get());
child->Add(grandchild.get());
compositor()->SetRootLayer(root.get());
grandchild->SetAnimator(LayerAnimator::CreateImplicitAnimator());
grandchild->SetOpacity(0.5f);
EXPECT_TRUE(compositor()->layer_animator_collection()->HasActiveAnimators());
root->Remove(child.get());
EXPECT_FALSE(compositor()->layer_animator_collection()->HasActiveAnimators());
root->Add(child.get());
EXPECT_TRUE(compositor()->layer_animator_collection()->HasActiveAnimators());
}
TEST_F(LayerWithDelegateTest, DestroyingLayerRemovesTheAnimatorFromCollection) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> child = CreateLayer(LAYER_TEXTURED);
root->Add(child.get());
compositor()->SetRootLayer(root.get());
child->SetAnimator(LayerAnimator::CreateImplicitAnimator());
child->SetOpacity(0.5f);
EXPECT_TRUE(compositor()->layer_animator_collection()->HasActiveAnimators());
child.reset();
EXPECT_FALSE(compositor()->layer_animator_collection()->HasActiveAnimators());
}
// A LayerAnimationObserver that removes a child layer from a parent when an
// animation completes.
class LayerRemovingLayerAnimationObserver : public LayerAnimationObserver {
public:
LayerRemovingLayerAnimationObserver(Layer* root, Layer* child)
: root_(root), child_(child) {}
// LayerAnimationObserver:
void OnLayerAnimationEnded(LayerAnimationSequence* sequence) override {
root_->Remove(child_);
}
void OnLayerAnimationAborted(LayerAnimationSequence* sequence) override {
root_->Remove(child_);
}
void OnLayerAnimationScheduled(LayerAnimationSequence* sequence) override {}
private:
Layer* root_;
Layer* child_;
DISALLOW_COPY_AND_ASSIGN(LayerRemovingLayerAnimationObserver);
};
// Verifies that empty LayerAnimators are not left behind when removing child
// Layers that own an empty LayerAnimator. See http://crbug.com/552037.
TEST_F(LayerWithDelegateTest, NonAnimatingAnimatorsAreRemovedFromCollection) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> parent = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> child = CreateLayer(LAYER_TEXTURED);
root->Add(parent.get());
parent->Add(child.get());
compositor()->SetRootLayer(root.get());
child->SetAnimator(LayerAnimator::CreateDefaultAnimator());
LayerRemovingLayerAnimationObserver observer(root.get(), parent.get());
child->GetAnimator()->AddObserver(&observer);
std::unique_ptr<LayerAnimationElement> element =
ui::LayerAnimationElement::CreateOpacityElement(
0.5f, base::TimeDelta::FromSeconds(1));
LayerAnimationSequence* sequence =
new LayerAnimationSequence(std::move(element));
child->GetAnimator()->StartAnimation(sequence);
EXPECT_TRUE(compositor()->layer_animator_collection()->HasActiveAnimators());
child->GetAnimator()->StopAnimating();
EXPECT_FALSE(root->Contains(parent.get()));
EXPECT_FALSE(compositor()->layer_animator_collection()->HasActiveAnimators());
}
namespace {
std::string Vector2dFTo100thPrecisionString(const gfx::Vector2dF& vector) {
return base::StringPrintf("%.2f %0.2f", vector.x(), vector.y());
}
} // namespace
TEST_P(LayerWithRealCompositorTest, SnapLayerToPixels) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> c1 = CreateLayer(LAYER_TEXTURED);
std::unique_ptr<Layer> c11 = CreateLayer(LAYER_TEXTURED);
viz::ParentLocalSurfaceIdAllocator allocator;
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.25f, gfx::Size(100, 100),
allocator.GetCurrentLocalSurfaceIdAllocation());
GetCompositor()->SetRootLayer(root.get());
root->Add(c1.get());
c1->Add(c11.get());
root->SetBounds(gfx::Rect(0, 0, 100, 100));
c1->SetBounds(gfx::Rect(1, 1, 10, 10));
c11->SetBounds(gfx::Rect(1, 1, 10, 10));
// 1 at 1.25 scale = 1.25 : (-0.25) / 1.25 = -0.20
EXPECT_EQ("-0.20 -0.20",
Vector2dFTo100thPrecisionString(c11->GetSubpixelOffset()));
allocator.GenerateId();
GetCompositor()->SetScaleAndSize(
1.5f, gfx::Size(100, 100),
allocator.GetCurrentLocalSurfaceIdAllocation());
// 1 at 1.5 scale = 1.5 : (round(1.5) - 1.5) / 1.5 = 0.33
EXPECT_EQ("0.33 0.33",
Vector2dFTo100thPrecisionString(c11->GetSubpixelOffset()));
c11->SetBounds(gfx::Rect(2, 2, 10, 10));
// 2 at 1.5 scale = 3 : (round(3) - 3) / 1.5 = 0
EXPECT_EQ("0.00 0.00",
Vector2dFTo100thPrecisionString(c11->GetSubpixelOffset()));
}
// Verify that LayerDelegate::OnLayerBoundsChanged() is called when the bounds
// are set without an animation.
TEST(LayerDelegateTest, OnLayerBoundsChanged) {
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
const gfx::Rect initial_bounds = layer->bounds();
constexpr gfx::Rect kTargetBounds(1, 2, 3, 4);
EXPECT_CALL(delegate,
OnLayerBoundsChanged(initial_bounds,
PropertyChangeReason::NOT_FROM_ANIMATION))
.WillOnce(testing::Invoke([&](const gfx::Rect&, PropertyChangeReason) {
// Verify that |layer->bounds()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->bounds(), kTargetBounds);
}));
layer->SetBounds(kTargetBounds);
}
// Verify that LayerDelegate::OnLayerBoundsChanged() is called at every step of
// a bounds animation.
TEST(LayerDelegateTest, OnLayerBoundsChangedAnimation) {
ScopedAnimationDurationScaleMode scoped_animation_duration_scale_mode(
ScopedAnimationDurationScaleMode::NORMAL_DURATION);
LayerAnimatorTestController test_controller(
LayerAnimator::CreateImplicitAnimator());
LayerAnimator* const animator = test_controller.animator();
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
layer->SetAnimator(animator);
const gfx::Rect initial_bounds = layer->bounds();
constexpr gfx::Rect kTargetBounds(10, 20, 30, 40);
const gfx::Rect step_bounds =
gfx::Tween::RectValueBetween(0.5, initial_bounds, kTargetBounds);
// Start the animation.
std::unique_ptr<LayerAnimationElement> element =
LayerAnimationElement::CreateBoundsElement(
kTargetBounds, base::TimeDelta::FromSeconds(1));
ASSERT_FALSE(element->IsThreaded(layer.get()));
LayerAnimationElement* element_raw = element.get();
animator->StartAnimation(new LayerAnimationSequence(std::move(element)));
testing::Mock::VerifyAndClear(&delegate);
// Progress the animation.
EXPECT_CALL(delegate,
OnLayerBoundsChanged(initial_bounds,
PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](const gfx::Rect&, PropertyChangeReason) {
// Verify that |layer->bounds()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->bounds(), step_bounds);
EXPECT_TRUE(
animator->IsAnimatingProperty(LayerAnimationElement::BOUNDS));
}));
test_controller.Step(element_raw->duration() / 2);
testing::Mock::VerifyAndClear(&delegate);
// End the animation.
EXPECT_CALL(delegate, OnLayerBoundsChanged(
step_bounds, PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](const gfx::Rect&, PropertyChangeReason) {
// Verify that |layer->bounds()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->bounds(), kTargetBounds);
EXPECT_FALSE(
animator->IsAnimatingProperty(LayerAnimationElement::BOUNDS));
}));
test_controller.Step(element_raw->duration() / 2);
testing::Mock::VerifyAndClear(&delegate);
}
// Verify that LayerDelegate::OnLayerTransformed() is called when the transform
// is set without an animation.
TEST(LayerDelegateTest, OnLayerTransformed) {
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
gfx::Transform target_transform1;
target_transform1.Skew(10.0f, 5.0f);
{
EXPECT_CALL(delegate,
OnLayerTransformed(gfx::Transform(),
PropertyChangeReason::NOT_FROM_ANIMATION))
.WillOnce(testing::Invoke(
[&](const gfx::Transform& old_transform, PropertyChangeReason) {
// Verify that |layer->transform()| returns the correct value when
// the delegate is notified.
EXPECT_EQ(target_transform1, layer->transform());
}));
layer->SetTransform(target_transform1);
}
gfx::Transform target_transform2;
target_transform2.Skew(10.0f, 5.0f);
EXPECT_CALL(delegate,
OnLayerTransformed(target_transform1,
PropertyChangeReason::NOT_FROM_ANIMATION))
.WillOnce(testing::Invoke(
[&](const gfx::Transform& old_transform, PropertyChangeReason) {
// Verify that |layer->transform()| returns the correct value when
// the delegate is notified.
EXPECT_EQ(target_transform2, layer->transform());
}));
layer->SetTransform(target_transform2);
}
// Verify that LayerDelegate::OnLayerTransformed() is called at every step of a
// non-threaded transform transition.
TEST(LayerDelegateTest, OnLayerTransformedNonThreadedAnimation) {
ScopedAnimationDurationScaleMode scoped_animation_duration_scale_mode(
ScopedAnimationDurationScaleMode::NORMAL_DURATION);
LayerAnimatorTestController test_controller(
LayerAnimator::CreateImplicitAnimator());
LayerAnimator* const animator = test_controller.animator();
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
layer->SetAnimator(animator);
auto interpolated_transform = std::make_unique<InterpolatedRotation>(10, 45);
const gfx::Transform initial_transform =
interpolated_transform->Interpolate(0.0);
const gfx::Transform step_transform =
interpolated_transform->Interpolate(0.5);
const gfx::Transform target_transform =
interpolated_transform->Interpolate(1.0);
// Start the animation.
std::unique_ptr<LayerAnimationElement> element =
LayerAnimationElement::CreateInterpolatedTransformElement(
std::move(interpolated_transform), base::TimeDelta::FromSeconds(1));
// The LayerAnimationElement returned by CreateInterpolatedTransformElement()
// is non-threaded.
ASSERT_FALSE(element->IsThreaded(layer.get()));
LayerAnimationElement* element_raw = element.get();
EXPECT_CALL(delegate,
OnLayerTransformed(gfx::Transform(),
PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](const gfx::Transform& old_transform,
PropertyChangeReason) {
// Verify that |layer->transform()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->transform(), initial_transform);
EXPECT_TRUE(
animator->IsAnimatingProperty(LayerAnimationElement::TRANSFORM));
}));
animator->StartAnimation(new LayerAnimationSequence(std::move(element)));
testing::Mock::VerifyAndClear(&delegate);
// Progress the animation.
EXPECT_CALL(delegate,
OnLayerTransformed(initial_transform,
PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke(
[&](const gfx::Transform& old_transform, PropertyChangeReason) {
// Verify that |layer->transform()| returns the correct value when
// the delegate is notified.
EXPECT_EQ(layer->transform(), step_transform);
}));
test_controller.Step(element_raw->duration() / 2);
testing::Mock::VerifyAndClear(&delegate);
// End the animation.
EXPECT_CALL(
delegate,
OnLayerTransformed(step_transform, PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](const gfx::Transform& old_transform,
PropertyChangeReason) {
// Verify that |layer->transform()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->transform(), target_transform);
EXPECT_FALSE(
animator->IsAnimatingProperty(LayerAnimationElement::TRANSFORM));
}));
test_controller.Step(element_raw->duration() / 2);
testing::Mock::VerifyAndClear(&delegate);
}
// Verify that LayerDelegate::OnLayerTransformed() is called at the beginning
// and at the end of a threaded transform transition.
TEST(LayerDelegateTest, OnLayerTransformedThreadedAnimation) {
ScopedAnimationDurationScaleMode scoped_animation_duration_scale_mode(
ScopedAnimationDurationScaleMode::NORMAL_DURATION);
LayerAnimatorTestController test_controller(
LayerAnimator::CreateImplicitAnimator());
LayerAnimator* const animator = test_controller.animator();
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
layer->SetAnimator(animator);
// Start the animation.
gfx::Transform initial_transform = layer->transform();
gfx::Transform target_transform;
target_transform.Skew(10.0f, 5.0f);
std::unique_ptr<LayerAnimationElement> element =
LayerAnimationElement::CreateTransformElement(
target_transform, base::TimeDelta::FromSeconds(1));
ASSERT_TRUE(element->IsThreaded(layer.get()));
LayerAnimationElement* element_raw = element.get();
EXPECT_CALL(delegate,
OnLayerTransformed(gfx::Transform(),
PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](const gfx::Transform& old_transform,
PropertyChangeReason) {
// Verify that |layer->transform()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->transform(), initial_transform);
EXPECT_TRUE(
animator->IsAnimatingProperty(LayerAnimationElement::TRANSFORM));
}));
animator->StartAnimation(new LayerAnimationSequence(std::move(element)));
testing::Mock::VerifyAndClear(&delegate);
test_controller.StartThreadedAnimationsIfNeeded();
// End the animation.
EXPECT_CALL(delegate,
OnLayerTransformed(initial_transform,
PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](const gfx::Transform& old_transform,
PropertyChangeReason) {
// Verify that |layer->transform()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->transform(), target_transform);
EXPECT_FALSE(
animator->IsAnimatingProperty(LayerAnimationElement::TRANSFORM));
}));
test_controller.Step(
element_raw->duration() +
(element_raw->effective_start_time() - animator->last_step_time()));
testing::Mock::VerifyAndClear(&delegate);
}
// Verify that LayerDelegate::OnLayerOpacityChanged() is called when the opacity
// is set without an animation.
TEST(LayerDelegateTest, OnLayerOpacityChanged) {
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
constexpr float kTargetOpacity = 0.5f;
EXPECT_CALL(delegate,
OnLayerOpacityChanged(PropertyChangeReason::NOT_FROM_ANIMATION))
.WillOnce(testing::Invoke([&](PropertyChangeReason) {
// Verify that |layer->opacity()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->opacity(), kTargetOpacity);
}));
layer->SetOpacity(kTargetOpacity);
}
// Verify that LayerDelegate::OnLayerOpacityChanged() is called at the beginning
// and at the end of a threaded opacity animation.
TEST(LayerDelegateTest, OnLayerOpacityChangedAnimation) {
ScopedAnimationDurationScaleMode scoped_animation_duration_scale_mode(
ScopedAnimationDurationScaleMode::NORMAL_DURATION);
LayerAnimatorTestController test_controller(
LayerAnimator::CreateImplicitAnimator());
LayerAnimator* const animator = test_controller.animator();
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
layer->SetAnimator(animator);
// Start the animation.
const float initial_opacity = layer->opacity();
const float kTargetOpacity = 0.5f;
std::unique_ptr<LayerAnimationElement> element =
LayerAnimationElement::CreateOpacityElement(
kTargetOpacity, base::TimeDelta::FromSeconds(1));
ASSERT_TRUE(element->IsThreaded(layer.get()));
LayerAnimationElement* element_raw = element.get();
EXPECT_CALL(delegate,
OnLayerOpacityChanged(PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](PropertyChangeReason) {
// Verify that |layer->opacity()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->opacity(), initial_opacity);
EXPECT_TRUE(
animator->IsAnimatingProperty(LayerAnimationElement::OPACITY));
}));
animator->StartAnimation(new LayerAnimationSequence(std::move(element)));
testing::Mock::VerifyAndClear(&delegate);
test_controller.StartThreadedAnimationsIfNeeded();
// End the animation.
EXPECT_CALL(delegate,
OnLayerOpacityChanged(PropertyChangeReason::FROM_ANIMATION))
.WillOnce(testing::Invoke([&](PropertyChangeReason) {
// Verify that |layer->opacity()| returns the correct value when the
// delegate is notified.
EXPECT_EQ(layer->opacity(), kTargetOpacity);
EXPECT_FALSE(
animator->IsAnimatingProperty(LayerAnimationElement::OPACITY));
}));
test_controller.Step(
element_raw->duration() +
(element_raw->effective_start_time() - animator->last_step_time()));
testing::Mock::VerifyAndClear(&delegate);
}
// Verify that LayerDelegate::OnLayerAlphaShapeChanged() is called when the
// alpha shape of a layer is set.
TEST(LayerDelegateTest, OnLayerAlphaShapeChanged) {
auto layer = std::make_unique<Layer>(LAYER_TEXTURED);
testing::StrictMock<TestLayerDelegate> delegate;
layer->set_delegate(&delegate);
// Set an alpha shape for the layer. Expect the delegate to be notified.
auto shape = std::make_unique<Layer::ShapeRects>();
shape->emplace_back(0, 0, 10, 20);
EXPECT_CALL(delegate, OnLayerAlphaShapeChanged());
layer->SetAlphaShape(std::move(shape));
testing::Mock::VerifyAndClear(&delegate);
// Clear the alpha shape for the layer. Expect the delegate to be notified.
EXPECT_CALL(delegate, OnLayerAlphaShapeChanged());
layer->SetAlphaShape(nullptr);
testing::Mock::VerifyAndClear(&delegate);
}
TEST_P(LayerWithRealCompositorTest, CompositorAnimationObserverTest) {
std::unique_ptr<Layer> root = CreateLayer(LAYER_TEXTURED);
root->SetAnimator(LayerAnimator::CreateImplicitAnimator());
TestCompositorAnimationObserver animation_observer(GetCompositor());
EXPECT_EQ(0u, animation_observer.animation_step_count());
root->SetOpacity(0.5f);
WaitForDraw();
EXPECT_EQ(1u, animation_observer.animation_step_count());
EXPECT_FALSE(animation_observer.shutdown());
ResetCompositor();
EXPECT_TRUE(animation_observer.shutdown());
}
} // namespace ui