// Copyright 2011 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "cc/trees/layer_tree_host_common.h" #include #include "cc/animation/layer_animation_controller.h" #include "cc/base/math_util.h" #include "cc/layers/content_layer.h" #include "cc/layers/content_layer_client.h" #include "cc/layers/heads_up_display_layer_impl.h" #include "cc/layers/layer.h" #include "cc/layers/layer_client.h" #include "cc/layers/layer_impl.h" #include "cc/layers/render_surface.h" #include "cc/layers/render_surface_impl.h" #include "cc/output/copy_output_request.h" #include "cc/output/copy_output_result.h" #include "cc/test/animation_test_common.h" #include "cc/test/fake_impl_proxy.h" #include "cc/test/fake_layer_tree_host.h" #include "cc/test/fake_layer_tree_host_impl.h" #include "cc/test/geometry_test_utils.h" #include "cc/trees/layer_tree_impl.h" #include "cc/trees/proxy.h" #include "cc/trees/single_thread_proxy.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" #include "ui/gfx/quad_f.h" #include "ui/gfx/size_conversions.h" #include "ui/gfx/transform.h" namespace cc { namespace { class LayerTreeHostCommonTestBase { protected: template void SetLayerPropertiesForTestingInternal( LayerType* layer, const gfx::Transform& transform, const gfx::PointF& anchor, const gfx::PointF& position, const gfx::Size& bounds, bool flatten_transform, bool is_3d_sorted) { layer->SetTransform(transform); layer->SetAnchorPoint(anchor); layer->SetPosition(position); layer->SetBounds(bounds); layer->SetShouldFlattenTransform(flatten_transform); layer->SetIs3dSorted(is_3d_sorted); } void SetLayerPropertiesForTesting(Layer* layer, const gfx::Transform& transform, const gfx::PointF& anchor, const gfx::PointF& position, const gfx::Size& bounds, bool flatten_transform, bool is_3d_sorted) { SetLayerPropertiesForTestingInternal(layer, transform, anchor, position, bounds, flatten_transform, is_3d_sorted); } void SetLayerPropertiesForTesting(LayerImpl* layer, const gfx::Transform& transform, const gfx::PointF& anchor, const gfx::PointF& position, const gfx::Size& bounds, bool flatten_transform, bool is_3d_sorted) { SetLayerPropertiesForTestingInternal(layer, transform, anchor, position, bounds, flatten_transform, is_3d_sorted); layer->SetContentBounds(bounds); } void ExecuteCalculateDrawProperties(Layer* root_layer, float device_scale_factor, float page_scale_factor, Layer* page_scale_application_layer, bool can_use_lcd_text) { EXPECT_TRUE(page_scale_application_layer || (page_scale_factor == 1.f)); gfx::Transform identity_matrix; gfx::Size device_viewport_size = gfx::Size(root_layer->bounds().width() * device_scale_factor, root_layer->bounds().height() * device_scale_factor); render_surface_layer_list_.reset(new RenderSurfaceLayerList); // We are probably not testing what is intended if the root_layer bounds are // empty. DCHECK(!root_layer->bounds().IsEmpty()); LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root_layer, device_viewport_size, render_surface_layer_list_.get()); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = page_scale_application_layer; inputs.can_use_lcd_text = can_use_lcd_text; inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); } void ExecuteCalculateDrawProperties(LayerImpl* root_layer, float device_scale_factor, float page_scale_factor, LayerImpl* page_scale_application_layer, bool can_use_lcd_text) { gfx::Transform identity_matrix; LayerImplList dummy_render_surface_layer_list; gfx::Size device_viewport_size = gfx::Size(root_layer->bounds().width() * device_scale_factor, root_layer->bounds().height() * device_scale_factor); // We are probably not testing what is intended if the root_layer bounds are // empty. DCHECK(!root_layer->bounds().IsEmpty()); LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root_layer, device_viewport_size, &dummy_render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = page_scale_application_layer; inputs.can_use_lcd_text = can_use_lcd_text; inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); } template void ExecuteCalculateDrawProperties(LayerType* root_layer) { LayerType* page_scale_application_layer = NULL; ExecuteCalculateDrawProperties( root_layer, 1.f, 1.f, page_scale_application_layer, false); } template void ExecuteCalculateDrawProperties(LayerType* root_layer, float device_scale_factor) { LayerType* page_scale_application_layer = NULL; ExecuteCalculateDrawProperties(root_layer, device_scale_factor, 1.f, page_scale_application_layer, false); } template void ExecuteCalculateDrawProperties(LayerType* root_layer, float device_scale_factor, float page_scale_factor, LayerType* page_scale_application_layer) { ExecuteCalculateDrawProperties(root_layer, device_scale_factor, page_scale_factor, page_scale_application_layer, false); } RenderSurfaceLayerList* render_surface_layer_list() const { return render_surface_layer_list_.get(); } private: scoped_ptr render_surface_layer_list_; }; class LayerTreeHostCommonTest : public LayerTreeHostCommonTestBase, public testing::Test { }; class LayerWithForcedDrawsContent : public Layer { public: LayerWithForcedDrawsContent() : Layer() {} virtual bool DrawsContent() const OVERRIDE; private: virtual ~LayerWithForcedDrawsContent() {} }; bool LayerWithForcedDrawsContent::DrawsContent() const { return true; } class MockContentLayerClient : public ContentLayerClient { public: MockContentLayerClient() {} virtual ~MockContentLayerClient() {} virtual void PaintContents(SkCanvas* canvas, const gfx::Rect& clip, gfx::RectF* opaque) OVERRIDE {} virtual void DidChangeLayerCanUseLCDText() OVERRIDE {} virtual bool FillsBoundsCompletely() const OVERRIDE { return false; } }; scoped_refptr CreateDrawableContentLayer( ContentLayerClient* delegate) { scoped_refptr to_return = ContentLayer::Create(delegate); to_return->SetIsDrawable(true); return to_return; } #define EXPECT_CONTENTS_SCALE_EQ(expected, layer) \ do { \ EXPECT_FLOAT_EQ(expected, layer->contents_scale_x()); \ EXPECT_FLOAT_EQ(expected, layer->contents_scale_y()); \ } while (false) TEST_F(LayerTreeHostCommonTest, TransformsForNoOpLayer) { // Sanity check: For layers positioned at zero, with zero size, // and with identity transforms, then the draw transform, // screen space transform, and the hierarchy passed on to children // layers should also be identity transforms. scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = Layer::Create(); parent->AddChild(child); child->AddChild(grand_child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(), true, false); ExecuteCalculateDrawProperties(parent.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, child->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, grand_child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, grand_child->screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, TransformsForSingleLayer) { gfx::Transform identity_matrix; scoped_refptr layer = Layer::Create(); scoped_refptr root = Layer::Create(); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 2), true, false); root->AddChild(layer); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // Case 2: Setting the bounds of the layer should not affect either the draw // transform or the screenspace transform. gfx::Transform translation_to_center; translation_to_center.Translate(5.0, 6.0); SetLayerPropertiesForTesting(layer.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 12), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, layer->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, layer->screen_space_transform()); // Case 3: The anchor point by itself (without a layer transform) should have // no effect on the transforms. SetLayerPropertiesForTesting(layer.get(), identity_matrix, gfx::PointF(0.25f, 0.25f), gfx::PointF(), gfx::Size(10, 12), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, layer->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, layer->screen_space_transform()); // Case 4: A change in actual position affects both the draw transform and // screen space transform. gfx::Transform position_transform; position_transform.Translate(0.f, 1.2f); SetLayerPropertiesForTesting(layer.get(), identity_matrix, gfx::PointF(0.25f, 0.25f), gfx::PointF(0.f, 1.2f), gfx::Size(10, 12), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(position_transform, layer->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(position_transform, layer->screen_space_transform()); // Case 5: In the correct sequence of transforms, the layer transform should // pre-multiply the translation_to_center. This is easily tested by using a // scale transform, because scale and translation are not commutative. gfx::Transform layer_transform; layer_transform.Scale3d(2.0, 2.0, 1.0); SetLayerPropertiesForTesting(layer.get(), layer_transform, gfx::PointF(), gfx::PointF(), gfx::Size(10, 12), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(layer_transform, layer->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(layer_transform, layer->screen_space_transform()); // Case 6: The layer transform should occur with respect to the anchor point. gfx::Transform translation_to_anchor; translation_to_anchor.Translate(5.0, 0.0); gfx::Transform expected_result = translation_to_anchor * layer_transform * Inverse(translation_to_anchor); SetLayerPropertiesForTesting(layer.get(), layer_transform, gfx::PointF(0.5f, 0.f), gfx::PointF(), gfx::Size(10, 12), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_result, layer->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_result, layer->screen_space_transform()); // Case 7: Verify that position pre-multiplies the layer transform. The // current implementation of CalculateDrawProperties does this implicitly, but // it is still worth testing to detect accidental regressions. expected_result = position_transform * translation_to_anchor * layer_transform * Inverse(translation_to_anchor); SetLayerPropertiesForTesting(layer.get(), layer_transform, gfx::PointF(0.5f, 0.f), gfx::PointF(0.f, 1.2f), gfx::Size(10, 12), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_result, layer->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_result, layer->screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, TransformsAboutScrollOffset) { const gfx::Vector2d kScrollOffset(50, 100); const gfx::Vector2dF kScrollDelta(2.34f, 5.67f); const gfx::Vector2d kMaxScrollOffset(200, 200); const gfx::PointF kScrollLayerPosition(-kScrollOffset.x(), -kScrollOffset.y()); const float kPageScale = 0.888f; const float kDeviceScale = 1.666f; FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); gfx::Transform identity_matrix; scoped_ptr sublayer_scoped_ptr( LayerImpl::Create(host_impl.active_tree(), 1)); LayerImpl* sublayer = sublayer_scoped_ptr.get(); sublayer->SetContentsScale(kPageScale * kDeviceScale, kPageScale * kDeviceScale); SetLayerPropertiesForTesting(sublayer, identity_matrix, gfx::Point(), gfx::PointF(), gfx::Size(500, 500), true, false); scoped_ptr scroll_layer_scoped_ptr( LayerImpl::Create(host_impl.active_tree(), 2)); LayerImpl* scroll_layer = scroll_layer_scoped_ptr.get(); SetLayerPropertiesForTesting(scroll_layer, identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 20), true, false); scoped_ptr clip_layer_scoped_ptr( LayerImpl::Create(host_impl.active_tree(), 4)); LayerImpl* clip_layer = clip_layer_scoped_ptr.get(); scroll_layer->SetScrollClipLayer(clip_layer->id()); clip_layer->SetBounds( gfx::Size(scroll_layer->bounds().width() + kMaxScrollOffset.x(), scroll_layer->bounds().height() + kMaxScrollOffset.y())); scroll_layer->SetScrollClipLayer(clip_layer->id()); scroll_layer->SetScrollDelta(kScrollDelta); gfx::Transform impl_transform; scroll_layer->AddChild(sublayer_scoped_ptr.Pass()); LayerImpl* scroll_layer_raw_ptr = scroll_layer_scoped_ptr.get(); clip_layer->AddChild(scroll_layer_scoped_ptr.Pass()); scroll_layer_raw_ptr->SetScrollOffset(kScrollOffset); scoped_ptr root(LayerImpl::Create(host_impl.active_tree(), 3)); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(3, 4), true, false); root->AddChild(clip_layer_scoped_ptr.Pass()); ExecuteCalculateDrawProperties( root.get(), kDeviceScale, kPageScale, scroll_layer->parent()); gfx::Transform expected_transform = identity_matrix; gfx::PointF sub_layer_screen_position = kScrollLayerPosition - kScrollDelta; sub_layer_screen_position.Scale(kPageScale * kDeviceScale); expected_transform.Translate(MathUtil::Round(sub_layer_screen_position.x()), MathUtil::Round(sub_layer_screen_position.y())); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_transform, sublayer->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_transform, sublayer->screen_space_transform()); gfx::Transform arbitrary_translate; const float kTranslateX = 10.6f; const float kTranslateY = 20.6f; arbitrary_translate.Translate(kTranslateX, kTranslateY); SetLayerPropertiesForTesting(scroll_layer, arbitrary_translate, gfx::PointF(), gfx::PointF(), gfx::Size(10, 20), true, false); ExecuteCalculateDrawProperties( root.get(), kDeviceScale, kPageScale, scroll_layer->parent()); expected_transform.MakeIdentity(); expected_transform.Translate( MathUtil::Round(kTranslateX * kPageScale * kDeviceScale + sub_layer_screen_position.x()), MathUtil::Round(kTranslateY * kPageScale * kDeviceScale + sub_layer_screen_position.y())); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_transform, sublayer->draw_transform()); } TEST_F(LayerTreeHostCommonTest, TransformsForSimpleHierarchy) { gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = Layer::Create(); root->AddChild(parent); parent->AddChild(child); child->AddChild(grand_child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // One-time setup of root layer SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 2), true, false); // Case 1: parent's anchor point should not affect child or grand_child. SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(0.25f, 0.25f), gfx::PointF(), gfx::Size(10, 12), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(16, 18), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(76, 78), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, child->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, grand_child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, grand_child->screen_space_transform()); // Case 2: parent's position affects child and grand_child. gfx::Transform parent_position_transform; parent_position_transform.Translate(0.f, 1.2f); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(0.25f, 0.25f), gfx::PointF(0.f, 1.2f), gfx::Size(10, 12), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(16, 18), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(76, 78), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_position_transform, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_position_transform, child->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_position_transform, grand_child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_position_transform, grand_child->screen_space_transform()); // Case 3: parent's local transform affects child and grandchild gfx::Transform parent_layer_transform; parent_layer_transform.Scale3d(2.0, 2.0, 1.0); gfx::Transform parent_translation_to_anchor; parent_translation_to_anchor.Translate(2.5, 3.0); gfx::Transform parent_composite_transform = parent_translation_to_anchor * parent_layer_transform * Inverse(parent_translation_to_anchor); SetLayerPropertiesForTesting(parent.get(), parent_layer_transform, gfx::PointF(0.25f, 0.25f), gfx::PointF(), gfx::Size(10, 12), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(16, 18), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(76, 78), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_composite_transform, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_composite_transform, child->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_composite_transform, grand_child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_composite_transform, grand_child->screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, TransformsForSingleRenderSurface) { scoped_refptr root = Layer::Create(); scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(parent); parent->AddChild(child); child->AddChild(grand_child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // One-time setup of root layer gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 2), true, false); // Child is set up so that a new render surface should be created. child->SetOpacity(0.5f); child->SetForceRenderSurface(true); gfx::Transform parent_layer_transform; parent_layer_transform.Scale3d(1.f, 0.9f, 1.f); gfx::Transform parent_translation_to_anchor; parent_translation_to_anchor.Translate(25.0, 30.0); gfx::Transform parent_composite_transform = parent_translation_to_anchor * parent_layer_transform * Inverse(parent_translation_to_anchor); gfx::Vector2dF parent_composite_scale = MathUtil::ComputeTransform2dScaleComponents(parent_composite_transform, 1.f); gfx::Transform surface_sublayer_transform; surface_sublayer_transform.Scale(parent_composite_scale.x(), parent_composite_scale.y()); gfx::Transform surface_sublayer_composite_transform = parent_composite_transform * Inverse(surface_sublayer_transform); // Child's render surface should not exist yet. ASSERT_FALSE(child->render_surface()); SetLayerPropertiesForTesting(parent.get(), parent_layer_transform, gfx::PointF(0.25f, 0.25f), gfx::PointF(), gfx::Size(100, 120), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(16, 18), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(8, 10), true, false); ExecuteCalculateDrawProperties(root.get()); // Render surface should have been created now. ASSERT_TRUE(child->render_surface()); ASSERT_EQ(child, child->render_target()); // The child layer's draw transform should refer to its new render surface. // The screen-space transform, however, should still refer to the root. EXPECT_TRANSFORMATION_MATRIX_EQ(surface_sublayer_transform, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(parent_composite_transform, child->screen_space_transform()); // Because the grand_child is the only drawable content, the child's render // surface will tighten its bounds to the grand_child. The scale at which the // surface's subtree is drawn must be removed from the composite transform. EXPECT_TRANSFORMATION_MATRIX_EQ( surface_sublayer_composite_transform, child->render_target()->render_surface()->draw_transform()); // The screen space is the same as the target since the child surface draws // into the root. EXPECT_TRANSFORMATION_MATRIX_EQ( surface_sublayer_composite_transform, child->render_target()->render_surface()->screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, TransformsForReplica) { scoped_refptr root = Layer::Create(); scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr child_replica = Layer::Create(); scoped_refptr grand_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(parent); parent->AddChild(child); child->AddChild(grand_child); child->SetReplicaLayer(child_replica.get()); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // One-time setup of root layer gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 2), true, false); // Child is set up so that a new render surface should be created. child->SetOpacity(0.5f); gfx::Transform parent_layer_transform; parent_layer_transform.Scale3d(2.0, 2.0, 1.0); gfx::Transform parent_translation_to_anchor; parent_translation_to_anchor.Translate(2.5, 3.0); gfx::Transform parent_composite_transform = parent_translation_to_anchor * parent_layer_transform * Inverse(parent_translation_to_anchor); gfx::Transform replica_layer_transform; replica_layer_transform.Scale3d(3.0, 3.0, 1.0); gfx::Vector2dF parent_composite_scale = MathUtil::ComputeTransform2dScaleComponents(parent_composite_transform, 1.f); gfx::Transform surface_sublayer_transform; surface_sublayer_transform.Scale(parent_composite_scale.x(), parent_composite_scale.y()); gfx::Transform replica_composite_transform = parent_composite_transform * replica_layer_transform * Inverse(surface_sublayer_transform); // Child's render surface should not exist yet. ASSERT_FALSE(child->render_surface()); SetLayerPropertiesForTesting(parent.get(), parent_layer_transform, gfx::PointF(0.25f, 0.25f), gfx::PointF(), gfx::Size(10, 12), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(16, 18), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(-0.5f, -0.5f), gfx::Size(1, 1), true, false); SetLayerPropertiesForTesting(child_replica.get(), replica_layer_transform, gfx::PointF(), gfx::PointF(), gfx::Size(), true, false); ExecuteCalculateDrawProperties(root.get()); // Render surface should have been created now. ASSERT_TRUE(child->render_surface()); ASSERT_EQ(child, child->render_target()); EXPECT_TRANSFORMATION_MATRIX_EQ( replica_composite_transform, child->render_target()->render_surface()->replica_draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(replica_composite_transform, child->render_target() ->render_surface() ->replica_screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, TransformsForRenderSurfaceHierarchy) { // This test creates a more complex tree and verifies it all at once. This // covers the following cases: // - layers that are described w.r.t. a render surface: should have draw // transforms described w.r.t. that surface // - A render surface described w.r.t. an ancestor render surface: should // have a draw transform described w.r.t. that ancestor surface // - Replicas of a render surface are described w.r.t. the replica's // transform around its anchor, along with the surface itself. // - Sanity check on recursion: verify transforms of layers described w.r.t. // a render surface that is described w.r.t. an ancestor render surface. // - verifying that each layer has a reference to the correct render surface // and render target values. scoped_refptr root = Layer::Create(); scoped_refptr parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr render_surface2 = Layer::Create(); scoped_refptr child_of_root = Layer::Create(); scoped_refptr child_of_rs1 = Layer::Create(); scoped_refptr child_of_rs2 = Layer::Create(); scoped_refptr replica_of_rs1 = Layer::Create(); scoped_refptr replica_of_rs2 = Layer::Create(); scoped_refptr grand_child_of_root = Layer::Create(); scoped_refptr grand_child_of_rs1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr grand_child_of_rs2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(parent); parent->AddChild(render_surface1); parent->AddChild(child_of_root); render_surface1->AddChild(child_of_rs1); render_surface1->AddChild(render_surface2); render_surface2->AddChild(child_of_rs2); child_of_root->AddChild(grand_child_of_root); child_of_rs1->AddChild(grand_child_of_rs1); child_of_rs2->AddChild(grand_child_of_rs2); render_surface1->SetReplicaLayer(replica_of_rs1.get()); render_surface2->SetReplicaLayer(replica_of_rs2.get()); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // In combination with descendant draws content, opacity != 1 forces the layer // to have a new render surface. render_surface1->SetOpacity(0.5f); render_surface2->SetOpacity(0.33f); // One-time setup of root layer gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 2), true, false); // All layers in the tree are initialized with an anchor at .25 and a size of // (10,10). matrix "A" is the composite layer transform used in all layers, // Matrix "R" is the composite replica transform used in all replica layers. gfx::Transform translation_to_anchor; translation_to_anchor.Translate(2.5, 0.0); gfx::Transform layer_transform; layer_transform.Translate(1.0, 1.0); gfx::Transform replica_layer_transform; replica_layer_transform.Scale3d(-2.0, 5.0, 1.0); gfx::Transform A = translation_to_anchor * layer_transform * Inverse(translation_to_anchor); gfx::Transform R = A * translation_to_anchor * replica_layer_transform * Inverse(translation_to_anchor); gfx::Vector2dF surface1_parent_transform_scale = MathUtil::ComputeTransform2dScaleComponents(A, 1.f); gfx::Transform surface1_sublayer_transform; surface1_sublayer_transform.Scale(surface1_parent_transform_scale.x(), surface1_parent_transform_scale.y()); // SS1 = transform given to the subtree of render_surface1 gfx::Transform SS1 = surface1_sublayer_transform; // S1 = transform to move from render_surface1 pixels to the layer space of // the owning layer gfx::Transform S1 = Inverse(surface1_sublayer_transform); gfx::Vector2dF surface2_parent_transform_scale = MathUtil::ComputeTransform2dScaleComponents(SS1 * A, 1.f); gfx::Transform surface2_sublayer_transform; surface2_sublayer_transform.Scale(surface2_parent_transform_scale.x(), surface2_parent_transform_scale.y()); // SS2 = transform given to the subtree of render_surface2 gfx::Transform SS2 = surface2_sublayer_transform; // S2 = transform to move from render_surface2 pixels to the layer space of // the owning layer gfx::Transform S2 = Inverse(surface2_sublayer_transform); SetLayerPropertiesForTesting(parent.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(render_surface1.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(render_surface2.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child_of_root.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child_of_rs1.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child_of_rs2.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child_of_root.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child_of_rs1.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child_of_rs2.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(replica_of_rs1.get(), replica_layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(), true, false); SetLayerPropertiesForTesting(replica_of_rs2.get(), replica_layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(), gfx::Size(), true, false); ExecuteCalculateDrawProperties(root.get()); // Only layers that are associated with render surfaces should have an actual // RenderSurface() value. ASSERT_TRUE(root->render_surface()); ASSERT_FALSE(child_of_root->render_surface()); ASSERT_FALSE(grand_child_of_root->render_surface()); ASSERT_TRUE(render_surface1->render_surface()); ASSERT_FALSE(child_of_rs1->render_surface()); ASSERT_FALSE(grand_child_of_rs1->render_surface()); ASSERT_TRUE(render_surface2->render_surface()); ASSERT_FALSE(child_of_rs2->render_surface()); ASSERT_FALSE(grand_child_of_rs2->render_surface()); // Verify all render target accessors EXPECT_EQ(root, parent->render_target()); EXPECT_EQ(root, child_of_root->render_target()); EXPECT_EQ(root, grand_child_of_root->render_target()); EXPECT_EQ(render_surface1, render_surface1->render_target()); EXPECT_EQ(render_surface1, child_of_rs1->render_target()); EXPECT_EQ(render_surface1, grand_child_of_rs1->render_target()); EXPECT_EQ(render_surface2, render_surface2->render_target()); EXPECT_EQ(render_surface2, child_of_rs2->render_target()); EXPECT_EQ(render_surface2, grand_child_of_rs2->render_target()); // Verify layer draw transforms note that draw transforms are described with // respect to the nearest ancestor render surface but screen space transforms // are described with respect to the root. EXPECT_TRANSFORMATION_MATRIX_EQ(A, parent->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A, child_of_root->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A * A, grand_child_of_root->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(SS1, render_surface1->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(SS1 * A, child_of_rs1->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(SS1 * A * A, grand_child_of_rs1->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(SS2, render_surface2->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(SS2 * A, child_of_rs2->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(SS2 * A * A, grand_child_of_rs2->draw_transform()); // Verify layer screen-space transforms // EXPECT_TRANSFORMATION_MATRIX_EQ(A, parent->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A, child_of_root->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( A * A * A, grand_child_of_root->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A, render_surface1->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A * A, child_of_rs1->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A * A * A, grand_child_of_rs1->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A * A, render_surface2->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A * A * A, child_of_rs2->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(A * A * A * A * A, grand_child_of_rs2->screen_space_transform()); // Verify render surface transforms. // // Draw transform of render surface 1 is described with respect to root. EXPECT_TRANSFORMATION_MATRIX_EQ( A * A * S1, render_surface1->render_surface()->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( A * R * S1, render_surface1->render_surface()->replica_draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( A * A * S1, render_surface1->render_surface()->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( A * R * S1, render_surface1->render_surface()->replica_screen_space_transform()); // Draw transform of render surface 2 is described with respect to render // surface 1. EXPECT_TRANSFORMATION_MATRIX_EQ( SS1 * A * S2, render_surface2->render_surface()->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( SS1 * R * S2, render_surface2->render_surface()->replica_draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( A * A * A * S2, render_surface2->render_surface()->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( A * A * R * S2, render_surface2->render_surface()->replica_screen_space_transform()); // Sanity check. If these fail there is probably a bug in the test itself. It // is expected that we correctly set up transforms so that the y-component of // the screen-space transform encodes the "depth" of the layer in the tree. EXPECT_FLOAT_EQ(1.0, parent->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(2.0, child_of_root->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ( 3.0, grand_child_of_root->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(2.0, render_surface1->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(3.0, child_of_rs1->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ( 4.0, grand_child_of_rs1->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(3.0, render_surface2->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(4.0, child_of_rs2->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ( 5.0, grand_child_of_rs2->screen_space_transform().matrix().get(1, 3)); } TEST_F(LayerTreeHostCommonTest, TransformsForFlatteningLayer) { // For layers that flatten their subtree, there should be an orthographic // projection (for x and y values) in the middle of the transform sequence. // Note that the way the code is currently implemented, it is not expected to // use a canonical orthographic projection. scoped_refptr root = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); gfx::Transform rotation_about_y_axis; rotation_about_y_axis.RotateAboutYAxis(30.0); const gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), rotation_about_y_axis, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child.get(), rotation_about_y_axis, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); root->AddChild(child); child->AddChild(grand_child); child->SetForceRenderSurface(true); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // No layers in this test should preserve 3d. ASSERT_TRUE(root->should_flatten_transform()); ASSERT_TRUE(child->should_flatten_transform()); ASSERT_TRUE(grand_child->should_flatten_transform()); gfx::Transform expected_child_draw_transform = rotation_about_y_axis; gfx::Transform expected_child_screen_space_transform = rotation_about_y_axis; gfx::Transform expected_grand_child_draw_transform = rotation_about_y_axis; // draws onto child's render surface gfx::Transform flattened_rotation_about_y = rotation_about_y_axis; flattened_rotation_about_y.FlattenTo2d(); gfx::Transform expected_grand_child_screen_space_transform = flattened_rotation_about_y * rotation_about_y_axis; ExecuteCalculateDrawProperties(root.get()); // The child's draw transform should have been taken by its surface. ASSERT_TRUE(child->render_surface()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_draw_transform, child->render_surface()->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_child_screen_space_transform, child->render_surface()->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_screen_space_transform, child->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_grand_child_draw_transform, grand_child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_grand_child_screen_space_transform, grand_child->screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, TransformsForDegenerateIntermediateLayer) { // A layer that is empty in one axis, but not the other, was accidentally // skipping a necessary translation. Without that translation, the coordinate // space of the layer's draw transform is incorrect. // // Normally this isn't a problem, because the layer wouldn't be drawn anyway, // but if that layer becomes a render surface, then its draw transform is // implicitly inherited by the rest of the subtree, which then is positioned // incorrectly as a result. scoped_refptr root = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); // The child height is zero, but has non-zero width that should be accounted // for while computing draw transforms. const gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 0), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); root->AddChild(child); child->AddChild(grand_child); child->SetForceRenderSurface(true); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); ASSERT_TRUE(child->render_surface()); // This is the real test, the rest are sanity checks. EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, child->render_surface()->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_matrix, grand_child->draw_transform()); } TEST_F(LayerTreeHostCommonTest, TransformAboveRootLayer) { // Transformations applied at the root of the tree should be forwarded // to child layers instead of applied to the root RenderSurface. const gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); scoped_refptr child = Layer::Create(); child->SetScrollClipLayerId(root->id()); root->AddChild(child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); gfx::Transform translate; translate.Translate(50, 50); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), translate, &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_EQ(translate, root->draw_properties().target_space_transform); EXPECT_EQ(translate, child->draw_properties().target_space_transform); EXPECT_EQ(identity_matrix, root->render_surface()->draw_transform()); } gfx::Transform scale; scale.Scale(2, 2); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), scale, &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_EQ(scale, root->draw_properties().target_space_transform); EXPECT_EQ(scale, child->draw_properties().target_space_transform); EXPECT_EQ(identity_matrix, root->render_surface()->draw_transform()); } gfx::Transform rotate; rotate.Rotate(2); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), rotate, &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_EQ(rotate, root->draw_properties().target_space_transform); EXPECT_EQ(rotate, child->draw_properties().target_space_transform); EXPECT_EQ(identity_matrix, root->render_surface()->draw_transform()); } gfx::Transform composite; composite.ConcatTransform(translate); composite.ConcatTransform(scale); composite.ConcatTransform(rotate); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), composite, &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_EQ(composite, root->draw_properties().target_space_transform); EXPECT_EQ(composite, child->draw_properties().target_space_transform); EXPECT_EQ(identity_matrix, root->render_surface()->draw_transform()); } // Verify it composes correctly with device scale. float device_scale_factor = 1.5f; { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), translate, &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); gfx::Transform device_scaled_translate = translate; device_scaled_translate.Scale(device_scale_factor, device_scale_factor); EXPECT_EQ(device_scaled_translate, root->draw_properties().target_space_transform); EXPECT_EQ(device_scaled_translate, child->draw_properties().target_space_transform); EXPECT_EQ(identity_matrix, root->render_surface()->draw_transform()); } // Verify it composes correctly with page scale. float page_scale_factor = 2.f; { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), translate, &render_surface_layer_list); inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); gfx::Transform page_scaled_translate = translate; page_scaled_translate.Scale(page_scale_factor, page_scale_factor); EXPECT_EQ(translate, root->draw_properties().target_space_transform); EXPECT_EQ(page_scaled_translate, child->draw_properties().target_space_transform); EXPECT_EQ(identity_matrix, root->render_surface()->draw_transform()); } // Verify that it composes correctly with transforms directly on root layer. root->SetTransform(composite); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), composite, &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); gfx::Transform compositeSquared = composite; compositeSquared.ConcatTransform(composite); EXPECT_TRANSFORMATION_MATRIX_EQ( compositeSquared, root->draw_properties().target_space_transform); EXPECT_TRANSFORMATION_MATRIX_EQ( compositeSquared, child->draw_properties().target_space_transform); EXPECT_EQ(identity_matrix, root->render_surface()->draw_transform()); } } TEST_F(LayerTreeHostCommonTest, RenderSurfaceListForRenderSurfaceWithClippedLayer) { scoped_refptr parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); const gfx::Transform identity_matrix; SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(30.f, 30.f), gfx::Size(10, 10), true, false); parent->AddChild(render_surface1); parent->SetMasksToBounds(true); render_surface1->AddChild(child); render_surface1->SetForceRenderSurface(true); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), gfx::Transform(), &render_surface_layer_list); LayerTreeHostCommon::CalculateDrawProperties(&inputs); // The child layer's content is entirely outside the parent's clip rect, so // the intermediate render surface should not be listed here, even if it was // forced to be created. Render surfaces without children or visible content // are unexpected at draw time (e.g. we might try to create a content texture // of size 0). ASSERT_TRUE(parent->render_surface()); ASSERT_FALSE(render_surface1->render_surface()); EXPECT_EQ(1U, render_surface_layer_list.size()); } TEST_F(LayerTreeHostCommonTest, RenderSurfaceListForTransparentChild) { scoped_refptr parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); const gfx::Transform identity_matrix; SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); parent->AddChild(render_surface1); render_surface1->AddChild(child); render_surface1->SetForceRenderSurface(true); render_surface1->SetOpacity(0.f); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Since the layer is transparent, render_surface1->render_surface() should // not have gotten added anywhere. Also, the drawable content rect should not // have been extended by the children. ASSERT_TRUE(parent->render_surface()); EXPECT_EQ(0U, parent->render_surface()->layer_list().size()); EXPECT_EQ(1U, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(gfx::Rect(), parent->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, ForceRenderSurface) { scoped_refptr parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr child = make_scoped_refptr(new LayerWithForcedDrawsContent()); render_surface1->SetForceRenderSurface(true); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); const gfx::Transform identity_matrix; SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); parent->AddChild(render_surface1); render_surface1->AddChild(child); // Sanity check before the actual test EXPECT_FALSE(parent->render_surface()); EXPECT_FALSE(render_surface1->render_surface()); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // The root layer always creates a render surface EXPECT_TRUE(parent->render_surface()); EXPECT_TRUE(render_surface1->render_surface()); EXPECT_EQ(2U, render_surface_layer_list.size()); } { RenderSurfaceLayerList render_surface_layer_list; render_surface1->SetForceRenderSurface(false); LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_TRUE(parent->render_surface()); EXPECT_FALSE(render_surface1->render_surface()); EXPECT_EQ(1U, render_surface_layer_list.size()); } } TEST_F(LayerTreeHostCommonTest, ClipRectCullsRenderSurfaces) { // The entire subtree of layers that are outside the clip rect should be // culled away, and should not affect the render_surface_layer_list. // // The test tree is set up as follows: // - all layers except the leaf_nodes are forced to be a new render surface // that have something to draw. // - parent is a large container layer. // - child has masksToBounds=true to cause clipping. // - grand_child is positioned outside of the child's bounds // - great_grand_child is also kept outside child's bounds. // // In this configuration, grand_child and great_grand_child are completely // outside the clip rect, and they should never get scheduled on the list of // render surfaces. // const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = Layer::Create(); scoped_refptr great_grand_child = Layer::Create(); scoped_refptr leaf_node1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr leaf_node2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(child); child->AddChild(grand_child); grand_child->AddChild(great_grand_child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); // leaf_node1 ensures that parent and child are kept on the // render_surface_layer_list, even though grand_child and great_grand_child // should be clipped. child->AddChild(leaf_node1); great_grand_child->AddChild(leaf_node2); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(500, 500), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(45.f, 45.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(great_grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(leaf_node1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(500, 500), true, false); SetLayerPropertiesForTesting(leaf_node2.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); child->SetMasksToBounds(true); child->SetOpacity(0.4f); child->SetForceRenderSurface(true); grand_child->SetOpacity(0.5f); great_grand_child->SetOpacity(0.4f); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); ASSERT_EQ(2U, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(child->id(), render_surface_layer_list.at(1)->id()); } TEST_F(LayerTreeHostCommonTest, ClipRectCullsSurfaceWithoutVisibleContent) { // When a render surface has a clip rect, it is used to clip the content rect // of the surface. When the render surface is animating its transforms, then // the content rect's position in the clip rect is not defined on the main // thread, and its content rect should not be clipped. // The test tree is set up as follows: // - parent is a container layer that masksToBounds=true to cause clipping. // - child is a render surface, which has a clip rect set to the bounds of // the parent. // - grand_child is a render surface, and the only visible content in child. // It is positioned outside of the clip rect from parent. // In this configuration, grand_child should be outside the clipped // content rect of the child, making grand_child not appear in the // render_surface_layer_list. However, when we place an animation on the // child, this clipping should be avoided and we should keep the grand_child // in the render_surface_layer_list. const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = Layer::Create(); scoped_refptr leaf_node = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(child); child->AddChild(grand_child); grand_child->AddChild(leaf_node); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(200.f, 200.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(leaf_node.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); parent->SetMasksToBounds(true); child->SetOpacity(0.4f); child->SetForceRenderSurface(true); grand_child->SetOpacity(0.4f); grand_child->SetForceRenderSurface(true); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Without an animation, we should cull child and grand_child from the // render_surface_layer_list. ASSERT_EQ(1U, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); } // Now put an animating transform on child. AddAnimatedTransformToController( child->layer_animation_controller(), 10.0, 30, 0); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // With an animating transform, we should keep child and grand_child in the // render_surface_layer_list. ASSERT_EQ(3U, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(child->id(), render_surface_layer_list.at(1)->id()); EXPECT_EQ(grand_child->id(), render_surface_layer_list.at(2)->id()); } } TEST_F(LayerTreeHostCommonTest, IsClippedIsSetCorrectly) { // Layer's IsClipped() property is set to true when: // - the layer clips its subtree, e.g. masks to bounds, // - the layer is clipped by an ancestor that contributes to the same // render target, // - a surface is clipped by an ancestor that contributes to the same // render target. // // In particular, for a layer that owns a render surface: // - the render surface inherits any clip from ancestors, and does NOT // pass that clipped status to the layer itself. // - but if the layer itself masks to bounds, it is considered clipped // and propagates the clip to the subtree. const gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); scoped_refptr parent = Layer::Create(); scoped_refptr child1 = Layer::Create(); scoped_refptr child2 = Layer::Create(); scoped_refptr grand_child = Layer::Create(); scoped_refptr leaf_node1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr leaf_node2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(parent); parent->AddChild(child1); parent->AddChild(child2); child1->AddChild(grand_child); child2->AddChild(leaf_node2); grand_child->AddChild(leaf_node1); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); child2->SetForceRenderSurface(true); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(leaf_node1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(leaf_node2.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); // Case 1: nothing is clipped except the root render surface. { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); ASSERT_TRUE(root->render_surface()); ASSERT_TRUE(child2->render_surface()); EXPECT_FALSE(root->is_clipped()); EXPECT_TRUE(root->render_surface()->is_clipped()); EXPECT_FALSE(parent->is_clipped()); EXPECT_FALSE(child1->is_clipped()); EXPECT_FALSE(child2->is_clipped()); EXPECT_FALSE(child2->render_surface()->is_clipped()); EXPECT_FALSE(grand_child->is_clipped()); EXPECT_FALSE(leaf_node1->is_clipped()); EXPECT_FALSE(leaf_node2->is_clipped()); } // Case 2: parent masksToBounds, so the parent, child1, and child2's // surface are clipped. But layers that contribute to child2's surface are // not clipped explicitly because child2's surface already accounts for // that clip. { RenderSurfaceLayerList render_surface_layer_list; parent->SetMasksToBounds(true); LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); ASSERT_TRUE(root->render_surface()); ASSERT_TRUE(child2->render_surface()); EXPECT_FALSE(root->is_clipped()); EXPECT_TRUE(root->render_surface()->is_clipped()); EXPECT_TRUE(parent->is_clipped()); EXPECT_TRUE(child1->is_clipped()); EXPECT_FALSE(child2->is_clipped()); EXPECT_TRUE(child2->render_surface()->is_clipped()); EXPECT_TRUE(grand_child->is_clipped()); EXPECT_TRUE(leaf_node1->is_clipped()); EXPECT_FALSE(leaf_node2->is_clipped()); } // Case 3: child2 masksToBounds. The layer and subtree are clipped, and // child2's render surface is not clipped. { RenderSurfaceLayerList render_surface_layer_list; parent->SetMasksToBounds(false); child2->SetMasksToBounds(true); LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); ASSERT_TRUE(root->render_surface()); ASSERT_TRUE(child2->render_surface()); EXPECT_FALSE(root->is_clipped()); EXPECT_TRUE(root->render_surface()->is_clipped()); EXPECT_FALSE(parent->is_clipped()); EXPECT_FALSE(child1->is_clipped()); EXPECT_TRUE(child2->is_clipped()); EXPECT_FALSE(child2->render_surface()->is_clipped()); EXPECT_FALSE(grand_child->is_clipped()); EXPECT_FALSE(leaf_node1->is_clipped()); EXPECT_TRUE(leaf_node2->is_clipped()); } } TEST_F(LayerTreeHostCommonTest, DrawableContentRectForLayers) { // Verify that layers get the appropriate DrawableContentRect when their // parent masksToBounds is true. // // grand_child1 - completely inside the region; DrawableContentRect should // be the layer rect expressed in target space. // grand_child2 - partially clipped but NOT masksToBounds; the clip rect // will be the intersection of layer bounds and the mask region. // grand_child3 - partially clipped and masksToBounds; the // DrawableContentRect will still be the intersection of layer bounds and // the mask region. // grand_child4 - outside parent's clip rect; the DrawableContentRect should // be empty. // const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child1 = Layer::Create(); scoped_refptr grand_child2 = Layer::Create(); scoped_refptr grand_child3 = Layer::Create(); scoped_refptr grand_child4 = Layer::Create(); parent->AddChild(child); child->AddChild(grand_child1); child->AddChild(grand_child2); child->AddChild(grand_child3); child->AddChild(grand_child4); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(500, 500), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); SetLayerPropertiesForTesting(grand_child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(15.f, 15.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(15.f, 15.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child4.get(), identity_matrix, gfx::PointF(), gfx::PointF(45.f, 45.f), gfx::Size(10, 10), true, false); child->SetMasksToBounds(true); grand_child3->SetMasksToBounds(true); // Force everyone to be a render surface. child->SetOpacity(0.4f); grand_child1->SetOpacity(0.5f); grand_child2->SetOpacity(0.5f); grand_child3->SetOpacity(0.5f); grand_child4->SetOpacity(0.5f); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_RECT_EQ(gfx::Rect(5, 5, 10, 10), grand_child1->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(15, 15, 5, 5), grand_child3->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(15, 15, 5, 5), grand_child3->drawable_content_rect()); EXPECT_TRUE(grand_child4->drawable_content_rect().IsEmpty()); } TEST_F(LayerTreeHostCommonTest, ClipRectIsPropagatedCorrectlyToSurfaces) { // Verify that render surfaces (and their layers) get the appropriate // clip rects when their parent masksToBounds is true. // // Layers that own render surfaces (at least for now) do not inherit any // clipping; instead the surface will enforce the clip for the entire subtree. // They may still have a clip rect of their own layer bounds, however, if // masksToBounds was true. const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child1 = Layer::Create(); scoped_refptr grand_child2 = Layer::Create(); scoped_refptr grand_child3 = Layer::Create(); scoped_refptr grand_child4 = Layer::Create(); scoped_refptr leaf_node1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr leaf_node2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr leaf_node3 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr leaf_node4 = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(child); child->AddChild(grand_child1); child->AddChild(grand_child2); child->AddChild(grand_child3); child->AddChild(grand_child4); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); // the leaf nodes ensure that these grand_children become render surfaces for // this test. grand_child1->AddChild(leaf_node1); grand_child2->AddChild(leaf_node2); grand_child3->AddChild(leaf_node3); grand_child4->AddChild(leaf_node4); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(500, 500), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); SetLayerPropertiesForTesting(grand_child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(15.f, 15.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(15.f, 15.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child4.get(), identity_matrix, gfx::PointF(), gfx::PointF(45.f, 45.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(leaf_node1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(leaf_node2.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(leaf_node3.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(leaf_node4.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); child->SetMasksToBounds(true); grand_child3->SetMasksToBounds(true); grand_child4->SetMasksToBounds(true); // Force everyone to be a render surface. child->SetOpacity(0.4f); child->SetForceRenderSurface(true); grand_child1->SetOpacity(0.5f); grand_child1->SetForceRenderSurface(true); grand_child2->SetOpacity(0.5f); grand_child2->SetForceRenderSurface(true); grand_child3->SetOpacity(0.5f); grand_child3->SetForceRenderSurface(true); grand_child4->SetOpacity(0.5f); grand_child4->SetForceRenderSurface(true); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); ASSERT_TRUE(grand_child1->render_surface()); ASSERT_TRUE(grand_child2->render_surface()); ASSERT_TRUE(grand_child3->render_surface()); // Because grand_child4 is entirely clipped, it is expected to not have a // render surface. EXPECT_FALSE(grand_child4->render_surface()); // Surfaces are clipped by their parent, but un-affected by the owning layer's // masksToBounds. EXPECT_RECT_EQ(gfx::Rect(0, 0, 20, 20), grand_child1->render_surface()->clip_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 20, 20), grand_child2->render_surface()->clip_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 20, 20), grand_child3->render_surface()->clip_rect()); } TEST_F(LayerTreeHostCommonTest, AnimationsForRenderSurfaceHierarchy) { scoped_refptr parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr render_surface2 = Layer::Create(); scoped_refptr child_of_root = Layer::Create(); scoped_refptr child_of_rs1 = Layer::Create(); scoped_refptr child_of_rs2 = Layer::Create(); scoped_refptr grand_child_of_root = Layer::Create(); scoped_refptr grand_child_of_rs1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr grand_child_of_rs2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(render_surface1); parent->AddChild(child_of_root); render_surface1->AddChild(child_of_rs1); render_surface1->AddChild(render_surface2); render_surface2->AddChild(child_of_rs2); child_of_root->AddChild(grand_child_of_root); child_of_rs1->AddChild(grand_child_of_rs1); child_of_rs2->AddChild(grand_child_of_rs2); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); // Make our render surfaces. render_surface1->SetForceRenderSurface(true); render_surface2->SetForceRenderSurface(true); gfx::Transform layer_transform; layer_transform.Translate(1.0, 1.0); SetLayerPropertiesForTesting(parent.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(render_surface1.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(render_surface2.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child_of_root.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child_of_rs1.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(child_of_rs2.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child_of_root.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child_of_rs1.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child_of_rs2.get(), layer_transform, gfx::PointF(0.25f, 0.f), gfx::PointF(2.5f, 0.f), gfx::Size(10, 10), true, false); // Put an animated opacity on the render surface. AddOpacityTransitionToController( render_surface1->layer_animation_controller(), 10.0, 1.f, 0.f, false); // Also put an animated opacity on a layer without descendants. AddOpacityTransitionToController( grand_child_of_root->layer_animation_controller(), 10.0, 1.f, 0.f, false); // Put a transform animation on the render surface. AddAnimatedTransformToController( render_surface2->layer_animation_controller(), 10.0, 30, 0); // Also put transform animations on grand_child_of_root, and // grand_child_of_rs2 AddAnimatedTransformToController( grand_child_of_root->layer_animation_controller(), 10.0, 30, 0); AddAnimatedTransformToController( grand_child_of_rs2->layer_animation_controller(), 10.0, 30, 0); ExecuteCalculateDrawProperties(parent.get()); // Only layers that are associated with render surfaces should have an actual // RenderSurface() value. ASSERT_TRUE(parent->render_surface()); ASSERT_FALSE(child_of_root->render_surface()); ASSERT_FALSE(grand_child_of_root->render_surface()); ASSERT_TRUE(render_surface1->render_surface()); ASSERT_FALSE(child_of_rs1->render_surface()); ASSERT_FALSE(grand_child_of_rs1->render_surface()); ASSERT_TRUE(render_surface2->render_surface()); ASSERT_FALSE(child_of_rs2->render_surface()); ASSERT_FALSE(grand_child_of_rs2->render_surface()); // Verify all render target accessors EXPECT_EQ(parent, parent->render_target()); EXPECT_EQ(parent, child_of_root->render_target()); EXPECT_EQ(parent, grand_child_of_root->render_target()); EXPECT_EQ(render_surface1, render_surface1->render_target()); EXPECT_EQ(render_surface1, child_of_rs1->render_target()); EXPECT_EQ(render_surface1, grand_child_of_rs1->render_target()); EXPECT_EQ(render_surface2, render_surface2->render_target()); EXPECT_EQ(render_surface2, child_of_rs2->render_target()); EXPECT_EQ(render_surface2, grand_child_of_rs2->render_target()); // Verify draw_opacity_is_animating values EXPECT_FALSE(parent->draw_opacity_is_animating()); EXPECT_FALSE(child_of_root->draw_opacity_is_animating()); EXPECT_TRUE(grand_child_of_root->draw_opacity_is_animating()); EXPECT_FALSE(render_surface1->draw_opacity_is_animating()); EXPECT_TRUE(render_surface1->render_surface()->draw_opacity_is_animating()); EXPECT_FALSE(child_of_rs1->draw_opacity_is_animating()); EXPECT_FALSE(grand_child_of_rs1->draw_opacity_is_animating()); EXPECT_FALSE(render_surface2->draw_opacity_is_animating()); EXPECT_FALSE(render_surface2->render_surface()->draw_opacity_is_animating()); EXPECT_FALSE(child_of_rs2->draw_opacity_is_animating()); EXPECT_FALSE(grand_child_of_rs2->draw_opacity_is_animating()); // Verify draw_transform_is_animating values EXPECT_FALSE(parent->draw_transform_is_animating()); EXPECT_FALSE(child_of_root->draw_transform_is_animating()); EXPECT_TRUE(grand_child_of_root->draw_transform_is_animating()); EXPECT_FALSE(render_surface1->draw_transform_is_animating()); EXPECT_FALSE(render_surface1->render_surface() ->target_surface_transforms_are_animating()); EXPECT_FALSE(child_of_rs1->draw_transform_is_animating()); EXPECT_FALSE(grand_child_of_rs1->draw_transform_is_animating()); EXPECT_FALSE(render_surface2->draw_transform_is_animating()); EXPECT_TRUE(render_surface2->render_surface() ->target_surface_transforms_are_animating()); EXPECT_FALSE(child_of_rs2->draw_transform_is_animating()); EXPECT_TRUE(grand_child_of_rs2->draw_transform_is_animating()); // Verify screen_space_transform_is_animating values EXPECT_FALSE(parent->screen_space_transform_is_animating()); EXPECT_FALSE(child_of_root->screen_space_transform_is_animating()); EXPECT_TRUE(grand_child_of_root->screen_space_transform_is_animating()); EXPECT_FALSE(render_surface1->screen_space_transform_is_animating()); EXPECT_FALSE(render_surface1->render_surface() ->screen_space_transforms_are_animating()); EXPECT_FALSE(child_of_rs1->screen_space_transform_is_animating()); EXPECT_FALSE(grand_child_of_rs1->screen_space_transform_is_animating()); EXPECT_TRUE(render_surface2->screen_space_transform_is_animating()); EXPECT_TRUE(render_surface2->render_surface() ->screen_space_transforms_are_animating()); EXPECT_TRUE(child_of_rs2->screen_space_transform_is_animating()); EXPECT_TRUE(grand_child_of_rs2->screen_space_transform_is_animating()); // Sanity check. If these fail there is probably a bug in the test itself. // It is expected that we correctly set up transforms so that the y-component // of the screen-space transform encodes the "depth" of the layer in the tree. EXPECT_FLOAT_EQ(1.0, parent->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(2.0, child_of_root->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ( 3.0, grand_child_of_root->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(2.0, render_surface1->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(3.0, child_of_rs1->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ( 4.0, grand_child_of_rs1->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(3.0, render_surface2->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ(4.0, child_of_rs2->screen_space_transform().matrix().get(1, 3)); EXPECT_FLOAT_EQ( 5.0, grand_child_of_rs2->screen_space_transform().matrix().get(1, 3)); } TEST_F(LayerTreeHostCommonTest, VisibleRectForIdentityTransform) { // Test the calculateVisibleRect() function works correctly for identity // transforms. gfx::Rect target_surface_rect = gfx::Rect(0, 0, 100, 100); gfx::Transform layer_to_surface_transform; // Case 1: Layer is contained within the surface. gfx::Rect layer_content_rect = gfx::Rect(10, 10, 30, 30); gfx::Rect expected = gfx::Rect(10, 10, 30, 30); gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); // Case 2: Layer is outside the surface rect. layer_content_rect = gfx::Rect(120, 120, 30, 30); actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_TRUE(actual.IsEmpty()); // Case 3: Layer is partially overlapping the surface rect. layer_content_rect = gfx::Rect(80, 80, 30, 30); expected = gfx::Rect(80, 80, 20, 20); actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); } TEST_F(LayerTreeHostCommonTest, VisibleRectForTranslations) { // Test the calculateVisibleRect() function works correctly for scaling // transforms. gfx::Rect target_surface_rect = gfx::Rect(0, 0, 100, 100); gfx::Rect layer_content_rect = gfx::Rect(0, 0, 30, 30); gfx::Transform layer_to_surface_transform; // Case 1: Layer is contained within the surface. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(10.0, 10.0); gfx::Rect expected = gfx::Rect(0, 0, 30, 30); gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); // Case 2: Layer is outside the surface rect. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(120.0, 120.0); actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_TRUE(actual.IsEmpty()); // Case 3: Layer is partially overlapping the surface rect. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(80.0, 80.0); expected = gfx::Rect(0, 0, 20, 20); actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); } TEST_F(LayerTreeHostCommonTest, VisibleRectFor2DRotations) { // Test the calculateVisibleRect() function works correctly for rotations // about z-axis (i.e. 2D rotations). Remember that calculateVisibleRect() // should return the g in the layer's space. gfx::Rect target_surface_rect = gfx::Rect(0, 0, 100, 100); gfx::Rect layer_content_rect = gfx::Rect(0, 0, 30, 30); gfx::Transform layer_to_surface_transform; // Case 1: Layer is contained within the surface. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(50.0, 50.0); layer_to_surface_transform.Rotate(45.0); gfx::Rect expected = gfx::Rect(0, 0, 30, 30); gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); // Case 2: Layer is outside the surface rect. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(-50.0, 0.0); layer_to_surface_transform.Rotate(45.0); actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_TRUE(actual.IsEmpty()); // Case 3: The layer is rotated about its top-left corner. In surface space, // the layer is oriented diagonally, with the left half outside of the render // surface. In this case, the g should still be the entire layer // (remember the g is computed in layer space); both the top-left // and bottom-right corners of the layer are still visible. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Rotate(45.0); expected = gfx::Rect(0, 0, 30, 30); actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); // Case 4: The layer is rotated about its top-left corner, and translated // upwards. In surface space, the layer is oriented diagonally, with only the // top corner of the surface overlapping the layer. In layer space, the render // surface overlaps the right side of the layer. The g should be // the layer's right half. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(0.0, -sqrt(2.0) * 15.0); layer_to_surface_transform.Rotate(45.0); expected = gfx::Rect(15, 0, 15, 30); // Right half of layer bounds. actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); } TEST_F(LayerTreeHostCommonTest, VisibleRectFor3dOrthographicTransform) { // Test that the calculateVisibleRect() function works correctly for 3d // transforms. gfx::Rect target_surface_rect = gfx::Rect(0, 0, 100, 100); gfx::Rect layer_content_rect = gfx::Rect(0, 0, 100, 100); gfx::Transform layer_to_surface_transform; // Case 1: Orthographic projection of a layer rotated about y-axis by 45 // degrees, should be fully contained in the render surface. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.RotateAboutYAxis(45.0); gfx::Rect expected = gfx::Rect(0, 0, 100, 100); gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); // Case 2: Orthographic projection of a layer rotated about y-axis by 45 // degrees, but shifted to the side so only the right-half the layer would be // visible on the surface. // 100 is the un-rotated layer width; divided by sqrt(2) is the rotated width. SkMScalar half_width_of_rotated_layer = SkDoubleToMScalar((100.0 / sqrt(2.0)) * 0.5); layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(-half_width_of_rotated_layer, 0.0); layer_to_surface_transform.RotateAboutYAxis(45.0); // Rotates about the left // edge of the layer. expected = gfx::Rect(50, 0, 50, 100); // Tight half of the layer. actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); } TEST_F(LayerTreeHostCommonTest, VisibleRectFor3dPerspectiveTransform) { // Test the calculateVisibleRect() function works correctly when the layer has // a perspective projection onto the target surface. gfx::Rect target_surface_rect = gfx::Rect(0, 0, 100, 100); gfx::Rect layer_content_rect = gfx::Rect(-50, -50, 200, 200); gfx::Transform layer_to_surface_transform; // Case 1: Even though the layer is twice as large as the surface, due to // perspective foreshortening, the layer will fit fully in the surface when // its translated more than the perspective amount. layer_to_surface_transform.MakeIdentity(); // The following sequence of transforms applies the perspective about the // center of the surface. layer_to_surface_transform.Translate(50.0, 50.0); layer_to_surface_transform.ApplyPerspectiveDepth(9.0); layer_to_surface_transform.Translate(-50.0, -50.0); // This translate places the layer in front of the surface's projection plane. layer_to_surface_transform.Translate3d(0.0, 0.0, -27.0); gfx::Rect expected = gfx::Rect(-50, -50, 200, 200); gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); // Case 2: same projection as before, except that the layer is also translated // to the side, so that only the right half of the layer should be visible. // // Explanation of expected result: The perspective ratio is (z distance // between layer and camera origin) / (z distance between projection plane and // camera origin) == ((-27 - 9) / 9) Then, by similar triangles, if we want to // move a layer by translating -50 units in projected surface units (so that // only half of it is visible), then we would need to translate by (-36 / 9) * // -50 == -200 in the layer's units. layer_to_surface_transform.Translate3d(-200.0, 0.0, 0.0); expected = gfx::Rect(gfx::Point(50, -50), gfx::Size(100, 200)); // The right half of the layer's // bounding rect. actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); } TEST_F(LayerTreeHostCommonTest, VisibleRectFor3dOrthographicIsNotClippedBehindSurface) { // There is currently no explicit concept of an orthographic projection plane // in our code (nor in the CSS spec to my knowledge). Therefore, layers that // are technically behind the surface in an orthographic world should not be // clipped when they are flattened to the surface. gfx::Rect target_surface_rect = gfx::Rect(0, 0, 100, 100); gfx::Rect layer_content_rect = gfx::Rect(0, 0, 100, 100); gfx::Transform layer_to_surface_transform; // This sequence of transforms effectively rotates the layer about the y-axis // at the center of the layer. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.Translate(50.0, 0.0); layer_to_surface_transform.RotateAboutYAxis(45.0); layer_to_surface_transform.Translate(-50.0, 0.0); gfx::Rect expected = gfx::Rect(0, 0, 100, 100); gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); } TEST_F(LayerTreeHostCommonTest, VisibleRectFor3dPerspectiveWhenClippedByW) { // Test the calculateVisibleRect() function works correctly when projecting a // surface onto a layer, but the layer is partially behind the camera (not // just behind the projection plane). In this case, the cartesian coordinates // may seem to be valid, but actually they are not. The visible rect needs to // be properly clipped by the w = 0 plane in homogeneous coordinates before // converting to cartesian coordinates. gfx::Rect target_surface_rect = gfx::Rect(-50, -50, 100, 100); gfx::Rect layer_content_rect = gfx::Rect(-10, -1, 20, 2); gfx::Transform layer_to_surface_transform; // The layer is positioned so that the right half of the layer should be in // front of the camera, while the other half is behind the surface's // projection plane. The following sequence of transforms applies the // perspective and rotation about the center of the layer. layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.ApplyPerspectiveDepth(1.0); layer_to_surface_transform.Translate3d(-2.0, 0.0, 1.0); layer_to_surface_transform.RotateAboutYAxis(45.0); // Sanity check that this transform does indeed cause w < 0 when applying the // transform, otherwise this code is not testing the intended scenario. bool clipped; MathUtil::MapQuad(layer_to_surface_transform, gfx::QuadF(gfx::RectF(layer_content_rect)), &clipped); ASSERT_TRUE(clipped); int expected_x_position = 0; int expected_width = 10; gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_EQ(expected_x_position, actual.x()); EXPECT_EQ(expected_width, actual.width()); } TEST_F(LayerTreeHostCommonTest, VisibleRectForPerspectiveUnprojection) { // To determine visible rect in layer space, there needs to be an // un-projection from surface space to layer space. When the original // transform was a perspective projection that was clipped, it returns a rect // that encloses the clipped bounds. Un-projecting this new rect may require // clipping again. // This sequence of transforms causes one corner of the layer to protrude // across the w = 0 plane, and should be clipped. gfx::Rect target_surface_rect = gfx::Rect(-50, -50, 100, 100); gfx::Rect layer_content_rect = gfx::Rect(-10, -10, 20, 20); gfx::Transform layer_to_surface_transform; layer_to_surface_transform.MakeIdentity(); layer_to_surface_transform.ApplyPerspectiveDepth(1.0); layer_to_surface_transform.Translate3d(0.0, 0.0, -5.0); layer_to_surface_transform.RotateAboutYAxis(45.0); layer_to_surface_transform.RotateAboutXAxis(80.0); // Sanity check that un-projection does indeed cause w < 0, otherwise this // code is not testing the intended scenario. bool clipped; gfx::RectF clipped_rect = MathUtil::MapClippedRect(layer_to_surface_transform, layer_content_rect); MathUtil::ProjectQuad( Inverse(layer_to_surface_transform), gfx::QuadF(clipped_rect), &clipped); ASSERT_TRUE(clipped); // Only the corner of the layer is not visible on the surface because of being // clipped. But, the net result of rounding visible region to an axis-aligned // rect is that the entire layer should still be considered visible. gfx::Rect expected = gfx::Rect(-10, -10, 20, 20); gfx::Rect actual = LayerTreeHostCommon::CalculateVisibleRect( target_surface_rect, layer_content_rect, layer_to_surface_transform); EXPECT_RECT_EQ(expected, actual); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsForSimpleLayers) { scoped_refptr root = Layer::Create(); scoped_refptr child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child3 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(child1); root->AddChild(child2); root->AddChild(child3); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(75.f, 75.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(125.f, 125.f), gfx::Size(50, 50), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->drawable_content_rect()); // Layers that do not draw content should have empty visible_content_rects. EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), root->visible_content_rect()); // layer visible_content_rects are clipped by their target surface. EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 25, 25), child2->visible_content_rect()); EXPECT_TRUE(child3->visible_content_rect().IsEmpty()); // layer drawable_content_rects are not clipped. EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child1->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(75, 75, 50, 50), child2->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(125, 125, 50, 50), child3->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsForLayersClippedByLayer) { scoped_refptr root = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr grand_child2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr grand_child3 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(child); child->AddChild(grand_child1); child->AddChild(grand_child2); child->AddChild(grand_child3); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(grand_child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(grand_child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(75.f, 75.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(grand_child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(125.f, 125.f), gfx::Size(50, 50), true, false); child->SetMasksToBounds(true); ExecuteCalculateDrawProperties(root.get()); ASSERT_FALSE(child->render_surface()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->drawable_content_rect()); // Layers that do not draw content should have empty visible content rects. EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), root->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), child->visible_content_rect()); // All grandchild visible content rects should be clipped by child. EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), grand_child1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 25, 25), grand_child2->visible_content_rect()); EXPECT_TRUE(grand_child3->visible_content_rect().IsEmpty()); // All grandchild DrawableContentRects should also be clipped by child. EXPECT_RECT_EQ(gfx::Rect(5, 5, 50, 50), grand_child1->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(75, 75, 25, 25), grand_child2->drawable_content_rect()); EXPECT_TRUE(grand_child3->drawable_content_rect().IsEmpty()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsForLayersInUnclippedRenderSurface) { scoped_refptr root = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child3 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(render_surface1); render_surface1->AddChild(child1); render_surface1->AddChild(child2); render_surface1->AddChild(child3); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(3, 4), true, false); SetLayerPropertiesForTesting(child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(75.f, 75.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(125.f, 125.f), gfx::Size(50, 50), true, false); render_surface1->SetForceRenderSurface(true); ExecuteCalculateDrawProperties(root.get()); ASSERT_TRUE(render_surface1->render_surface()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->drawable_content_rect()); // Layers that do not draw content should have empty visible content rects. EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), root->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), render_surface1->visible_content_rect()); // An unclipped surface grows its DrawableContentRect to include all drawable // regions of the subtree. EXPECT_RECT_EQ(gfx::Rect(5, 5, 170, 170), render_surface1->render_surface()->DrawableContentRect()); // All layers that draw content into the unclipped surface are also unclipped. EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child2->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child3->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(5, 5, 50, 50), child1->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(75, 75, 50, 50), child2->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(125, 125, 50, 50), child3->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsForLayersWithUninvertibleTransform) { scoped_refptr root = Layer::Create(); scoped_refptr child = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // Case 1: a truly degenerate matrix gfx::Transform identity_matrix; gfx::Transform uninvertible_matrix(0.0, 0.0, 0.0, 0.0, 0.0, 0.0); ASSERT_FALSE(uninvertible_matrix.IsInvertible()); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), uninvertible_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(child->visible_content_rect().IsEmpty()); EXPECT_TRUE(child->drawable_content_rect().IsEmpty()); // Case 2: a matrix with flattened z, technically uninvertible but still // drawable and visible. In this case, we must assume that the entire layer // bounds are visible since there is no way to inverse-project the surface // bounds to intersect. uninvertible_matrix.MakeIdentity(); uninvertible_matrix.matrix().set(2, 2, 0.0); ASSERT_FALSE(uninvertible_matrix.IsInvertible()); SetLayerPropertiesForTesting(child.get(), uninvertible_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(5, 5, 50, 50), child->drawable_content_rect()); // Case 3: a matrix with flattened z, technically uninvertible but still // drawable, but not visible. In this case, we don't need to conservatively // assume that the whole layer is visible. uninvertible_matrix.MakeIdentity(); uninvertible_matrix.Translate(500.0, 0.0); uninvertible_matrix.matrix().set(2, 2, 0.0); ASSERT_FALSE(uninvertible_matrix.IsInvertible()); SetLayerPropertiesForTesting(child.get(), uninvertible_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(child->visible_content_rect().IsEmpty()); EXPECT_RECT_EQ(gfx::Rect(505, 5, 50, 50), child->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsForLayersInClippedRenderSurface) { scoped_refptr root = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child3 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(render_surface1); render_surface1->AddChild(child1); render_surface1->AddChild(child2); render_surface1->AddChild(child3); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(3, 4), true, false); SetLayerPropertiesForTesting(child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(75.f, 75.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(125.f, 125.f), gfx::Size(50, 50), true, false); root->SetMasksToBounds(true); render_surface1->SetForceRenderSurface(true); ExecuteCalculateDrawProperties(root.get()); ASSERT_TRUE(render_surface1->render_surface()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->drawable_content_rect()); // Layers that do not draw content should have empty visible content rects. EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), root->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), render_surface1->visible_content_rect()); // A clipped surface grows its DrawableContentRect to include all drawable // regions of the subtree, but also gets clamped by the ancestor's clip. EXPECT_RECT_EQ(gfx::Rect(5, 5, 95, 95), render_surface1->render_surface()->DrawableContentRect()); // All layers that draw content into the surface have their visible content // rect clipped by the surface clip rect. EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 25, 25), child2->visible_content_rect()); EXPECT_TRUE(child3->visible_content_rect().IsEmpty()); // But the DrawableContentRects are unclipped. EXPECT_RECT_EQ(gfx::Rect(5, 5, 50, 50), child1->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(75, 75, 50, 50), child2->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(125, 125, 50, 50), child3->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsForSurfaceHierarchy) { // Check that clipping does not propagate down surfaces. scoped_refptr root = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr render_surface2 = Layer::Create(); scoped_refptr child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child3 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(render_surface1); render_surface1->AddChild(render_surface2); render_surface2->AddChild(child1); render_surface2->AddChild(child2); render_surface2->AddChild(child3); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(3, 4), true, false); SetLayerPropertiesForTesting(render_surface2.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(7, 13), true, false); SetLayerPropertiesForTesting(child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(75.f, 75.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(125.f, 125.f), gfx::Size(50, 50), true, false); root->SetMasksToBounds(true); render_surface1->SetForceRenderSurface(true); render_surface2->SetForceRenderSurface(true); ExecuteCalculateDrawProperties(root.get()); ASSERT_TRUE(render_surface1->render_surface()); ASSERT_TRUE(render_surface2->render_surface()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->drawable_content_rect()); // Layers that do not draw content should have empty visible content rects. EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), root->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), render_surface1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), render_surface2->visible_content_rect()); // A clipped surface grows its DrawableContentRect to include all drawable // regions of the subtree, but also gets clamped by the ancestor's clip. EXPECT_RECT_EQ(gfx::Rect(5, 5, 95, 95), render_surface1->render_surface()->DrawableContentRect()); // render_surface1 lives in the "unclipped universe" of render_surface1, and // is only implicitly clipped by render_surface1's content rect. So, // render_surface2 grows to enclose all drawable content of its subtree. EXPECT_RECT_EQ(gfx::Rect(5, 5, 170, 170), render_surface2->render_surface()->DrawableContentRect()); // All layers that draw content into render_surface2 think they are unclipped. EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child2->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child3->visible_content_rect()); // DrawableContentRects are also unclipped. EXPECT_RECT_EQ(gfx::Rect(5, 5, 50, 50), child1->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(75, 75, 50, 50), child2->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(125, 125, 50, 50), child3->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsWithTransformOnUnclippedSurface) { // Layers that have non-axis aligned bounds (due to transforms) have an // expanded, axis-aligned DrawableContentRect and visible content rect. scoped_refptr root = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(render_surface1); render_surface1->AddChild(child1); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; gfx::Transform child_rotation; child_rotation.Rotate(45.0); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(3, 4), true, false); SetLayerPropertiesForTesting(child1.get(), child_rotation, gfx::PointF(0.5f, 0.5f), gfx::PointF(25.f, 25.f), gfx::Size(50, 50), true, false); render_surface1->SetForceRenderSurface(true); ExecuteCalculateDrawProperties(root.get()); ASSERT_TRUE(render_surface1->render_surface()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), root->drawable_content_rect()); // Layers that do not draw content should have empty visible content rects. EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), root->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), render_surface1->visible_content_rect()); // The unclipped surface grows its DrawableContentRect to include all drawable // regions of the subtree. int diagonal_radius = ceil(sqrt(2.0) * 25.0); gfx::Rect expected_surface_drawable_content = gfx::Rect(50 - diagonal_radius, 50 - diagonal_radius, diagonal_radius * 2, diagonal_radius * 2); EXPECT_RECT_EQ(expected_surface_drawable_content, render_surface1->render_surface()->DrawableContentRect()); // All layers that draw content into the unclipped surface are also unclipped. EXPECT_RECT_EQ(gfx::Rect(0, 0, 50, 50), child1->visible_content_rect()); EXPECT_RECT_EQ(expected_surface_drawable_content, child1->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsWithTransformOnClippedSurface) { // Layers that have non-axis aligned bounds (due to transforms) have an // expanded, axis-aligned DrawableContentRect and visible content rect. scoped_refptr root = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); root->AddChild(render_surface1); render_surface1->AddChild(child1); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; gfx::Transform child_rotation; child_rotation.Rotate(45.0); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(3, 4), true, false); SetLayerPropertiesForTesting(child1.get(), child_rotation, gfx::PointF(0.5f, 0.5f), gfx::PointF(25.f, 25.f), gfx::Size(50, 50), true, false); root->SetMasksToBounds(true); render_surface1->SetForceRenderSurface(true); ExecuteCalculateDrawProperties(root.get()); ASSERT_TRUE(render_surface1->render_surface()); // The clipped surface clamps the DrawableContentRect that encloses the // rotated layer. int diagonal_radius = ceil(sqrt(2.0) * 25.0); gfx::Rect unclipped_surface_content = gfx::Rect(50 - diagonal_radius, 50 - diagonal_radius, diagonal_radius * 2, diagonal_radius * 2); gfx::Rect expected_surface_drawable_content = gfx::IntersectRects(unclipped_surface_content, gfx::Rect(0, 0, 50, 50)); EXPECT_RECT_EQ(expected_surface_drawable_content, render_surface1->render_surface()->DrawableContentRect()); // On the clipped surface, only a quarter of the child1 is visible, but when // rotating it back to child1's content space, the actual enclosing rect ends // up covering the full left half of child1. // // Given the floating point math, this number is a little bit fuzzy. EXPECT_RECT_EQ(gfx::Rect(0, 0, 26, 50), child1->visible_content_rect()); // The child's DrawableContentRect is unclipped. EXPECT_RECT_EQ(unclipped_surface_content, child1->drawable_content_rect()); } TEST_F(LayerTreeHostCommonTest, DrawableAndVisibleContentRectsInHighDPI) { MockContentLayerClient client; scoped_refptr root = Layer::Create(); scoped_refptr render_surface1 = CreateDrawableContentLayer(&client); scoped_refptr render_surface2 = CreateDrawableContentLayer(&client); scoped_refptr child1 = CreateDrawableContentLayer(&client); scoped_refptr child2 = CreateDrawableContentLayer(&client); scoped_refptr child3 = CreateDrawableContentLayer(&client); root->AddChild(render_surface1); render_surface1->AddChild(render_surface2); render_surface2->AddChild(child1); render_surface2->AddChild(child2); render_surface2->AddChild(child3); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(3, 4), true, false); SetLayerPropertiesForTesting(render_surface2.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(7, 13), true, false); SetLayerPropertiesForTesting(child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(5.f, 5.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(75.f, 75.f), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(child3.get(), identity_matrix, gfx::PointF(), gfx::PointF(125.f, 125.f), gfx::Size(50, 50), true, false); float device_scale_factor = 2.f; root->SetMasksToBounds(true); render_surface1->SetForceRenderSurface(true); render_surface2->SetForceRenderSurface(true); ExecuteCalculateDrawProperties(root.get(), device_scale_factor); ASSERT_TRUE(render_surface1->render_surface()); ASSERT_TRUE(render_surface2->render_surface()); // drawable_content_rects for all layers and surfaces are scaled by // device_scale_factor. EXPECT_RECT_EQ(gfx::Rect(0, 0, 200, 200), root->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 200, 200), root->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(10, 10, 190, 190), render_surface1->render_surface()->DrawableContentRect()); // render_surface2 lives in the "unclipped universe" of render_surface1, and // is only implicitly clipped by render_surface1. EXPECT_RECT_EQ(gfx::Rect(10, 10, 350, 350), render_surface2->render_surface()->DrawableContentRect()); EXPECT_RECT_EQ(gfx::Rect(10, 10, 100, 100), child1->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(150, 150, 100, 100), child2->drawable_content_rect()); EXPECT_RECT_EQ(gfx::Rect(250, 250, 100, 100), child3->drawable_content_rect()); // The root layer does not actually draw content of its own. EXPECT_RECT_EQ(gfx::Rect(0, 0, 0, 0), root->visible_content_rect()); // All layer visible content rects are expressed in content space of each // layer, so they are also scaled by the device_scale_factor. EXPECT_RECT_EQ(gfx::Rect(0, 0, 6, 8), render_surface1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 14, 26), render_surface2->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), child1->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), child2->visible_content_rect()); EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), child3->visible_content_rect()); } TEST_F(LayerTreeHostCommonTest, BackFaceCullingWithoutPreserves3d) { // Verify the behavior of back-face culling when there are no preserve-3d // layers. Note that 3d transforms still apply in this case, but they are // "flattened" to each parent layer according to current W3C spec. const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr front_facing_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr front_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr front_facing_child_of_front_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_child_of_front_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr front_facing_child_of_back_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_child_of_back_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(front_facing_child); parent->AddChild(back_facing_child); parent->AddChild(front_facing_surface); parent->AddChild(back_facing_surface); front_facing_surface->AddChild(front_facing_child_of_front_facing_surface); front_facing_surface->AddChild(back_facing_child_of_front_facing_surface); back_facing_surface->AddChild(front_facing_child_of_back_facing_surface); back_facing_surface->AddChild(back_facing_child_of_back_facing_surface); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); // Nothing is double-sided front_facing_child->SetDoubleSided(false); back_facing_child->SetDoubleSided(false); front_facing_surface->SetDoubleSided(false); back_facing_surface->SetDoubleSided(false); front_facing_child_of_front_facing_surface->SetDoubleSided(false); back_facing_child_of_front_facing_surface->SetDoubleSided(false); front_facing_child_of_back_facing_surface->SetDoubleSided(false); back_facing_child_of_back_facing_surface->SetDoubleSided(false); gfx::Transform backface_matrix; backface_matrix.Translate(50.0, 50.0); backface_matrix.RotateAboutYAxis(180.0); backface_matrix.Translate(-50.0, -50.0); // Having a descendant and opacity will force these to have render surfaces. front_facing_surface->SetOpacity(0.5f); back_facing_surface->SetOpacity(0.5f); // Nothing preserves 3d. According to current W3C CSS gfx::Transforms spec, // these layers should blindly use their own local transforms to determine // back-face culling. SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(front_facing_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(back_facing_child.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(front_facing_surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(back_facing_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(front_facing_child_of_front_facing_surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(back_facing_child_of_front_facing_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(front_facing_child_of_back_facing_surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(back_facing_child_of_back_facing_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Verify which render surfaces were created. EXPECT_FALSE(front_facing_child->render_surface()); EXPECT_FALSE(back_facing_child->render_surface()); EXPECT_TRUE(front_facing_surface->render_surface()); EXPECT_TRUE(back_facing_surface->render_surface()); EXPECT_FALSE(front_facing_child_of_front_facing_surface->render_surface()); EXPECT_FALSE(back_facing_child_of_front_facing_surface->render_surface()); EXPECT_FALSE(front_facing_child_of_back_facing_surface->render_surface()); EXPECT_FALSE(back_facing_child_of_back_facing_surface->render_surface()); // Verify the render_surface_layer_list. ASSERT_EQ(3u, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(1)->id()); // Even though the back facing surface LAYER gets culled, the other // descendants should still be added, so the SURFACE should not be culled. EXPECT_EQ(back_facing_surface->id(), render_surface_layer_list.at(2)->id()); // Verify root surface's layer list. ASSERT_EQ( 3u, render_surface_layer_list.at(0)->render_surface()->layer_list().size()); EXPECT_EQ(front_facing_child->id(), render_surface_layer_list.at(0) ->render_surface() ->layer_list() .at(0) ->id()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(0) ->render_surface() ->layer_list() .at(1) ->id()); EXPECT_EQ(back_facing_surface->id(), render_surface_layer_list.at(0) ->render_surface() ->layer_list() .at(2) ->id()); // Verify front_facing_surface's layer list. ASSERT_EQ( 2u, render_surface_layer_list.at(1)->render_surface()->layer_list().size()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(1) ->render_surface() ->layer_list() .at(0) ->id()); EXPECT_EQ(front_facing_child_of_front_facing_surface->id(), render_surface_layer_list.at(1) ->render_surface() ->layer_list() .at(1) ->id()); // Verify back_facing_surface's layer list; its own layer should be culled // from the surface list. ASSERT_EQ( 1u, render_surface_layer_list.at(2)->render_surface()->layer_list().size()); EXPECT_EQ(front_facing_child_of_back_facing_surface->id(), render_surface_layer_list.at(2) ->render_surface() ->layer_list() .at(0) ->id()); } TEST_F(LayerTreeHostCommonTest, BackFaceCullingWithPreserves3d) { // Verify the behavior of back-face culling when preserves-3d transform style // is used. const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr front_facing_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr front_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr front_facing_child_of_front_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_child_of_front_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr front_facing_child_of_back_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_child_of_back_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr dummy_replica_layer1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr dummy_replica_layer2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(front_facing_child); parent->AddChild(back_facing_child); parent->AddChild(front_facing_surface); parent->AddChild(back_facing_surface); front_facing_surface->AddChild(front_facing_child_of_front_facing_surface); front_facing_surface->AddChild(back_facing_child_of_front_facing_surface); back_facing_surface->AddChild(front_facing_child_of_back_facing_surface); back_facing_surface->AddChild(back_facing_child_of_back_facing_surface); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); // Nothing is double-sided front_facing_child->SetDoubleSided(false); back_facing_child->SetDoubleSided(false); front_facing_surface->SetDoubleSided(false); back_facing_surface->SetDoubleSided(false); front_facing_child_of_front_facing_surface->SetDoubleSided(false); back_facing_child_of_front_facing_surface->SetDoubleSided(false); front_facing_child_of_back_facing_surface->SetDoubleSided(false); back_facing_child_of_back_facing_surface->SetDoubleSided(false); gfx::Transform backface_matrix; backface_matrix.Translate(50.0, 50.0); backface_matrix.RotateAboutYAxis(180.0); backface_matrix.Translate(-50.0, -50.0); // Opacity will not force creation of render surfaces in this case because of // the preserve-3d transform style. Instead, an example of when a surface // would be created with preserve-3d is when there is a replica layer. front_facing_surface->SetReplicaLayer(dummy_replica_layer1.get()); back_facing_surface->SetReplicaLayer(dummy_replica_layer2.get()); // Each surface creates its own new 3d rendering context (as defined by W3C // spec). According to current W3C CSS gfx::Transforms spec, layers in a 3d // rendering context should use the transform with respect to that context. // This 3d rendering context occurs when (a) parent's transform style is flat // and (b) the layer's transform style is preserve-3d. SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); // parent transform style is flat. SetLayerPropertiesForTesting(front_facing_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(back_facing_child.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); // surface transform style is preserve-3d. SetLayerPropertiesForTesting(front_facing_surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); // surface transform style is preserve-3d. SetLayerPropertiesForTesting(back_facing_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); SetLayerPropertiesForTesting(front_facing_child_of_front_facing_surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, true); SetLayerPropertiesForTesting(back_facing_child_of_front_facing_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, true); SetLayerPropertiesForTesting(front_facing_child_of_back_facing_surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, true); SetLayerPropertiesForTesting(back_facing_child_of_back_facing_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, true); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Verify which render surfaces were created. EXPECT_FALSE(front_facing_child->render_surface()); EXPECT_FALSE(back_facing_child->render_surface()); EXPECT_TRUE(front_facing_surface->render_surface()); EXPECT_FALSE(back_facing_surface->render_surface()); EXPECT_FALSE(front_facing_child_of_front_facing_surface->render_surface()); EXPECT_FALSE(back_facing_child_of_front_facing_surface->render_surface()); EXPECT_FALSE(front_facing_child_of_back_facing_surface->render_surface()); EXPECT_FALSE(back_facing_child_of_back_facing_surface->render_surface()); // Verify the render_surface_layer_list. The back-facing surface should be // culled. ASSERT_EQ(2u, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(1)->id()); // Verify root surface's layer list. ASSERT_EQ( 2u, render_surface_layer_list.at(0)->render_surface()->layer_list().size()); EXPECT_EQ(front_facing_child->id(), render_surface_layer_list.at(0) ->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(0) ->render_surface()->layer_list().at(1)->id()); // Verify front_facing_surface's layer list. ASSERT_EQ( 2u, render_surface_layer_list.at(1)->render_surface()->layer_list().size()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(1) ->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(front_facing_child_of_front_facing_surface->id(), render_surface_layer_list.at(1) ->render_surface()->layer_list().at(1)->id()); } TEST_F(LayerTreeHostCommonTest, BackFaceCullingWithAnimatingTransforms) { // Verify that layers are appropriately culled when their back face is showing // and they are not double sided, while animations are going on. // // Layers that are animating do not get culled on the main thread, as their // transforms should be treated as "unknown" so we can not be sure that their // back face is really showing. const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr animating_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child_of_animating_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr animating_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(child); parent->AddChild(animating_surface); animating_surface->AddChild(child_of_animating_surface); parent->AddChild(animating_child); parent->AddChild(child2); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); // Nothing is double-sided child->SetDoubleSided(false); child2->SetDoubleSided(false); animating_surface->SetDoubleSided(false); child_of_animating_surface->SetDoubleSided(false); animating_child->SetDoubleSided(false); gfx::Transform backface_matrix; backface_matrix.Translate(50.0, 50.0); backface_matrix.RotateAboutYAxis(180.0); backface_matrix.Translate(-50.0, -50.0); // Make our render surface. animating_surface->SetForceRenderSurface(true); // Animate the transform on the render surface. AddAnimatedTransformToController( animating_surface->layer_animation_controller(), 10.0, 30, 0); // This is just an animating layer, not a surface. AddAnimatedTransformToController( animating_child->layer_animation_controller(), 10.0, 30, 0); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(animating_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child_of_animating_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(animating_child.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_FALSE(child->render_surface()); EXPECT_TRUE(animating_surface->render_surface()); EXPECT_FALSE(child_of_animating_surface->render_surface()); EXPECT_FALSE(animating_child->render_surface()); EXPECT_FALSE(child2->render_surface()); // Verify that the animating_child and child_of_animating_surface were not // culled, but that child was. ASSERT_EQ(2u, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(animating_surface->id(), render_surface_layer_list.at(1)->id()); // The non-animating child be culled from the layer list for the parent render // surface. ASSERT_EQ( 3u, render_surface_layer_list.at(0)->render_surface()->layer_list().size()); EXPECT_EQ(animating_surface->id(), render_surface_layer_list.at(0) ->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(animating_child->id(), render_surface_layer_list.at(0) ->render_surface()->layer_list().at(1)->id()); EXPECT_EQ(child2->id(), render_surface_layer_list.at(0) ->render_surface()->layer_list().at(2)->id()); ASSERT_EQ( 2u, render_surface_layer_list.at(1)->render_surface()->layer_list().size()); EXPECT_EQ(animating_surface->id(), render_surface_layer_list.at(1) ->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(child_of_animating_surface->id(), render_surface_layer_list.at(1) ->render_surface()->layer_list().at(1)->id()); EXPECT_FALSE(child2->visible_content_rect().IsEmpty()); // The animating layers should have a visible content rect that represents the // area of the front face that is within the viewport. EXPECT_EQ(animating_child->visible_content_rect(), gfx::Rect(animating_child->content_bounds())); EXPECT_EQ(animating_surface->visible_content_rect(), gfx::Rect(animating_surface->content_bounds())); // And layers in the subtree of the animating layer should have valid visible // content rects also. EXPECT_EQ(child_of_animating_surface->visible_content_rect(), gfx::Rect(child_of_animating_surface->content_bounds())); } TEST_F(LayerTreeHostCommonTest, BackFaceCullingWithPreserves3dForFlatteningSurface) { // Verify the behavior of back-face culling for a render surface that is // created when it flattens its subtree, and its parent has preserves-3d. const gfx::Transform identity_matrix; scoped_refptr parent = Layer::Create(); scoped_refptr front_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr back_facing_surface = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child1 = make_scoped_refptr(new LayerWithForcedDrawsContent()); scoped_refptr child2 = make_scoped_refptr(new LayerWithForcedDrawsContent()); parent->AddChild(front_facing_surface); parent->AddChild(back_facing_surface); front_facing_surface->AddChild(child1); back_facing_surface->AddChild(child2); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); // RenderSurfaces are not double-sided front_facing_surface->SetDoubleSided(false); back_facing_surface->SetDoubleSided(false); gfx::Transform backface_matrix; backface_matrix.Translate(50.0, 50.0); backface_matrix.RotateAboutYAxis(180.0); backface_matrix.Translate(-50.0, -50.0); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); // parent transform style is preserve3d. SetLayerPropertiesForTesting(front_facing_surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, true); // surface transform style is flat. SetLayerPropertiesForTesting(back_facing_surface.get(), backface_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, true); // surface transform style is flat. SetLayerPropertiesForTesting(child1.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child2.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); front_facing_surface->SetIs3dSorted(true); back_facing_surface->SetIs3dSorted(true); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Verify which render surfaces were created. EXPECT_TRUE(front_facing_surface->render_surface()); EXPECT_FALSE( back_facing_surface->render_surface()); // because it should be culled EXPECT_FALSE(child1->render_surface()); EXPECT_FALSE(child2->render_surface()); // Verify the render_surface_layer_list. The back-facing surface should be // culled. ASSERT_EQ(2u, render_surface_layer_list.size()); EXPECT_EQ(parent->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(1)->id()); // Verify root surface's layer list. ASSERT_EQ( 1u, render_surface_layer_list.at(0)->render_surface()->layer_list().size()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(0) ->render_surface()->layer_list().at(0)->id()); // Verify front_facing_surface's layer list. ASSERT_EQ( 2u, render_surface_layer_list.at(1)->render_surface()->layer_list().size()); EXPECT_EQ(front_facing_surface->id(), render_surface_layer_list.at(1) ->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(child1->id(), render_surface_layer_list.at(1) ->render_surface()->layer_list().at(1)->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForEmptyLayerList) { // Hit testing on an empty render_surface_layer_list should return a null // pointer. LayerImplList render_surface_layer_list; gfx::Point test_point(0, 0); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(10, 20); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); } TEST_F(LayerTreeHostCommonTest, HitTestingForSingleLayer) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit testing for a point outside the layer should return a null pointer. gfx::Point test_point(101, 101); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(-1, -1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the root layer. test_point = gfx::Point(1, 1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(99, 99); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForSingleLayerAndHud) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); scoped_ptr hud = HeadsUpDisplayLayerImpl::Create(host_impl.active_tree(), 11111); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); // Create hud and add it as a child of root. gfx::Size hud_bounds(200, 200); SetLayerPropertiesForTesting(hud.get(), identity_matrix, anchor, position, hud_bounds, true, false); hud->SetDrawsContent(true); host_impl.active_tree()->set_hud_layer(hud.get()); root->AddChild(hud.PassAs()); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), hud_bounds, &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(2u, root->render_surface()->layer_list().size()); // Hit testing for a point inside HUD, but outside root should return null gfx::Point test_point(101, 101); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(-1, -1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the root layer, never the HUD // layer. test_point = gfx::Point(1, 1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(99, 99); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForUninvertibleTransform) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform uninvertible_transform; uninvertible_transform.matrix().set(0, 0, 0.0); uninvertible_transform.matrix().set(1, 1, 0.0); uninvertible_transform.matrix().set(2, 2, 0.0); uninvertible_transform.matrix().set(3, 3, 0.0); ASSERT_FALSE(uninvertible_transform.IsInvertible()); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), uninvertible_transform, anchor, position, bounds, true, false); root->SetDrawsContent(true); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); ASSERT_FALSE(root->screen_space_transform().IsInvertible()); // Hit testing any point should not hit the layer. If the invertible matrix is // accidentally ignored and treated like an identity, then the hit testing // will incorrectly hit the layer when it shouldn't. gfx::Point test_point(1, 1); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(10, 10); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(10, 30); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(50, 50); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(67, 48); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(99, 99); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(-1, -1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); } TEST_F(LayerTreeHostCommonTest, HitTestingForSinglePositionedLayer) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform identity_matrix; gfx::PointF anchor; // this layer is positioned, and hit testing should correctly know where the // layer is located. gfx::PointF position(50.f, 50.f); gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit testing for a point outside the layer should return a null pointer. gfx::Point test_point(49, 49); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Even though the layer exists at (101, 101), it should not be visible there // since the root render surface would clamp it. test_point = gfx::Point(101, 101); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the root layer. test_point = gfx::Point(51, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(99, 99); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForSingleRotatedLayer) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform identity_matrix; gfx::Transform rotation45_degrees_about_center; rotation45_degrees_about_center.Translate(50.0, 50.0); rotation45_degrees_about_center.RotateAboutZAxis(45.0); rotation45_degrees_about_center.Translate(-50.0, -50.0); gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), rotation45_degrees_about_center, anchor, position, bounds, true, false); root->SetDrawsContent(true); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit testing for points outside the layer. // These corners would have been inside the un-transformed layer, but they // should not hit the correctly transformed layer. gfx::Point test_point(99, 99); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(1, 1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the root layer. test_point = gfx::Point(1, 50); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); // Hit testing the corners that would overlap the unclipped layer, but are // outside the clipped region. test_point = gfx::Point(50, -1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_FALSE(result_layer); test_point = gfx::Point(-1, 50); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_FALSE(result_layer); } TEST_F(LayerTreeHostCommonTest, HitTestingForSinglePerspectiveLayer) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform identity_matrix; // perspective_projection_about_center * translation_by_z is designed so that // the 100 x 100 layer becomes 50 x 50, and remains centered at (50, 50). gfx::Transform perspective_projection_about_center; perspective_projection_about_center.Translate(50.0, 50.0); perspective_projection_about_center.ApplyPerspectiveDepth(1.0); perspective_projection_about_center.Translate(-50.0, -50.0); gfx::Transform translation_by_z; translation_by_z.Translate3d(0.0, 0.0, -1.0); gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting( root.get(), perspective_projection_about_center * translation_by_z, anchor, position, bounds, true, false); root->SetDrawsContent(true); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit testing for points outside the layer. // These corners would have been inside the un-transformed layer, but they // should not hit the correctly transformed layer. gfx::Point test_point(24, 24); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(76, 76); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the root layer. test_point = gfx::Point(26, 26); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(74, 74); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForSingleLayerWithScaledContents) { // A layer's visible content rect is actually in the layer's content space. // The screen space transform converts from the layer's origin space to screen // space. This test makes sure that hit testing works correctly accounts for // the contents scale. A contents scale that is not 1 effectively forces a // non-identity transform between layer's content space and layer's origin // space. The hit testing code must take this into account. // // To test this, the layer is positioned at (25, 25), and is size (50, 50). If // contents scale is ignored, then hit testing will mis-interpret the visible // content rect as being larger than the actual bounds of the layer. // FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); gfx::Transform identity_matrix; gfx::PointF anchor; SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, gfx::PointF(), gfx::Size(100, 100), true, false); { gfx::PointF position(25.f, 25.f); gfx::Size bounds(50, 50); scoped_ptr test_layer = LayerImpl::Create(host_impl.active_tree(), 12345); SetLayerPropertiesForTesting(test_layer.get(), identity_matrix, anchor, position, bounds, true, false); // override content bounds and contents scale test_layer->SetContentBounds(gfx::Size(100, 100)); test_layer->SetContentsScale(2, 2); test_layer->SetDrawsContent(true); root->AddChild(test_layer.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. // The visible content rect for test_layer is actually 100x100, even though // its layout size is 50x50, positioned at 25x25. LayerImpl* test_layer = root->children()[0]; EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), test_layer->visible_content_rect()); ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit testing for a point outside the layer should return a null pointer (the // root layer does not draw content, so it will not be hit tested either). gfx::Point test_point(101, 101); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(24, 24); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(76, 76); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the test layer. test_point = gfx::Point(26, 26); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(74, 74); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForSimpleClippedLayer) { // Test that hit-testing will only work for the visible portion of a layer, // and not the entire layer bounds. Here we just test the simple axis-aligned // case. gfx::Transform identity_matrix; gfx::PointF anchor; FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, gfx::PointF(), gfx::Size(100, 100), true, false); { scoped_ptr clipping_layer = LayerImpl::Create(host_impl.active_tree(), 123); // this layer is positioned, and hit testing should correctly know where the // layer is located. gfx::PointF position(25.f, 25.f); gfx::Size bounds(50, 50); SetLayerPropertiesForTesting(clipping_layer.get(), identity_matrix, anchor, position, bounds, true, false); clipping_layer->SetMasksToBounds(true); scoped_ptr child = LayerImpl::Create(host_impl.active_tree(), 456); position = gfx::PointF(-50.f, -50.f); bounds = gfx::Size(300, 300); SetLayerPropertiesForTesting(child.get(), identity_matrix, anchor, position, bounds, true, false); child->SetDrawsContent(true); clipping_layer->AddChild(child.Pass()); root->AddChild(clipping_layer.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); ASSERT_EQ(456, root->render_surface()->layer_list().at(0)->id()); // Hit testing for a point outside the layer should return a null pointer. // Despite the child layer being very large, it should be clipped to the root // layer's bounds. gfx::Point test_point(24, 24); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Even though the layer exists at (101, 101), it should not be visible there // since the clipping_layer would clamp it. test_point = gfx::Point(76, 76); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the child layer. test_point = gfx::Point(26, 26); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(456, result_layer->id()); test_point = gfx::Point(74, 74); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(456, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForMultiClippedRotatedLayer) { // This test checks whether hit testing correctly avoids hit testing with // multiple ancestors that clip in non axis-aligned ways. To pass this test, // the hit testing algorithm needs to recognize that multiple parent layers // may clip the layer, and should not actually hit those clipped areas. // // The child and grand_child layers are both initialized to clip the // rotated_leaf. The child layer is rotated about the top-left corner, so that // the root + child clips combined create a triangle. The rotated_leaf will // only be visible where it overlaps this triangle. // FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 123); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetMasksToBounds(true); { scoped_ptr child = LayerImpl::Create(host_impl.active_tree(), 456); scoped_ptr grand_child = LayerImpl::Create(host_impl.active_tree(), 789); scoped_ptr rotated_leaf = LayerImpl::Create(host_impl.active_tree(), 2468); position = gfx::PointF(10.f, 10.f); bounds = gfx::Size(80, 80); SetLayerPropertiesForTesting(child.get(), identity_matrix, anchor, position, bounds, true, false); child->SetMasksToBounds(true); gfx::Transform rotation45_degrees_about_corner; rotation45_degrees_about_corner.RotateAboutZAxis(45.0); // remember, positioned with respect to its parent which is already at 10, // 10 position = gfx::PointF(); bounds = gfx::Size(200, 200); // to ensure it covers at least sqrt(2) * 100. SetLayerPropertiesForTesting(grand_child.get(), rotation45_degrees_about_corner, anchor, position, bounds, true, false); grand_child->SetMasksToBounds(true); // Rotates about the center of the layer gfx::Transform rotated_leaf_transform; rotated_leaf_transform.Translate( -10.0, -10.0); // cancel out the grand_parent's position rotated_leaf_transform.RotateAboutZAxis( -45.0); // cancel out the corner 45-degree rotation of the parent. rotated_leaf_transform.Translate(50.0, 50.0); rotated_leaf_transform.RotateAboutZAxis(45.0); rotated_leaf_transform.Translate(-50.0, -50.0); position = gfx::PointF(); bounds = gfx::Size(100, 100); SetLayerPropertiesForTesting(rotated_leaf.get(), rotated_leaf_transform, anchor, position, bounds, true, false); rotated_leaf->SetDrawsContent(true); grand_child->AddChild(rotated_leaf.Pass()); child->AddChild(grand_child.Pass()); root->AddChild(child.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. // The grand_child is expected to create a render surface because it // MasksToBounds and is not axis aligned. ASSERT_EQ(2u, render_surface_layer_list.size()); ASSERT_EQ( 1u, render_surface_layer_list.at(0)->render_surface()->layer_list().size()); ASSERT_EQ(789, render_surface_layer_list.at(0)->render_surface()->layer_list().at( 0)->id()); // grand_child's surface. ASSERT_EQ( 1u, render_surface_layer_list.at(1)->render_surface()->layer_list().size()); ASSERT_EQ( 2468, render_surface_layer_list[1]->render_surface()->layer_list().at(0)->id()); // (11, 89) is close to the the bottom left corner within the clip, but it is // not inside the layer. gfx::Point test_point(11, 89); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Closer inwards from the bottom left will overlap the layer. test_point = gfx::Point(25, 75); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(2468, result_layer->id()); // (4, 50) is inside the unclipped layer, but that corner of the layer should // be clipped away by the grandparent and should not get hit. If hit testing // blindly uses visible content rect without considering how parent may clip // the layer, then hit testing would accidentally think that the point // successfully hits the layer. test_point = gfx::Point(4, 50); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // (11, 50) is inside the layer and within the clipped area. test_point = gfx::Point(11, 50); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(2468, result_layer->id()); // Around the middle, just to the right and up, would have hit the layer // except that that area should be clipped away by the parent. test_point = gfx::Point(51, 49); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Around the middle, just to the left and down, should successfully hit the // layer. test_point = gfx::Point(49, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(2468, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForNonClippingIntermediateLayer) { // This test checks that hit testing code does not accidentally clip to layer // bounds for a layer that actually does not clip. gfx::Transform identity_matrix; gfx::PointF anchor; FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, gfx::PointF(), gfx::Size(100, 100), true, false); { scoped_ptr intermediate_layer = LayerImpl::Create(host_impl.active_tree(), 123); // this layer is positioned, and hit testing should correctly know where the // layer is located. gfx::PointF position(10.f, 10.f); gfx::Size bounds(50, 50); SetLayerPropertiesForTesting(intermediate_layer.get(), identity_matrix, anchor, position, bounds, true, false); // Sanity check the intermediate layer should not clip. ASSERT_FALSE(intermediate_layer->masks_to_bounds()); ASSERT_FALSE(intermediate_layer->mask_layer()); // The child of the intermediate_layer is translated so that it does not // overlap intermediate_layer at all. If child is incorrectly clipped, we // would not be able to hit it successfully. scoped_ptr child = LayerImpl::Create(host_impl.active_tree(), 456); position = gfx::PointF(60.f, 60.f); // 70, 70 in screen space bounds = gfx::Size(20, 20); SetLayerPropertiesForTesting(child.get(), identity_matrix, anchor, position, bounds, true, false); child->SetDrawsContent(true); intermediate_layer->AddChild(child.Pass()); root->AddChild(intermediate_layer.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); ASSERT_EQ(456, root->render_surface()->layer_list().at(0)->id()); // Hit testing for a point outside the layer should return a null pointer. gfx::Point test_point(69, 69); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(91, 91); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit testing for a point inside should return the child layer. test_point = gfx::Point(71, 71); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(456, result_layer->id()); test_point = gfx::Point(89, 89); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(456, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForMultipleLayers) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); { // child 1 and child2 are initialized to overlap between x=50 and x=60. // grand_child is set to overlap both child1 and child2 between y=50 and // y=60. The expected stacking order is: (front) child2, (second) // grand_child, (third) child1, and (back) the root layer behind all other // layers. scoped_ptr child1 = LayerImpl::Create(host_impl.active_tree(), 2); scoped_ptr child2 = LayerImpl::Create(host_impl.active_tree(), 3); scoped_ptr grand_child1 = LayerImpl::Create(host_impl.active_tree(), 4); position = gfx::PointF(10.f, 10.f); bounds = gfx::Size(50, 50); SetLayerPropertiesForTesting(child1.get(), identity_matrix, anchor, position, bounds, true, false); child1->SetDrawsContent(true); position = gfx::PointF(50.f, 10.f); bounds = gfx::Size(50, 50); SetLayerPropertiesForTesting(child2.get(), identity_matrix, anchor, position, bounds, true, false); child2->SetDrawsContent(true); // Remember that grand_child is positioned with respect to its parent (i.e. // child1). In screen space, the intended position is (10, 50), with size // 100 x 50. position = gfx::PointF(0.f, 40.f); bounds = gfx::Size(100, 50); SetLayerPropertiesForTesting(grand_child1.get(), identity_matrix, anchor, position, bounds, true, false); grand_child1->SetDrawsContent(true); child1->AddChild(grand_child1.Pass()); root->AddChild(child1.Pass()); root->AddChild(child2.Pass()); } LayerImpl* child1 = root->children()[0]; LayerImpl* child2 = root->children()[1]; LayerImpl* grand_child1 = child1->children()[0]; LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_TRUE(child1); ASSERT_TRUE(child2); ASSERT_TRUE(grand_child1); ASSERT_EQ(1u, render_surface_layer_list.size()); RenderSurfaceImpl* root_render_surface = root->render_surface(); ASSERT_EQ(4u, root_render_surface->layer_list().size()); ASSERT_EQ(1, root_render_surface->layer_list().at(0)->id()); // root layer ASSERT_EQ(2, root_render_surface->layer_list().at(1)->id()); // child1 ASSERT_EQ(4, root_render_surface->layer_list().at(2)->id()); // grand_child1 ASSERT_EQ(3, root_render_surface->layer_list().at(3)->id()); // child2 // Nothing overlaps the root_layer at (1, 1), so hit testing there should find // the root layer. gfx::Point test_point = gfx::Point(1, 1); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(1, result_layer->id()); // At (15, 15), child1 and root are the only layers. child1 is expected to be // on top. test_point = gfx::Point(15, 15); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(2, result_layer->id()); // At (51, 20), child1 and child2 overlap. child2 is expected to be on top. test_point = gfx::Point(51, 20); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(3, result_layer->id()); // At (80, 51), child2 and grand_child1 overlap. child2 is expected to be on // top. test_point = gfx::Point(80, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(3, result_layer->id()); // At (51, 51), all layers overlap each other. child2 is expected to be on top // of all other layers. test_point = gfx::Point(51, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(3, result_layer->id()); // At (20, 51), child1 and grand_child1 overlap. grand_child1 is expected to // be on top. test_point = gfx::Point(20, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(4, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForMultipleLayerLists) { // // The geometry is set up similarly to the previous case, but // all layers are forced to be render surfaces now. // FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); { // child 1 and child2 are initialized to overlap between x=50 and x=60. // grand_child is set to overlap both child1 and child2 between y=50 and // y=60. The expected stacking order is: (front) child2, (second) // grand_child, (third) child1, and (back) the root layer behind all other // layers. scoped_ptr child1 = LayerImpl::Create(host_impl.active_tree(), 2); scoped_ptr child2 = LayerImpl::Create(host_impl.active_tree(), 3); scoped_ptr grand_child1 = LayerImpl::Create(host_impl.active_tree(), 4); position = gfx::PointF(10.f, 10.f); bounds = gfx::Size(50, 50); SetLayerPropertiesForTesting(child1.get(), identity_matrix, anchor, position, bounds, true, false); child1->SetDrawsContent(true); child1->SetForceRenderSurface(true); position = gfx::PointF(50.f, 10.f); bounds = gfx::Size(50, 50); SetLayerPropertiesForTesting(child2.get(), identity_matrix, anchor, position, bounds, true, false); child2->SetDrawsContent(true); child2->SetForceRenderSurface(true); // Remember that grand_child is positioned with respect to its parent (i.e. // child1). In screen space, the intended position is (10, 50), with size // 100 x 50. position = gfx::PointF(0.f, 40.f); bounds = gfx::Size(100, 50); SetLayerPropertiesForTesting(grand_child1.get(), identity_matrix, anchor, position, bounds, true, false); grand_child1->SetDrawsContent(true); grand_child1->SetForceRenderSurface(true); child1->AddChild(grand_child1.Pass()); root->AddChild(child1.Pass()); root->AddChild(child2.Pass()); } LayerImpl* child1 = root->children()[0]; LayerImpl* child2 = root->children()[1]; LayerImpl* grand_child1 = child1->children()[0]; LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_TRUE(child1); ASSERT_TRUE(child2); ASSERT_TRUE(grand_child1); ASSERT_TRUE(child1->render_surface()); ASSERT_TRUE(child2->render_surface()); ASSERT_TRUE(grand_child1->render_surface()); ASSERT_EQ(4u, render_surface_layer_list.size()); // The root surface has the root layer, and child1's and child2's render // surfaces. ASSERT_EQ(3u, root->render_surface()->layer_list().size()); // The child1 surface has the child1 layer and grand_child1's render surface. ASSERT_EQ(2u, child1->render_surface()->layer_list().size()); ASSERT_EQ(1u, child2->render_surface()->layer_list().size()); ASSERT_EQ(1u, grand_child1->render_surface()->layer_list().size()); ASSERT_EQ(1, render_surface_layer_list.at(0)->id()); // root layer ASSERT_EQ(2, render_surface_layer_list[1]->id()); // child1 ASSERT_EQ(4, render_surface_layer_list.at(2)->id()); // grand_child1 ASSERT_EQ(3, render_surface_layer_list[3]->id()); // child2 // Nothing overlaps the root_layer at (1, 1), so hit testing there should find // the root layer. gfx::Point test_point = gfx::Point(1, 1); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(1, result_layer->id()); // At (15, 15), child1 and root are the only layers. child1 is expected to be // on top. test_point = gfx::Point(15, 15); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(2, result_layer->id()); // At (51, 20), child1 and child2 overlap. child2 is expected to be on top. test_point = gfx::Point(51, 20); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(3, result_layer->id()); // At (80, 51), child2 and grand_child1 overlap. child2 is expected to be on // top. test_point = gfx::Point(80, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(3, result_layer->id()); // At (51, 51), all layers overlap each other. child2 is expected to be on top // of all other layers. test_point = gfx::Point(51, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(3, result_layer->id()); // At (20, 51), child1 and grand_child1 overlap. grand_child1 is expected to // be on top. test_point = gfx::Point(20, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(4, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitTestingForEmptyLayers) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); // Layer 1 - root scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); { // Layer 2 - empty: drawsContent=false gfx::PointF position(10.f, 10.f); gfx::Size bounds(30, 30); scoped_ptr empty_layer = LayerImpl::Create(host_impl.active_tree(), 2); SetLayerPropertiesForTesting(empty_layer.get(), identity_matrix, anchor, position, bounds, true, false); empty_layer->SetDrawsContent(false); root->AddChild(empty_layer.Pass()); } { // Layer 3 - empty, but has touch handler gfx::PointF position(10.f, 60.f); gfx::Size bounds(30, 30); scoped_ptr test_layer = LayerImpl::Create(host_impl.active_tree(), 3); SetLayerPropertiesForTesting(test_layer.get(), identity_matrix, anchor, position, bounds, true, false); test_layer->SetDrawsContent(false); Region touch_handler_region(gfx::Rect(10, 10, 10, 10)); test_layer->SetTouchEventHandlerRegion(touch_handler_region); root->AddChild(test_layer.Pass()); } { // Layer 4 - empty, but has mousewheel handler gfx::PointF position(60.f, 60.f); gfx::Size bounds(30, 30); scoped_ptr test_layer = LayerImpl::Create(host_impl.active_tree(), 4); SetLayerPropertiesForTesting(test_layer.get(), identity_matrix, anchor, position, bounds, true, false); test_layer->SetDrawsContent(false); test_layer->SetHaveWheelEventHandlers(true); root->AddChild(test_layer.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Verify that the root layer and empty layers with touch/wheel handlers // (but not the empty layer without a touch handler) are in the RSSL. ASSERT_EQ(1u, render_surface_layer_list.size()); EXPECT_EQ(1, render_surface_layer_list[0]->id()); ASSERT_EQ(3u, root->render_surface()->layer_list().size()); EXPECT_EQ(1, root->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(3, root->render_surface()->layer_list().at(1)->id()); EXPECT_EQ(4, root->render_surface()->layer_list().at(2)->id()); // Hit testing for a point inside the empty no-handlers layer should return // the root layer. gfx::Point test_point = gfx::Point(15, 15); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(1, result_layer->id()); // Hit testing for a point inside the touch handler layer should return it. test_point = gfx::Point(15, 75); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(3, result_layer->id()); // Hit testing for a point inside the mousewheel layer should return it. test_point = gfx::Point(75, 75); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPoint( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(4, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerRegionsForEmptyLayerList) { // Hit checking on an empty render_surface_layer_list should return a null // pointer. LayerImplList render_surface_layer_list; gfx::Point test_point(0, 0); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(10, 20); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerRegionsForSingleLayer) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform identity_matrix; Region touch_handler_region(gfx::Rect(10, 10, 50, 50)); gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit checking for any point should return a null pointer for a layer without // any touch event handler regions. gfx::Point test_point(11, 11); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); root->SetTouchEventHandlerRegion(touch_handler_region); // Hit checking for a point outside the layer should return a null pointer. test_point = gfx::Point(101, 101); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(-1, -1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the layer, but outside the touch handler // region should return a null pointer. test_point = gfx::Point(1, 1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(99, 99); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the touch event handler region should // return the root layer. test_point = gfx::Point(11, 11); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(59, 59); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerRegionsForUninvertibleTransform) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform uninvertible_transform; uninvertible_transform.matrix().set(0, 0, 0.0); uninvertible_transform.matrix().set(1, 1, 0.0); uninvertible_transform.matrix().set(2, 2, 0.0); uninvertible_transform.matrix().set(3, 3, 0.0); ASSERT_FALSE(uninvertible_transform.IsInvertible()); gfx::Transform identity_matrix; Region touch_handler_region(gfx::Rect(10, 10, 50, 50)); gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), uninvertible_transform, anchor, position, bounds, true, false); root->SetDrawsContent(true); root->SetTouchEventHandlerRegion(touch_handler_region); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); ASSERT_FALSE(root->screen_space_transform().IsInvertible()); // Hit checking any point should not hit the touch handler region on the // layer. If the invertible matrix is accidentally ignored and treated like an // identity, then the hit testing will incorrectly hit the layer when it // shouldn't. gfx::Point test_point(1, 1); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(10, 10); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(10, 30); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(50, 50); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(67, 48); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(99, 99); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(-1, -1); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerRegionsForSinglePositionedLayer) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); gfx::Transform identity_matrix; Region touch_handler_region(gfx::Rect(10, 10, 50, 50)); gfx::PointF anchor; // this layer is positioned, and hit testing should correctly know where the // layer is located. gfx::PointF position(50.f, 50.f); gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); root->SetTouchEventHandlerRegion(touch_handler_region); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit checking for a point outside the layer should return a null pointer. gfx::Point test_point(49, 49); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Even though the layer has a touch handler region containing (101, 101), it // should not be visible there since the root render surface would clamp it. test_point = gfx::Point(101, 101); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the layer, but outside the touch handler // region should return a null pointer. test_point = gfx::Point(51, 51); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the touch event handler region should // return the root layer. test_point = gfx::Point(61, 61); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(99, 99); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerRegionsForSingleLayerWithScaledContents) { // A layer's visible content rect is actually in the layer's content space. // The screen space transform converts from the layer's origin space to screen // space. This test makes sure that hit testing works correctly accounts for // the contents scale. A contents scale that is not 1 effectively forces a // non-identity transform between layer's content space and layer's origin // space. The hit testing code must take this into account. // // To test this, the layer is positioned at (25, 25), and is size (50, 50). If // contents scale is ignored, then hit checking will mis-interpret the visible // content rect as being larger than the actual bounds of the layer. // FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); gfx::Transform identity_matrix; gfx::PointF anchor; SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, gfx::PointF(), gfx::Size(100, 100), true, false); { Region touch_handler_region(gfx::Rect(10, 10, 30, 30)); gfx::PointF position(25.f, 25.f); gfx::Size bounds(50, 50); scoped_ptr test_layer = LayerImpl::Create(host_impl.active_tree(), 12345); SetLayerPropertiesForTesting(test_layer.get(), identity_matrix, anchor, position, bounds, true, false); // override content bounds and contents scale test_layer->SetContentBounds(gfx::Size(100, 100)); test_layer->SetContentsScale(2, 2); test_layer->SetDrawsContent(true); test_layer->SetTouchEventHandlerRegion(touch_handler_region); root->AddChild(test_layer.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. // The visible content rect for test_layer is actually 100x100, even though // its layout size is 50x50, positioned at 25x25. LayerImpl* test_layer = root->children()[0]; EXPECT_RECT_EQ(gfx::Rect(0, 0, 100, 100), test_layer->visible_content_rect()); ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Hit checking for a point outside the layer should return a null pointer // (the root layer does not draw content, so it will not be tested either). gfx::Point test_point(76, 76); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the layer, but outside the touch handler // region should return a null pointer. test_point = gfx::Point(26, 26); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(34, 34); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(65, 65); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(74, 74); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the touch event handler region should // return the root layer. test_point = gfx::Point(35, 35); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(64, 64); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerRegionsForSingleLayerWithDeviceScale) { // The layer's device_scale_factor and page_scale_factor should scale the // content rect and we should be able to hit the touch handler region by // scaling the points accordingly. FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); gfx::Transform identity_matrix; gfx::PointF anchor; // Set the bounds of the root layer big enough to fit the child when scaled. SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, gfx::PointF(), gfx::Size(100, 100), true, false); { Region touch_handler_region(gfx::Rect(10, 10, 30, 30)); gfx::PointF position(25.f, 25.f); gfx::Size bounds(50, 50); scoped_ptr test_layer = LayerImpl::Create(host_impl.active_tree(), 12345); SetLayerPropertiesForTesting(test_layer.get(), identity_matrix, anchor, position, bounds, true, false); test_layer->SetDrawsContent(true); test_layer->SetTouchEventHandlerRegion(touch_handler_region); root->AddChild(test_layer.Pass()); } LayerImplList render_surface_layer_list; float device_scale_factor = 3.f; float page_scale_factor = 5.f; gfx::Size scaled_bounds_for_root = gfx::ToCeiledSize( gfx::ScaleSize(root->bounds(), device_scale_factor * page_scale_factor)); LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), scaled_bounds_for_root, &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. // The visible content rect for test_layer is actually 100x100, even though // its layout size is 50x50, positioned at 25x25. LayerImpl* test_layer = root->children()[0]; ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); // Check whether the child layer fits into the root after scaled. EXPECT_RECT_EQ(gfx::Rect(test_layer->content_bounds()), test_layer->visible_content_rect()); // Hit checking for a point outside the layer should return a null pointer // (the root layer does not draw content, so it will not be tested either). gfx::PointF test_point(76.f, 76.f); test_point = gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the layer, but outside the touch handler // region should return a null pointer. test_point = gfx::Point(26, 26); test_point = gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(34, 34); test_point = gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(65, 65); test_point = gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(74, 74); test_point = gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the touch event handler region should // return the root layer. test_point = gfx::Point(35, 35); test_point = gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); test_point = gfx::Point(64, 64); test_point = gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(12345, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerRegionsForSimpleClippedLayer) { // Test that hit-checking will only work for the visible portion of a layer, // and not the entire layer bounds. Here we just test the simple axis-aligned // case. gfx::Transform identity_matrix; gfx::PointF anchor; FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, gfx::PointF(), gfx::Size(100, 100), true, false); { scoped_ptr clipping_layer = LayerImpl::Create(host_impl.active_tree(), 123); // this layer is positioned, and hit testing should correctly know where the // layer is located. gfx::PointF position(25.f, 25.f); gfx::Size bounds(50, 50); SetLayerPropertiesForTesting(clipping_layer.get(), identity_matrix, anchor, position, bounds, true, false); clipping_layer->SetMasksToBounds(true); scoped_ptr child = LayerImpl::Create(host_impl.active_tree(), 456); Region touch_handler_region(gfx::Rect(10, 10, 50, 50)); position = gfx::PointF(-50.f, -50.f); bounds = gfx::Size(300, 300); SetLayerPropertiesForTesting(child.get(), identity_matrix, anchor, position, bounds, true, false); child->SetDrawsContent(true); child->SetTouchEventHandlerRegion(touch_handler_region); clipping_layer->AddChild(child.Pass()); root->AddChild(clipping_layer.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); ASSERT_EQ(456, root->render_surface()->layer_list().at(0)->id()); // Hit checking for a point outside the layer should return a null pointer. // Despite the child layer being very large, it should be clipped to the root // layer's bounds. gfx::Point test_point(24, 24); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the layer, but outside the touch handler // region should return a null pointer. test_point = gfx::Point(35, 35); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(74, 74); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); // Hit checking for a point inside the touch event handler region should // return the root layer. test_point = gfx::Point(25, 25); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(456, result_layer->id()); test_point = gfx::Point(34, 34); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(456, result_layer->id()); } TEST_F(LayerTreeHostCommonTest, HitCheckingTouchHandlerOverlappingRegions) { gfx::Transform identity_matrix; gfx::PointF anchor; FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, gfx::PointF(), gfx::Size(100, 100), true, false); { scoped_ptr touch_layer = LayerImpl::Create(host_impl.active_tree(), 123); // this layer is positioned, and hit testing should correctly know where the // layer is located. gfx::PointF position; gfx::Size bounds(50, 50); SetLayerPropertiesForTesting(touch_layer.get(), identity_matrix, anchor, position, bounds, true, false); touch_layer->SetDrawsContent(true); touch_layer->SetTouchEventHandlerRegion(gfx::Rect(0, 0, 50, 50)); root->AddChild(touch_layer.Pass()); } { scoped_ptr notouch_layer = LayerImpl::Create(host_impl.active_tree(), 1234); // this layer is positioned, and hit testing should correctly know where the // layer is located. gfx::PointF position(0, 25); gfx::Size bounds(50, 50); SetLayerPropertiesForTesting(notouch_layer.get(), identity_matrix, anchor, position, bounds, true, false); notouch_layer->SetDrawsContent(true); root->AddChild(notouch_layer.Pass()); } LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // Sanity check the scenario we just created. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(2u, root->render_surface()->layer_list().size()); ASSERT_EQ(123, root->render_surface()->layer_list().at(0)->id()); ASSERT_EQ(1234, root->render_surface()->layer_list().at(1)->id()); gfx::Point test_point(35, 35); LayerImpl* result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); test_point = gfx::Point(35, 15); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); ASSERT_TRUE(result_layer); EXPECT_EQ(123, result_layer->id()); test_point = gfx::Point(35, 65); result_layer = LayerTreeHostCommon::FindLayerThatIsHitByPointInTouchHandlerRegion( test_point, render_surface_layer_list); EXPECT_FALSE(result_layer); } class NoScaleContentLayer : public ContentLayer { public: static scoped_refptr Create(ContentLayerClient* client) { return make_scoped_refptr(new NoScaleContentLayer(client)); } virtual void CalculateContentsScale(float ideal_contents_scale, float device_scale_factor, float page_scale_factor, bool animating_transform_to_screen, float* contents_scale_x, float* contents_scale_y, gfx::Size* content_bounds) OVERRIDE { // Skip over the ContentLayer to the base Layer class. Layer::CalculateContentsScale(ideal_contents_scale, device_scale_factor, page_scale_factor, animating_transform_to_screen, contents_scale_x, contents_scale_y, content_bounds); } protected: explicit NoScaleContentLayer(ContentLayerClient* client) : ContentLayer(client) {} virtual ~NoScaleContentLayer() {} }; scoped_refptr CreateNoScaleDrawableContentLayer( ContentLayerClient* delegate) { scoped_refptr to_return = NoScaleContentLayer::Create(delegate); to_return->SetIsDrawable(true); return to_return; } TEST_F(LayerTreeHostCommonTest, LayerTransformsInHighDPI) { // Verify draw and screen space transforms of layers not in a surface. MockContentLayerClient delegate; gfx::Transform identity_matrix; scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr child = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); scoped_refptr child_empty = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_empty.get(), identity_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(), false, true); scoped_refptr child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_no_scale.get(), identity_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); parent->AddChild(child); parent->AddChild(child_empty); parent->AddChild(child_no_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); float device_scale_factor = 2.5f; float page_scale_factor = 1.f; RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child_empty); EXPECT_CONTENTS_SCALE_EQ(1, child_no_scale); EXPECT_EQ(1u, render_surface_layer_list.size()); // Verify parent transforms gfx::Transform expected_parent_transform; EXPECT_TRANSFORMATION_MATRIX_EQ(expected_parent_transform, parent->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_parent_transform, parent->draw_transform()); // Verify results of transformed parent rects gfx::RectF parent_content_bounds(parent->content_bounds()); gfx::RectF parent_draw_rect = MathUtil::MapClippedRect(parent->draw_transform(), parent_content_bounds); gfx::RectF parent_screen_space_rect = MathUtil::MapClippedRect( parent->screen_space_transform(), parent_content_bounds); gfx::RectF expected_parent_draw_rect(parent->bounds()); expected_parent_draw_rect.Scale(device_scale_factor); EXPECT_FLOAT_RECT_EQ(expected_parent_draw_rect, parent_draw_rect); EXPECT_FLOAT_RECT_EQ(expected_parent_draw_rect, parent_screen_space_rect); // Verify child and child_empty transforms. They should match. gfx::Transform expected_child_transform; expected_child_transform.Translate( device_scale_factor * child->position().x(), device_scale_factor * child->position().y()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_transform, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_transform, child->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_transform, child_empty->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_transform, child_empty->screen_space_transform()); // Verify results of transformed child and child_empty rects. They should // match. gfx::RectF child_content_bounds(child->content_bounds()); gfx::RectF child_draw_rect = MathUtil::MapClippedRect(child->draw_transform(), child_content_bounds); gfx::RectF child_screen_space_rect = MathUtil::MapClippedRect( child->screen_space_transform(), child_content_bounds); gfx::RectF child_empty_draw_rect = MathUtil::MapClippedRect( child_empty->draw_transform(), child_content_bounds); gfx::RectF child_empty_screen_space_rect = MathUtil::MapClippedRect( child_empty->screen_space_transform(), child_content_bounds); gfx::RectF expected_child_draw_rect(child->position(), child->bounds()); expected_child_draw_rect.Scale(device_scale_factor); EXPECT_FLOAT_RECT_EQ(expected_child_draw_rect, child_draw_rect); EXPECT_FLOAT_RECT_EQ(expected_child_draw_rect, child_screen_space_rect); EXPECT_FLOAT_RECT_EQ(expected_child_draw_rect, child_empty_draw_rect); EXPECT_FLOAT_RECT_EQ(expected_child_draw_rect, child_empty_screen_space_rect); // Verify child_no_scale transforms gfx::Transform expected_child_no_scale_transform = child->draw_transform(); // All transforms operate on content rects. The child's content rect // incorporates device scale, but the child_no_scale does not; add it here. expected_child_no_scale_transform.Scale(device_scale_factor, device_scale_factor); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_no_scale_transform, child_no_scale->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_no_scale_transform, child_no_scale->screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, SurfaceLayerTransformsInHighDPI) { // Verify draw and screen space transforms of layers in a surface. MockContentLayerClient delegate; gfx::Transform identity_matrix; gfx::Transform perspective_matrix; perspective_matrix.ApplyPerspectiveDepth(2.0); gfx::Transform scale_small_matrix; scale_small_matrix.Scale(SK_MScalar1 / 10.f, SK_MScalar1 / 12.f); scoped_refptr root = Layer::Create(); scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr perspective_surface = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(perspective_surface.get(), perspective_matrix * scale_small_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); scoped_refptr scale_surface = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(scale_surface.get(), scale_small_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); perspective_surface->SetForceRenderSurface(true); scale_surface->SetForceRenderSurface(true); parent->AddChild(perspective_surface); parent->AddChild(scale_surface); root->AddChild(parent); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); float device_scale_factor = 2.5f; float page_scale_factor = 3.f; RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), parent->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root; inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, perspective_surface); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, scale_surface); EXPECT_EQ(3u, render_surface_layer_list.size()); gfx::Transform expected_parent_draw_transform; EXPECT_TRANSFORMATION_MATRIX_EQ(expected_parent_draw_transform, parent->draw_transform()); // The scaled surface is rendered at its appropriate scale, and drawn 1:1 // into its target. gfx::Transform expected_scale_surface_draw_transform; expected_scale_surface_draw_transform.Translate( device_scale_factor * page_scale_factor * scale_surface->position().x(), device_scale_factor * page_scale_factor * scale_surface->position().y()); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_scale_surface_draw_transform, scale_surface->render_surface()->draw_transform()); gfx::Transform expected_scale_surface_layer_draw_transform = scale_small_matrix; EXPECT_TRANSFORMATION_MATRIX_EQ(expected_scale_surface_layer_draw_transform, scale_surface->draw_transform()); // The scale for the perspective surface is not known, so it is rendered 1:1 // with the screen, and then scaled during drawing. gfx::Transform expected_perspective_surface_draw_transform; expected_perspective_surface_draw_transform.Translate( device_scale_factor * page_scale_factor * perspective_surface->position().x(), device_scale_factor * page_scale_factor * perspective_surface->position().y()); expected_perspective_surface_draw_transform.PreconcatTransform( perspective_matrix); expected_perspective_surface_draw_transform.PreconcatTransform( scale_small_matrix); gfx::Transform expected_perspective_surface_layer_draw_transform; EXPECT_TRANSFORMATION_MATRIX_EQ( expected_perspective_surface_draw_transform, perspective_surface->render_surface()->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_perspective_surface_layer_draw_transform, perspective_surface->draw_transform()); } TEST_F(LayerTreeHostCommonTest, LayerTransformsInHighDPIAccurateScaleZeroChildPosition) { // Verify draw and screen space transforms of layers not in a surface. MockContentLayerClient delegate; gfx::Transform identity_matrix; scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(133, 133), false, true); scoped_refptr child = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(13, 13), false, true); scoped_refptr child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_no_scale.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(13, 13), false, true); parent->AddChild(child); parent->AddChild(child_no_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); float device_scale_factor = 1.7f; float page_scale_factor = 1.f; RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = parent.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child); EXPECT_CONTENTS_SCALE_EQ(1, child_no_scale); EXPECT_EQ(1u, render_surface_layer_list.size()); // Verify parent transforms gfx::Transform expected_parent_transform; EXPECT_TRANSFORMATION_MATRIX_EQ(expected_parent_transform, parent->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_parent_transform, parent->draw_transform()); // Verify results of transformed parent rects gfx::RectF parent_content_bounds(parent->content_bounds()); gfx::RectF parent_draw_rect = MathUtil::MapClippedRect(parent->draw_transform(), parent_content_bounds); gfx::RectF parent_screen_space_rect = MathUtil::MapClippedRect( parent->screen_space_transform(), parent_content_bounds); gfx::RectF expected_parent_draw_rect(parent->bounds()); expected_parent_draw_rect.Scale(device_scale_factor); expected_parent_draw_rect.set_width(ceil(expected_parent_draw_rect.width())); expected_parent_draw_rect.set_height( ceil(expected_parent_draw_rect.height())); EXPECT_FLOAT_RECT_EQ(expected_parent_draw_rect, parent_draw_rect); EXPECT_FLOAT_RECT_EQ(expected_parent_draw_rect, parent_screen_space_rect); // Verify child transforms gfx::Transform expected_child_transform; EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_transform, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_transform, child->screen_space_transform()); // Verify results of transformed child rects gfx::RectF child_content_bounds(child->content_bounds()); gfx::RectF child_draw_rect = MathUtil::MapClippedRect(child->draw_transform(), child_content_bounds); gfx::RectF child_screen_space_rect = MathUtil::MapClippedRect( child->screen_space_transform(), child_content_bounds); gfx::RectF expected_child_draw_rect(child->bounds()); expected_child_draw_rect.Scale(device_scale_factor); expected_child_draw_rect.set_width(ceil(expected_child_draw_rect.width())); expected_child_draw_rect.set_height(ceil(expected_child_draw_rect.height())); EXPECT_FLOAT_RECT_EQ(expected_child_draw_rect, child_draw_rect); EXPECT_FLOAT_RECT_EQ(expected_child_draw_rect, child_screen_space_rect); // Verify child_no_scale transforms gfx::Transform expected_child_no_scale_transform = child->draw_transform(); // All transforms operate on content rects. The child's content rect // incorporates device scale, but the child_no_scale does not; add it here. expected_child_no_scale_transform.Scale(device_scale_factor, device_scale_factor); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_no_scale_transform, child_no_scale->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_child_no_scale_transform, child_no_scale->screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, ContentsScale) { MockContentLayerClient delegate; gfx::Transform identity_matrix; gfx::Transform parent_scale_matrix; SkMScalar initial_parent_scale = 1.75; parent_scale_matrix.Scale(initial_parent_scale, initial_parent_scale); gfx::Transform child_scale_matrix; SkMScalar initial_child_scale = 1.25; child_scale_matrix.Scale(initial_child_scale, initial_child_scale); scoped_refptr root = Layer::Create(); root->SetBounds(gfx::Size(100, 100)); scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), parent_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); scoped_refptr child_empty = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_empty.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(), false, true); scoped_refptr child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(12.f, 12.f), gfx::Size(10, 10), false, true); root->AddChild(parent); parent->AddChild(child_scale); parent->AddChild(child_empty); parent->AddChild(child_no_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); float device_scale_factor = 2.5f; float page_scale_factor = 1.f; { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_scale); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_empty); EXPECT_CONTENTS_SCALE_EQ(1, child_no_scale); // The parent is scaled up and shouldn't need to scale during draw. The // child that can scale its contents should also not need to scale during // draw. This shouldn't change if the child has empty bounds. The other // children should. EXPECT_FLOAT_EQ(1.0, parent->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(1.0, parent->draw_transform().matrix().get(1, 1)); EXPECT_FLOAT_EQ(1.0, child_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(1.0, child_scale->draw_transform().matrix().get(1, 1)); EXPECT_FLOAT_EQ(1.0, child_empty->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(1.0, child_empty->draw_transform().matrix().get(1, 1)); EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_no_scale->draw_transform().matrix().get(1, 1)); } // If the device_scale_factor or page_scale_factor changes, then it should be // updated using the initial transform as the raster scale. device_scale_factor = 2.25f; page_scale_factor = 1.25f; { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ( device_scale_factor * page_scale_factor * initial_parent_scale, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_scale); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_empty); EXPECT_CONTENTS_SCALE_EQ(1, child_no_scale); } // If the transform changes, we expect the raster scale to be reset to 1.0. SkMScalar second_child_scale = 1.75; child_scale_matrix.Scale(second_child_scale / initial_child_scale, second_child_scale / initial_child_scale); child_scale->SetTransform(child_scale_matrix); child_empty->SetTransform(child_scale_matrix); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child_scale); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child_empty); EXPECT_CONTENTS_SCALE_EQ(1, child_no_scale); } // If the device_scale_factor or page_scale_factor changes, then it should be // updated, but still using 1.0 as the raster scale. device_scale_factor = 2.75f; page_scale_factor = 1.75f; { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child_scale); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child_empty); EXPECT_CONTENTS_SCALE_EQ(1, child_no_scale); } } TEST_F(LayerTreeHostCommonTest, ContentsScale_LayerTransformsDontAffectContentsScale) { MockContentLayerClient delegate; gfx::Transform identity_matrix; gfx::Transform parent_scale_matrix; SkMScalar initial_parent_scale = 1.75; parent_scale_matrix.Scale(initial_parent_scale, initial_parent_scale); gfx::Transform child_scale_matrix; SkMScalar initial_child_scale = 1.25; child_scale_matrix.Scale(initial_child_scale, initial_child_scale); scoped_refptr root = Layer::Create(); root->SetBounds(gfx::Size(100, 100)); scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), parent_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); scoped_refptr child_empty = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_empty.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(), false, true); scoped_refptr child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(12.f, 12.f), gfx::Size(10, 10), false, true); root->AddChild(parent); parent->AddChild(child_scale); parent->AddChild(child_empty); parent->AddChild(child_no_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); RenderSurfaceLayerList render_surface_layer_list; float device_scale_factor = 2.5f; float page_scale_factor = 1.f; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(), LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child_scale); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, child_empty); EXPECT_CONTENTS_SCALE_EQ(1, child_no_scale); // Since the transform scale does not affect contents scale, it should affect // the draw transform instead. EXPECT_FLOAT_EQ(initial_parent_scale, parent->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(initial_parent_scale, parent->draw_transform().matrix().get(1, 1)); EXPECT_FLOAT_EQ(initial_parent_scale * initial_child_scale, child_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(initial_parent_scale * initial_child_scale, child_scale->draw_transform().matrix().get(1, 1)); EXPECT_FLOAT_EQ(initial_parent_scale * initial_child_scale, child_empty->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(initial_parent_scale * initial_child_scale, child_empty->draw_transform().matrix().get(1, 1)); EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, child_no_scale->draw_transform().matrix().get(1, 1)); } TEST_F(LayerTreeHostCommonTest, SmallContentsScale) { MockContentLayerClient delegate; gfx::Transform identity_matrix; gfx::Transform parent_scale_matrix; SkMScalar initial_parent_scale = 1.75; parent_scale_matrix.Scale(initial_parent_scale, initial_parent_scale); gfx::Transform child_scale_matrix; SkMScalar initial_child_scale = 0.25; child_scale_matrix.Scale(initial_child_scale, initial_child_scale); scoped_refptr root = Layer::Create(); root->SetBounds(gfx::Size(100, 100)); scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), parent_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); root->AddChild(parent); parent->AddChild(child_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); float device_scale_factor = 2.5f; float page_scale_factor = 0.01f; { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale, parent); // The child's scale is < 1, so we should not save and use that scale // factor. EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * 1, child_scale); } // When chilld's total scale becomes >= 1, we should save and use that scale // factor. child_scale_matrix.MakeIdentity(); SkMScalar final_child_scale = 0.75; child_scale_matrix.Scale(final_child_scale, final_child_scale); child_scale->SetTransform(child_scale_matrix); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * final_child_scale, child_scale); } } TEST_F(LayerTreeHostCommonTest, ContentsScaleForSurfaces) { MockContentLayerClient delegate; gfx::Transform identity_matrix; gfx::Transform parent_scale_matrix; SkMScalar initial_parent_scale = 2.0; parent_scale_matrix.Scale(initial_parent_scale, initial_parent_scale); gfx::Transform child_scale_matrix; SkMScalar initial_child_scale = 3.0; child_scale_matrix.Scale(initial_child_scale, initial_child_scale); scoped_refptr root = Layer::Create(); root->SetBounds(gfx::Size(100, 100)); scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), parent_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr surface_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); scoped_refptr surface_scale_child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_scale_child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); scoped_refptr surface_scale_child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_scale_child_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); scoped_refptr surface_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(12.f, 12.f), gfx::Size(10, 10), false, true); scoped_refptr surface_no_scale_child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_no_scale_child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); scoped_refptr surface_no_scale_child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_no_scale_child_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); root->AddChild(parent); parent->AddChild(surface_scale); parent->AddChild(surface_no_scale); surface_scale->SetForceRenderSurface(true); surface_scale->AddChild(surface_scale_child_scale); surface_scale->AddChild(surface_scale_child_no_scale); surface_no_scale->SetForceRenderSurface(true); surface_no_scale->AddChild(surface_no_scale_child_scale); surface_no_scale->AddChild(surface_no_scale_child_no_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); SkMScalar device_scale_factor = 5; SkMScalar page_scale_factor = 7; RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ( device_scale_factor * page_scale_factor * initial_parent_scale, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, surface_scale); EXPECT_CONTENTS_SCALE_EQ(1, surface_no_scale); EXPECT_CONTENTS_SCALE_EQ( device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale * initial_child_scale, surface_scale_child_scale); EXPECT_CONTENTS_SCALE_EQ(1, surface_scale_child_no_scale); EXPECT_CONTENTS_SCALE_EQ( device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale * initial_child_scale, surface_no_scale_child_scale); EXPECT_CONTENTS_SCALE_EQ(1, surface_no_scale_child_no_scale); // The parent is scaled up and shouldn't need to scale during draw. EXPECT_FLOAT_EQ(1.0, parent->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(1.0, parent->draw_transform().matrix().get(1, 1)); // RenderSurfaces should always be 1:1 with their target. EXPECT_FLOAT_EQ( 1.0, surface_scale->render_surface()->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( 1.0, surface_scale->render_surface()->draw_transform().matrix().get(1, 1)); // The surface_scale can apply contents scale so the layer shouldn't need to // scale during draw. EXPECT_FLOAT_EQ(1.0, surface_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(1.0, surface_scale->draw_transform().matrix().get(1, 1)); // The surface_scale_child_scale can apply contents scale so it shouldn't need // to scale during draw. EXPECT_FLOAT_EQ( 1.0, surface_scale_child_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( 1.0, surface_scale_child_scale->draw_transform().matrix().get(1, 1)); // The surface_scale_child_no_scale can not apply contents scale, so it needs // to be scaled during draw. EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale * initial_child_scale, surface_scale_child_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale * initial_child_scale, surface_scale_child_no_scale->draw_transform().matrix().get(1, 1)); // RenderSurfaces should always be 1:1 with their target. EXPECT_FLOAT_EQ( 1.0, surface_no_scale->render_surface()->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( 1.0, surface_no_scale->render_surface()->draw_transform().matrix().get(1, 1)); // The surface_no_scale layer can not apply contents scale, so it needs to be // scaled during draw. EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, surface_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale, surface_no_scale->draw_transform().matrix().get(1, 1)); // The surface_scale_child_scale can apply contents scale so it shouldn't need // to scale during draw. EXPECT_FLOAT_EQ( 1.0, surface_no_scale_child_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( 1.0, surface_no_scale_child_scale->draw_transform().matrix().get(1, 1)); // The surface_scale_child_no_scale can not apply contents scale, so it needs // to be scaled during draw. EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale * initial_child_scale, surface_no_scale_child_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_parent_scale * initial_child_scale * initial_child_scale, surface_no_scale_child_no_scale->draw_transform().matrix().get(1, 1)); } TEST_F(LayerTreeHostCommonTest, ContentsScaleForSurfaces_LayerTransformsDontAffectContentsScale) { MockContentLayerClient delegate; gfx::Transform identity_matrix; gfx::Transform parent_scale_matrix; SkMScalar initial_parent_scale = 2.0; parent_scale_matrix.Scale(initial_parent_scale, initial_parent_scale); gfx::Transform child_scale_matrix; SkMScalar initial_child_scale = 3.0; child_scale_matrix.Scale(initial_child_scale, initial_child_scale); scoped_refptr root = Layer::Create(); root->SetBounds(gfx::Size(100, 100)); scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), parent_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr surface_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); scoped_refptr surface_scale_child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_scale_child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); scoped_refptr surface_scale_child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_scale_child_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); scoped_refptr surface_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(12.f, 12.f), gfx::Size(10, 10), false, true); scoped_refptr surface_no_scale_child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_no_scale_child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); scoped_refptr surface_no_scale_child_no_scale = CreateNoScaleDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(surface_no_scale_child_no_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); root->AddChild(parent); parent->AddChild(surface_scale); parent->AddChild(surface_no_scale); surface_scale->SetForceRenderSurface(true); surface_scale->AddChild(surface_scale_child_scale); surface_scale->AddChild(surface_scale_child_no_scale); surface_no_scale->SetForceRenderSurface(true); surface_no_scale->AddChild(surface_no_scale_child_scale); surface_no_scale->AddChild(surface_no_scale_child_no_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); RenderSurfaceLayerList render_surface_layer_list; SkMScalar device_scale_factor = 5.0; SkMScalar page_scale_factor = 7.0; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.page_scale_factor = page_scale_factor; inputs.page_scale_application_layer = root.get(); LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, parent); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, surface_scale); EXPECT_CONTENTS_SCALE_EQ(1.f, surface_no_scale); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, surface_scale_child_scale); EXPECT_CONTENTS_SCALE_EQ(1.f, surface_scale_child_no_scale); EXPECT_CONTENTS_SCALE_EQ(device_scale_factor * page_scale_factor, surface_no_scale_child_scale); EXPECT_CONTENTS_SCALE_EQ(1.f, surface_no_scale_child_no_scale); // The parent is scaled up during draw, since its contents are not scaled by // the transform hierarchy. EXPECT_FLOAT_EQ(initial_parent_scale, parent->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(initial_parent_scale, parent->draw_transform().matrix().get(1, 1)); // The child surface is scaled up during draw since its subtree is not scaled // by the transform hierarchy. EXPECT_FLOAT_EQ( initial_parent_scale * initial_child_scale, surface_scale->render_surface()->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( initial_parent_scale * initial_child_scale, surface_scale->render_surface()->draw_transform().matrix().get(1, 1)); // The surface_scale's RenderSurface is scaled during draw, so the layer does // not need to be scaled when drawing into its surface. EXPECT_FLOAT_EQ(1.0, surface_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(1.0, surface_scale->draw_transform().matrix().get(1, 1)); // The surface_scale_child_scale is scaled when drawing into its surface, // since its content bounds are not scaled by the transform hierarchy. EXPECT_FLOAT_EQ( initial_child_scale, surface_scale_child_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( initial_child_scale, surface_scale_child_scale->draw_transform().matrix().get(1, 1)); // The surface_scale_child_no_scale has a fixed contents scale of 1, so it // needs to be scaled by the device and page scale factors, along with the // transform hierarchy. EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_child_scale, surface_scale_child_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_child_scale, surface_scale_child_no_scale->draw_transform().matrix().get(1, 1)); // The child surface is scaled up during draw since its subtree is not scaled // by the transform hierarchy. EXPECT_FLOAT_EQ( initial_parent_scale * initial_child_scale, surface_no_scale->render_surface()->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( initial_parent_scale * initial_child_scale, surface_no_scale->render_surface()->draw_transform().matrix().get(1, 1)); // The surface_no_scale layer has a fixed contents scale of 1, so it needs to // be scaled by the device and page scale factors. Its surface is already // scaled by the transform hierarchy so those don't need to scale the layer's // drawing. EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor, surface_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ(device_scale_factor * page_scale_factor, surface_no_scale->draw_transform().matrix().get(1, 1)); // The surface_no_scale_child_scale has its contents scaled by the page and // device scale factors, but needs to be scaled by the transform hierarchy // when drawing. EXPECT_FLOAT_EQ( initial_child_scale, surface_no_scale_child_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( initial_child_scale, surface_no_scale_child_scale->draw_transform().matrix().get(1, 1)); // The surface_no_scale_child_no_scale has a fixed contents scale of 1, so it // needs to be scaled by the device and page scale factors. It also needs to // be scaled by any transform heirarchy below its target surface. EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_child_scale, surface_no_scale_child_no_scale->draw_transform().matrix().get(0, 0)); EXPECT_FLOAT_EQ( device_scale_factor * page_scale_factor * initial_child_scale, surface_no_scale_child_no_scale->draw_transform().matrix().get(1, 1)); } TEST_F(LayerTreeHostCommonTest, ContentsScaleForAnimatingLayer) { MockContentLayerClient delegate; gfx::Transform identity_matrix; gfx::Transform parent_scale_matrix; SkMScalar initial_parent_scale = 1.75; parent_scale_matrix.Scale(initial_parent_scale, initial_parent_scale); gfx::Transform child_scale_matrix; SkMScalar initial_child_scale = 1.25; child_scale_matrix.Scale(initial_child_scale, initial_child_scale); scoped_refptr root = Layer::Create(); root->SetBounds(gfx::Size(100, 100)); scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), parent_scale_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), false, true); scoped_refptr child_scale = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child_scale.get(), child_scale_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); root->AddChild(parent); parent->AddChild(child_scale); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // Now put an animating transform on child. int animation_id = AddAnimatedTransformToController( child_scale->layer_animation_controller(), 10.0, 30, 0); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(initial_parent_scale, parent); // The layers with animating transforms should not compute a contents scale // other than 1 until they finish animating. EXPECT_CONTENTS_SCALE_EQ(1, child_scale); } // Remove the animation, now it can save a raster scale. child_scale->layer_animation_controller()->RemoveAnimation(animation_id); { RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_CONTENTS_SCALE_EQ(initial_parent_scale, parent); // The layers with animating transforms should not compute a contents scale // other than 1 until they finish animating. EXPECT_CONTENTS_SCALE_EQ(initial_parent_scale * initial_child_scale, child_scale); } } TEST_F(LayerTreeHostCommonTest, ChangeInContentBoundsOrScaleTriggersPushProperties) { MockContentLayerClient delegate; scoped_refptr root = Layer::Create(); scoped_refptr child = CreateDrawableContentLayer(&delegate); root->AddChild(child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); root->reset_needs_push_properties_for_testing(); child->reset_needs_push_properties_for_testing(); // This will change both layers' content bounds. ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->needs_push_properties()); EXPECT_TRUE(child->needs_push_properties()); root->reset_needs_push_properties_for_testing(); child->reset_needs_push_properties_for_testing(); // This will change only the child layer's contents scale and content bounds, // since the root layer is not a ContentsScalingLayer. ExecuteCalculateDrawProperties(root.get(), 2.f); EXPECT_FALSE(root->needs_push_properties()); EXPECT_TRUE(child->needs_push_properties()); root->reset_needs_push_properties_for_testing(); child->reset_needs_push_properties_for_testing(); // This will not change either layer's contents scale or content bounds. ExecuteCalculateDrawProperties(root.get(), 2.f); EXPECT_FALSE(root->needs_push_properties()); EXPECT_FALSE(child->needs_push_properties()); } TEST_F(LayerTreeHostCommonTest, RenderSurfaceTransformsInHighDPI) { MockContentLayerClient delegate; gfx::Transform identity_matrix; scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), false, true); scoped_refptr child = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); gfx::Transform replica_transform; replica_transform.Scale(1.0, -1.0); scoped_refptr replica = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(replica.get(), replica_transform, gfx::PointF(), gfx::PointF(2.f, 2.f), gfx::Size(10, 10), false, true); // This layer should end up in the same surface as child, with the same draw // and screen space transforms. scoped_refptr duplicate_child_non_owner = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(duplicate_child_non_owner.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), false, true); parent->AddChild(child); child->AddChild(duplicate_child_non_owner); child->SetReplicaLayer(replica.get()); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); RenderSurfaceLayerList render_surface_layer_list; float device_scale_factor = 1.5f; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have two render surfaces. The root's render surface and child's // render surface (it needs one because it has a replica layer). EXPECT_EQ(2u, render_surface_layer_list.size()); gfx::Transform expected_parent_transform; EXPECT_TRANSFORMATION_MATRIX_EQ(expected_parent_transform, parent->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_parent_transform, parent->draw_transform()); gfx::Transform expected_draw_transform; EXPECT_TRANSFORMATION_MATRIX_EQ(expected_draw_transform, child->draw_transform()); gfx::Transform expected_screen_space_transform; expected_screen_space_transform.Translate( device_scale_factor * child->position().x(), device_scale_factor * child->position().y()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_screen_space_transform, child->screen_space_transform()); gfx::Transform expected_duplicate_child_draw_transform = child->draw_transform(); EXPECT_TRANSFORMATION_MATRIX_EQ(child->draw_transform(), duplicate_child_non_owner->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( child->screen_space_transform(), duplicate_child_non_owner->screen_space_transform()); EXPECT_RECT_EQ(child->drawable_content_rect(), duplicate_child_non_owner->drawable_content_rect()); EXPECT_EQ(child->content_bounds(), duplicate_child_non_owner->content_bounds()); gfx::Transform expected_render_surface_draw_transform; expected_render_surface_draw_transform.Translate( device_scale_factor * child->position().x(), device_scale_factor * child->position().y()); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_render_surface_draw_transform, child->render_surface()->draw_transform()); gfx::Transform expected_surface_draw_transform; expected_surface_draw_transform.Translate(device_scale_factor * 2.f, device_scale_factor * 2.f); EXPECT_TRANSFORMATION_MATRIX_EQ(expected_surface_draw_transform, child->render_surface()->draw_transform()); gfx::Transform expected_surface_screen_space_transform; expected_surface_screen_space_transform.Translate(device_scale_factor * 2.f, device_scale_factor * 2.f); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_surface_screen_space_transform, child->render_surface()->screen_space_transform()); gfx::Transform expected_replica_draw_transform; expected_replica_draw_transform.matrix().set(1, 1, -1.0); expected_replica_draw_transform.matrix().set(0, 3, 6.0); expected_replica_draw_transform.matrix().set(1, 3, 6.0); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_replica_draw_transform, child->render_surface()->replica_draw_transform()); gfx::Transform expected_replica_screen_space_transform; expected_replica_screen_space_transform.matrix().set(1, 1, -1.0); expected_replica_screen_space_transform.matrix().set(0, 3, 6.0); expected_replica_screen_space_transform.matrix().set(1, 3, 6.0); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_replica_screen_space_transform, child->render_surface()->replica_screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_replica_screen_space_transform, child->render_surface()->replica_screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, RenderSurfaceTransformsInHighDPIAccurateScaleZeroPosition) { MockContentLayerClient delegate; gfx::Transform identity_matrix; scoped_refptr parent = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(33, 31), false, true); scoped_refptr child = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(13, 11), false, true); gfx::Transform replica_transform; replica_transform.Scale(1.0, -1.0); scoped_refptr replica = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(replica.get(), replica_transform, gfx::PointF(), gfx::PointF(), gfx::Size(13, 11), false, true); // This layer should end up in the same surface as child, with the same draw // and screen space transforms. scoped_refptr duplicate_child_non_owner = CreateDrawableContentLayer(&delegate); SetLayerPropertiesForTesting(duplicate_child_non_owner.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(13, 11), false, true); parent->AddChild(child); child->AddChild(duplicate_child_non_owner); child->SetReplicaLayer(replica.get()); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(parent); float device_scale_factor = 1.7f; RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( parent.get(), parent->bounds(), &render_surface_layer_list); inputs.device_scale_factor = device_scale_factor; inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have two render surfaces. The root's render surface and child's // render surface (it needs one because it has a replica layer). EXPECT_EQ(2u, render_surface_layer_list.size()); gfx::Transform identity_transform; EXPECT_TRANSFORMATION_MATRIX_EQ(identity_transform, parent->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_transform, parent->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_transform, child->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_transform, child->screen_space_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_transform, duplicate_child_non_owner->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( identity_transform, duplicate_child_non_owner->screen_space_transform()); EXPECT_RECT_EQ(child->drawable_content_rect(), duplicate_child_non_owner->drawable_content_rect()); EXPECT_EQ(child->content_bounds(), duplicate_child_non_owner->content_bounds()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_transform, child->render_surface()->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ(identity_transform, child->render_surface()->draw_transform()); EXPECT_TRANSFORMATION_MATRIX_EQ( identity_transform, child->render_surface()->screen_space_transform()); gfx::Transform expected_replica_draw_transform; expected_replica_draw_transform.matrix().set(1, 1, -1.0); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_replica_draw_transform, child->render_surface()->replica_draw_transform()); gfx::Transform expected_replica_screen_space_transform; expected_replica_screen_space_transform.matrix().set(1, 1, -1.0); EXPECT_TRANSFORMATION_MATRIX_EQ( expected_replica_screen_space_transform, child->render_surface()->replica_screen_space_transform()); } TEST_F(LayerTreeHostCommonTest, SubtreeSearch) { scoped_refptr root = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = Layer::Create(); scoped_refptr mask_layer = Layer::Create(); scoped_refptr replica_layer = Layer::Create(); grand_child->SetReplicaLayer(replica_layer.get()); child->AddChild(grand_child.get()); child->SetMaskLayer(mask_layer.get()); root->AddChild(child.get()); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); int nonexistent_id = -1; EXPECT_EQ(root, LayerTreeHostCommon::FindLayerInSubtree(root.get(), root->id())); EXPECT_EQ(child, LayerTreeHostCommon::FindLayerInSubtree(root.get(), child->id())); EXPECT_EQ( grand_child, LayerTreeHostCommon::FindLayerInSubtree(root.get(), grand_child->id())); EXPECT_EQ( mask_layer, LayerTreeHostCommon::FindLayerInSubtree(root.get(), mask_layer->id())); EXPECT_EQ( replica_layer, LayerTreeHostCommon::FindLayerInSubtree(root.get(), replica_layer->id())); EXPECT_EQ( 0, LayerTreeHostCommon::FindLayerInSubtree(root.get(), nonexistent_id)); } TEST_F(LayerTreeHostCommonTest, TransparentChildRenderSurfaceCreation) { scoped_refptr root = Layer::Create(); scoped_refptr child = Layer::Create(); scoped_refptr grand_child = make_scoped_refptr(new LayerWithForcedDrawsContent()); const gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); root->AddChild(child); child->AddChild(grand_child); child->SetOpacity(0.5f); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_FALSE(child->render_surface()); } TEST_F(LayerTreeHostCommonTest, OpacityAnimatingOnPendingTree) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); scoped_ptr root = LayerImpl::Create(host_impl.pending_tree(), 1); const gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(100, 100), true, false); root->SetDrawsContent(true); scoped_ptr child = LayerImpl::Create(host_impl.pending_tree(), 2); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); child->SetDrawsContent(true); child->SetOpacity(0.0f); // Add opacity animation. AddOpacityTransitionToController( child->layer_animation_controller(), 10.0, 0.0f, 1.0f, false); root->AddChild(child.Pass()); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have one render surface and two layers. The child // layer should be included even though it is transparent. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(2u, root->render_surface()->layer_list().size()); } typedef std::tr1::tuple LCDTextTestParam; class LCDTextTest : public LayerTreeHostCommonTestBase, public testing::TestWithParam { protected: virtual void SetUp() { can_use_lcd_text_ = std::tr1::get<0>(GetParam()); root_ = Layer::Create(); child_ = Layer::Create(); grand_child_ = Layer::Create(); child_->AddChild(grand_child_.get()); root_->AddChild(child_.get()); gfx::Transform identity_matrix; SetLayerPropertiesForTesting(root_.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 1), true, false); SetLayerPropertiesForTesting(child_.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 1), true, false); SetLayerPropertiesForTesting(grand_child_.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(1, 1), true, false); child_->SetForceRenderSurface(std::tr1::get<1>(GetParam())); host_ = FakeLayerTreeHost::Create(); host_->SetRootLayer(root_); } bool can_use_lcd_text_; scoped_ptr host_; scoped_refptr root_; scoped_refptr child_; scoped_refptr grand_child_; }; TEST_P(LCDTextTest, CanUseLCDText) { // Case 1: Identity transform. gfx::Transform identity_matrix; ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, child_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, grand_child_->can_use_lcd_text()); // Case 2: Integral translation. gfx::Transform integral_translation; integral_translation.Translate(1.0, 2.0); child_->SetTransform(integral_translation); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, child_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, grand_child_->can_use_lcd_text()); // Case 3: Non-integral translation. gfx::Transform non_integral_translation; non_integral_translation.Translate(1.5, 2.5); child_->SetTransform(non_integral_translation); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_FALSE(child_->can_use_lcd_text()); EXPECT_FALSE(grand_child_->can_use_lcd_text()); // Case 4: Rotation. gfx::Transform rotation; rotation.Rotate(10.0); child_->SetTransform(rotation); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_FALSE(child_->can_use_lcd_text()); EXPECT_FALSE(grand_child_->can_use_lcd_text()); // Case 5: Scale. gfx::Transform scale; scale.Scale(2.0, 2.0); child_->SetTransform(scale); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_FALSE(child_->can_use_lcd_text()); EXPECT_FALSE(grand_child_->can_use_lcd_text()); // Case 6: Skew. gfx::Transform skew; skew.SkewX(10.0); child_->SetTransform(skew); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_FALSE(child_->can_use_lcd_text()); EXPECT_FALSE(grand_child_->can_use_lcd_text()); // Case 7: Translucent. child_->SetTransform(identity_matrix); child_->SetOpacity(0.5f); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_FALSE(child_->can_use_lcd_text()); EXPECT_FALSE(grand_child_->can_use_lcd_text()); // Case 8: Sanity check: restore transform and opacity. child_->SetTransform(identity_matrix); child_->SetOpacity(1.f); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, child_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, grand_child_->can_use_lcd_text()); } TEST_P(LCDTextTest, CanUseLCDTextWithAnimation) { // Sanity check: Make sure can_use_lcd_text_ is set on each node. ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, child_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, grand_child_->can_use_lcd_text()); // Add opacity animation. child_->SetOpacity(0.9f); AddOpacityTransitionToController( child_->layer_animation_controller(), 10.0, 0.9f, 0.1f, false); ExecuteCalculateDrawProperties( root_.get(), 1.f, 1.f, NULL, can_use_lcd_text_); // Text AA should not be adjusted while animation is active. // Make sure LCD text AA setting remains unchanged. EXPECT_EQ(can_use_lcd_text_, root_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, child_->can_use_lcd_text()); EXPECT_EQ(can_use_lcd_text_, grand_child_->can_use_lcd_text()); } INSTANTIATE_TEST_CASE_P(LayerTreeHostCommonTest, LCDTextTest, testing::Combine(testing::Bool(), testing::Bool())); TEST_F(LayerTreeHostCommonTest, SubtreeHidden_SingleLayer) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); const gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); root->SetIsDrawable(true); scoped_refptr child = Layer::Create(); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); child->SetIsDrawable(true); scoped_refptr grand_child = Layer::Create(); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); grand_child->SetIsDrawable(true); grand_child->SetHideLayerAndSubtree(true); child->AddChild(grand_child); root->AddChild(child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have one render surface and two layers. The grand child has // hidden itself. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(2u, root->render_surface()->layer_list().size()); EXPECT_EQ(root->id(), root->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(child->id(), root->render_surface()->layer_list().at(1)->id()); } TEST_F(LayerTreeHostCommonTest, SubtreeHidden_SingleLayerImpl) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); const gfx::Transform identity_matrix; scoped_ptr root = LayerImpl::Create(host_impl.pending_tree(), 1); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); root->SetDrawsContent(true); scoped_ptr child = LayerImpl::Create(host_impl.pending_tree(), 2); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); child->SetDrawsContent(true); scoped_ptr grand_child = LayerImpl::Create(host_impl.pending_tree(), 3); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); grand_child->SetDrawsContent(true); grand_child->SetHideLayerAndSubtree(true); child->AddChild(grand_child.Pass()); root->AddChild(child.Pass()); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have one render surface and two layers. The grand child has // hidden itself. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(2u, root->render_surface()->layer_list().size()); EXPECT_EQ(1, root->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(2, root->render_surface()->layer_list().at(1)->id()); } TEST_F(LayerTreeHostCommonTest, SubtreeHidden_TwoLayers) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); const gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); root->SetIsDrawable(true); scoped_refptr child = Layer::Create(); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); child->SetIsDrawable(true); child->SetHideLayerAndSubtree(true); scoped_refptr grand_child = Layer::Create(); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); grand_child->SetIsDrawable(true); child->AddChild(grand_child); root->AddChild(child); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have one render surface and one layers. The child has // hidden itself and the grand child. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); EXPECT_EQ(root->id(), root->render_surface()->layer_list().at(0)->id()); } TEST_F(LayerTreeHostCommonTest, SubtreeHidden_TwoLayersImpl) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); const gfx::Transform identity_matrix; scoped_ptr root = LayerImpl::Create(host_impl.pending_tree(), 1); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); root->SetDrawsContent(true); scoped_ptr child = LayerImpl::Create(host_impl.pending_tree(), 2); SetLayerPropertiesForTesting(child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); child->SetDrawsContent(true); child->SetHideLayerAndSubtree(true); scoped_ptr grand_child = LayerImpl::Create(host_impl.pending_tree(), 3); SetLayerPropertiesForTesting(grand_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); grand_child->SetDrawsContent(true); child->AddChild(grand_child.Pass()); root->AddChild(child.Pass()); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have one render surface and one layers. The child has // hidden itself and the grand child. ASSERT_EQ(1u, render_surface_layer_list.size()); ASSERT_EQ(1u, root->render_surface()->layer_list().size()); EXPECT_EQ(1, root->render_surface()->layer_list().at(0)->id()); } void EmptyCopyOutputCallback(scoped_ptr result) {} TEST_F(LayerTreeHostCommonTest, SubtreeHiddenWithCopyRequest) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); const gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); root->SetIsDrawable(true); scoped_refptr copy_grand_parent = Layer::Create(); SetLayerPropertiesForTesting(copy_grand_parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); copy_grand_parent->SetIsDrawable(true); scoped_refptr copy_parent = Layer::Create(); SetLayerPropertiesForTesting(copy_parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); copy_parent->SetIsDrawable(true); copy_parent->SetForceRenderSurface(true); scoped_refptr copy_layer = Layer::Create(); SetLayerPropertiesForTesting(copy_layer.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); copy_layer->SetIsDrawable(true); scoped_refptr copy_child = Layer::Create(); SetLayerPropertiesForTesting(copy_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); copy_child->SetIsDrawable(true); scoped_refptr copy_grand_parent_sibling_before = Layer::Create(); SetLayerPropertiesForTesting(copy_grand_parent_sibling_before.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); copy_grand_parent_sibling_before->SetIsDrawable(true); scoped_refptr copy_grand_parent_sibling_after = Layer::Create(); SetLayerPropertiesForTesting(copy_grand_parent_sibling_after.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); copy_grand_parent_sibling_after->SetIsDrawable(true); copy_layer->AddChild(copy_child); copy_parent->AddChild(copy_layer); copy_grand_parent->AddChild(copy_parent); root->AddChild(copy_grand_parent_sibling_before); root->AddChild(copy_grand_parent); root->AddChild(copy_grand_parent_sibling_after); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); // Hide the copy_grand_parent and its subtree. But make a copy request in that // hidden subtree on copy_layer. copy_grand_parent->SetHideLayerAndSubtree(true); copy_grand_parent_sibling_before->SetHideLayerAndSubtree(true); copy_grand_parent_sibling_after->SetHideLayerAndSubtree(true); copy_layer->RequestCopyOfOutput(CopyOutputRequest::CreateRequest( base::Bind(&EmptyCopyOutputCallback))); EXPECT_TRUE(copy_layer->HasCopyRequest()); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_TRUE(root->draw_properties().layer_or_descendant_has_copy_request); EXPECT_TRUE(copy_grand_parent->draw_properties(). layer_or_descendant_has_copy_request); EXPECT_TRUE(copy_parent->draw_properties(). layer_or_descendant_has_copy_request); EXPECT_TRUE(copy_layer->draw_properties(). layer_or_descendant_has_copy_request); EXPECT_FALSE(copy_child->draw_properties(). layer_or_descendant_has_copy_request); EXPECT_FALSE(copy_grand_parent_sibling_before->draw_properties(). layer_or_descendant_has_copy_request); EXPECT_FALSE(copy_grand_parent_sibling_after->draw_properties(). layer_or_descendant_has_copy_request); // We should have three render surfaces, one for the root, one for the parent // since it owns a surface, and one for the copy_layer. ASSERT_EQ(3u, render_surface_layer_list.size()); EXPECT_EQ(root->id(), render_surface_layer_list.at(0)->id()); EXPECT_EQ(copy_parent->id(), render_surface_layer_list.at(1)->id()); EXPECT_EQ(copy_layer->id(), render_surface_layer_list.at(2)->id()); // The root render surface should have 2 contributing layers. The // copy_grand_parent is hidden along with its siblings, but the copy_parent // will appear since something in its subtree needs to be drawn for a copy // request. ASSERT_EQ(2u, root->render_surface()->layer_list().size()); EXPECT_EQ(root->id(), root->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(copy_parent->id(), root->render_surface()->layer_list().at(1)->id()); // Nothing actually draws into the copy parent, so only the copy_layer will // appear in its list, since it needs to be drawn for the copy request. ASSERT_EQ(1u, copy_parent->render_surface()->layer_list().size()); EXPECT_EQ(copy_layer->id(), copy_parent->render_surface()->layer_list().at(0)->id()); // The copy_layer's render surface should have two contributing layers. ASSERT_EQ(2u, copy_layer->render_surface()->layer_list().size()); EXPECT_EQ(copy_layer->id(), copy_layer->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(copy_child->id(), copy_layer->render_surface()->layer_list().at(1)->id()); } TEST_F(LayerTreeHostCommonTest, ClippedOutCopyRequest) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); const gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); root->SetIsDrawable(true); scoped_refptr copy_parent = Layer::Create(); SetLayerPropertiesForTesting(copy_parent.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(), true, false); copy_parent->SetIsDrawable(true); copy_parent->SetMasksToBounds(true); scoped_refptr copy_layer = Layer::Create(); SetLayerPropertiesForTesting(copy_layer.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); copy_layer->SetIsDrawable(true); scoped_refptr copy_child = Layer::Create(); SetLayerPropertiesForTesting(copy_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); copy_child->SetIsDrawable(true); copy_layer->AddChild(copy_child); copy_parent->AddChild(copy_layer); root->AddChild(copy_parent); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); copy_layer->RequestCopyOfOutput(CopyOutputRequest::CreateRequest( base::Bind(&EmptyCopyOutputCallback))); EXPECT_TRUE(copy_layer->HasCopyRequest()); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // We should have one render surface, as the others are clipped out. ASSERT_EQ(1u, render_surface_layer_list.size()); EXPECT_EQ(root->id(), render_surface_layer_list.at(0)->id()); // The root render surface should only have 1 contributing layer, since the // other layers are empty/clipped away. ASSERT_EQ(1u, root->render_surface()->layer_list().size()); EXPECT_EQ(root->id(), root->render_surface()->layer_list().at(0)->id()); } TEST_F(LayerTreeHostCommonTest, VisibleContentRectInsideSurface) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); const gfx::Transform identity_matrix; scoped_refptr root = Layer::Create(); SetLayerPropertiesForTesting(root.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); root->SetIsDrawable(true); // The surface is moved slightly outside of the viewport. scoped_refptr surface = Layer::Create(); SetLayerPropertiesForTesting(surface.get(), identity_matrix, gfx::PointF(), gfx::PointF(-10, -20), gfx::Size(), true, false); surface->SetForceRenderSurface(true); scoped_refptr surface_child = Layer::Create(); SetLayerPropertiesForTesting(surface_child.get(), identity_matrix, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); surface_child->SetIsDrawable(true); surface->AddChild(surface_child); root->AddChild(surface); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_adjust_raster_scales = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); // The visible_content_rect for the |surface_child| should not be clipped by // the viewport. EXPECT_EQ(gfx::Rect(50, 50).ToString(), surface_child->visible_content_rect().ToString()); } TEST_F(LayerTreeHostCommonTest, TransformedClipParent) { // Ensure that a transform between the layer and its render surface is not a // problem. Constructs the following layer tree. // // root (a render surface) // + render_surface // + clip_parent (scaled) // + intervening_clipping_layer // + clip_child // // The render surface should be resized correctly and the clip child should // inherit the right clip rect. scoped_refptr root = Layer::Create(); scoped_refptr render_surface = Layer::Create(); scoped_refptr clip_parent = Layer::Create(); scoped_refptr intervening = Layer::Create(); scoped_refptr clip_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(render_surface); render_surface->AddChild(clip_parent); clip_parent->AddChild(intervening); intervening->AddChild(clip_child); clip_child->SetClipParent(clip_parent.get()); intervening->SetMasksToBounds(true); clip_parent->SetMasksToBounds(true); render_surface->SetForceRenderSurface(true); gfx::Transform scale_transform; scale_transform.Scale(2, 2); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(render_surface.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(clip_parent.get(), scale_transform, gfx::PointF(), gfx::PointF(1.f, 1.f), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(intervening.get(), identity_transform, gfx::PointF(), gfx::PointF(1.f, 1.f), gfx::Size(5, 5), true, false); SetLayerPropertiesForTesting(clip_child.get(), identity_transform, gfx::PointF(), gfx::PointF(1.f, 1.f), gfx::Size(10, 10), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); ASSERT_TRUE(root->render_surface()); ASSERT_TRUE(render_surface->render_surface()); // Ensure that we've inherited our clip parent's clip and weren't affected // by the intervening clip layer. ASSERT_EQ(gfx::Rect(1, 1, 20, 20).ToString(), clip_parent->clip_rect().ToString()); ASSERT_EQ(clip_parent->clip_rect().ToString(), clip_child->clip_rect().ToString()); ASSERT_EQ(gfx::Rect(3, 3, 10, 10).ToString(), intervening->clip_rect().ToString()); // Ensure that the render surface reports a content rect that has been grown // to accomodate for the clip child. ASSERT_EQ(gfx::Rect(5, 5, 16, 16).ToString(), render_surface->render_surface()->content_rect().ToString()); // The above check implies the two below, but they nicely demonstrate that // we've grown, despite the intervening layer's clip. ASSERT_TRUE(clip_parent->clip_rect().Contains( render_surface->render_surface()->content_rect())); ASSERT_FALSE(intervening->clip_rect().Contains( render_surface->render_surface()->content_rect())); } TEST_F(LayerTreeHostCommonTest, ClipParentWithInterveningRenderSurface) { // Ensure that intervening render surfaces are not a problem in the basic // case. In the following tree, both render surfaces should be resized to // accomodate for the clip child, despite an intervening clip. // // root (a render surface) // + clip_parent (masks to bounds) // + render_surface1 (sets opacity) // + intervening (masks to bounds) // + render_surface2 (also sets opacity) // + clip_child // scoped_refptr root = Layer::Create(); scoped_refptr clip_parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr intervening = Layer::Create(); scoped_refptr render_surface2 = Layer::Create(); scoped_refptr clip_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(clip_parent); clip_parent->AddChild(render_surface1); render_surface1->AddChild(intervening); intervening->AddChild(render_surface2); render_surface2->AddChild(clip_child); clip_child->SetClipParent(clip_parent.get()); intervening->SetMasksToBounds(true); clip_parent->SetMasksToBounds(true); render_surface1->SetForceRenderSurface(true); render_surface2->SetForceRenderSurface(true); gfx::Transform translation_transform; translation_transform.Translate(2, 2); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(clip_parent.get(), translation_transform, gfx::PointF(), gfx::PointF(1.f, 1.f), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(intervening.get(), identity_transform, gfx::PointF(), gfx::PointF(1.f, 1.f), gfx::Size(5, 5), true, false); SetLayerPropertiesForTesting(render_surface2.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(clip_child.get(), identity_transform, gfx::PointF(), gfx::PointF(-10.f, -10.f), gfx::Size(60, 60), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->render_surface()); EXPECT_TRUE(render_surface1->render_surface()); EXPECT_TRUE(render_surface2->render_surface()); // Since the render surfaces could have expanded, they should not clip (their // bounds would no longer be reliable). We should resort to layer clipping // in this case. EXPECT_EQ(gfx::Rect(0, 0, 0, 0).ToString(), render_surface1->render_surface()->clip_rect().ToString()); EXPECT_FALSE(render_surface1->render_surface()->is_clipped()); EXPECT_EQ(gfx::Rect(0, 0, 0, 0).ToString(), render_surface2->render_surface()->clip_rect().ToString()); EXPECT_FALSE(render_surface2->render_surface()->is_clipped()); // NB: clip rects are in target space. EXPECT_EQ(gfx::Rect(0, 0, 40, 40).ToString(), render_surface1->clip_rect().ToString()); EXPECT_TRUE(render_surface1->is_clipped()); // This value is inherited from the clipping ancestor layer, 'intervening'. EXPECT_EQ(gfx::Rect(0, 0, 5, 5).ToString(), render_surface2->clip_rect().ToString()); EXPECT_TRUE(render_surface2->is_clipped()); // The content rects of both render surfaces should both have expanded to // contain the clip child. EXPECT_EQ(gfx::Rect(0, 0, 40, 40).ToString(), render_surface1->render_surface()->content_rect().ToString()); EXPECT_EQ(gfx::Rect(-1, -1, 40, 40).ToString(), render_surface2->render_surface()->content_rect().ToString()); // The clip child should have inherited the clip parent's clip (projected to // the right space, of course), and should have the correctly sized visible // content rect. EXPECT_EQ(gfx::Rect(-1, -1, 40, 40).ToString(), clip_child->clip_rect().ToString()); EXPECT_EQ(gfx::Rect(9, 9, 40, 40).ToString(), clip_child->visible_content_rect().ToString()); EXPECT_TRUE(clip_child->is_clipped()); } TEST_F(LayerTreeHostCommonTest, ClipParentScrolledInterveningLayer) { // Ensure that intervening render surfaces are not a problem, even if there // is a scroll involved. Note, we do _not_ have to consider any other sort // of transform. // // root (a render surface) // + clip_parent (masks to bounds) // + render_surface1 (sets opacity) // + intervening (masks to bounds AND scrolls) // + render_surface2 (also sets opacity) // + clip_child // scoped_refptr root = Layer::Create(); scoped_refptr clip_parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr intervening = Layer::Create(); scoped_refptr render_surface2 = Layer::Create(); scoped_refptr clip_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(clip_parent); clip_parent->AddChild(render_surface1); render_surface1->AddChild(intervening); intervening->AddChild(render_surface2); render_surface2->AddChild(clip_child); clip_child->SetClipParent(clip_parent.get()); intervening->SetMasksToBounds(true); clip_parent->SetMasksToBounds(true); intervening->SetScrollClipLayerId(clip_parent->id()); intervening->SetScrollOffset(gfx::Vector2d(3, 3)); render_surface1->SetForceRenderSurface(true); render_surface2->SetForceRenderSurface(true); gfx::Transform translation_transform; translation_transform.Translate(2, 2); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(clip_parent.get(), translation_transform, gfx::PointF(), gfx::PointF(1.f, 1.f), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(intervening.get(), identity_transform, gfx::PointF(), gfx::PointF(1.f, 1.f), gfx::Size(5, 5), true, false); SetLayerPropertiesForTesting(render_surface2.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(clip_child.get(), identity_transform, gfx::PointF(), gfx::PointF(-10.f, -10.f), gfx::Size(60, 60), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->render_surface()); EXPECT_TRUE(render_surface1->render_surface()); EXPECT_TRUE(render_surface2->render_surface()); // Since the render surfaces could have expanded, they should not clip (their // bounds would no longer be reliable). We should resort to layer clipping // in this case. EXPECT_EQ(gfx::Rect(0, 0, 0, 0).ToString(), render_surface1->render_surface()->clip_rect().ToString()); EXPECT_FALSE(render_surface1->render_surface()->is_clipped()); EXPECT_EQ(gfx::Rect(0, 0, 0, 0).ToString(), render_surface2->render_surface()->clip_rect().ToString()); EXPECT_FALSE(render_surface2->render_surface()->is_clipped()); // NB: clip rects are in target space. EXPECT_EQ(gfx::Rect(0, 0, 40, 40).ToString(), render_surface1->clip_rect().ToString()); EXPECT_TRUE(render_surface1->is_clipped()); // This value is inherited from the clipping ancestor layer, 'intervening'. EXPECT_EQ(gfx::Rect(2, 2, 3, 3).ToString(), render_surface2->clip_rect().ToString()); EXPECT_TRUE(render_surface2->is_clipped()); // The content rects of both render surfaces should both have expanded to // contain the clip child. EXPECT_EQ(gfx::Rect(0, 0, 40, 40).ToString(), render_surface1->render_surface()->content_rect().ToString()); EXPECT_EQ(gfx::Rect(2, 2, 40, 40).ToString(), render_surface2->render_surface()->content_rect().ToString()); // The clip child should have inherited the clip parent's clip (projected to // the right space, of course), and should have the correctly sized visible // content rect. EXPECT_EQ(gfx::Rect(2, 2, 40, 40).ToString(), clip_child->clip_rect().ToString()); EXPECT_EQ(gfx::Rect(12, 12, 40, 40).ToString(), clip_child->visible_content_rect().ToString()); EXPECT_TRUE(clip_child->is_clipped()); } TEST_F(LayerTreeHostCommonTest, DescendantsOfClipChildren) { // Ensures that descendants of the clip child inherit the correct clip. // // root (a render surface) // + clip_parent (masks to bounds) // + intervening (masks to bounds) // + clip_child // + child // scoped_refptr root = Layer::Create(); scoped_refptr clip_parent = Layer::Create(); scoped_refptr intervening = Layer::Create(); scoped_refptr clip_child = Layer::Create(); scoped_refptr child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(clip_parent); clip_parent->AddChild(intervening); intervening->AddChild(clip_child); clip_child->AddChild(child); clip_child->SetClipParent(clip_parent.get()); intervening->SetMasksToBounds(true); clip_parent->SetMasksToBounds(true); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(clip_parent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(intervening.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(5, 5), true, false); SetLayerPropertiesForTesting(clip_child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(60, 60), true, false); SetLayerPropertiesForTesting(child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(60, 60), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->render_surface()); // Neither the clip child nor its descendant should have inherited the clip // from |intervening|. EXPECT_EQ(gfx::Rect(0, 0, 40, 40).ToString(), clip_child->clip_rect().ToString()); EXPECT_TRUE(clip_child->is_clipped()); EXPECT_EQ(gfx::Rect(0, 0, 40, 40).ToString(), child->visible_content_rect().ToString()); EXPECT_TRUE(child->is_clipped()); } TEST_F(LayerTreeHostCommonTest, SurfacesShouldBeUnaffectedByNonDescendantClipChildren) { // Ensures that non-descendant clip children in the tree do not affect // render surfaces. // // root (a render surface) // + clip_parent (masks to bounds) // + render_surface1 // + clip_child // + render_surface2 // + non_clip_child // // In this example render_surface2 should be unaffected by clip_child. scoped_refptr root = Layer::Create(); scoped_refptr clip_parent = Layer::Create(); scoped_refptr render_surface1 = Layer::Create(); scoped_refptr clip_child = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr render_surface2 = Layer::Create(); scoped_refptr non_clip_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(clip_parent); clip_parent->AddChild(render_surface1); render_surface1->AddChild(clip_child); clip_parent->AddChild(render_surface2); render_surface2->AddChild(non_clip_child); clip_child->SetClipParent(clip_parent.get()); clip_parent->SetMasksToBounds(true); render_surface1->SetMasksToBounds(true); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(15, 15), true, false); SetLayerPropertiesForTesting(clip_parent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_transform, gfx::PointF(), gfx::PointF(5, 5), gfx::Size(5, 5), true, false); SetLayerPropertiesForTesting(render_surface2.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(5, 5), true, false); SetLayerPropertiesForTesting(clip_child.get(), identity_transform, gfx::PointF(), gfx::PointF(-1, 1), gfx::Size(10, 10), true, false); SetLayerPropertiesForTesting(non_clip_child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(5, 5), true, false); render_surface1->SetForceRenderSurface(true); render_surface2->SetForceRenderSurface(true); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->render_surface()); EXPECT_TRUE(render_surface1->render_surface()); EXPECT_TRUE(render_surface2->render_surface()); EXPECT_EQ(gfx::Rect(0, 0, 5, 5).ToString(), render_surface1->clip_rect().ToString()); EXPECT_TRUE(render_surface1->is_clipped()); // The render surface should not clip (it has unclipped descendants), instead // it should rely on layer clipping. EXPECT_EQ(gfx::Rect(0, 0, 0, 0).ToString(), render_surface1->render_surface()->clip_rect().ToString()); EXPECT_FALSE(render_surface1->render_surface()->is_clipped()); // That said, it should have grown to accomodate the unclipped descendant. EXPECT_EQ(gfx::Rect(-1, 1, 6, 4).ToString(), render_surface1->render_surface()->content_rect().ToString()); // This render surface should clip. It has no unclipped descendants. EXPECT_EQ(gfx::Rect(0, 0, 5, 5).ToString(), render_surface2->clip_rect().ToString()); EXPECT_TRUE(render_surface2->render_surface()->is_clipped()); // It also shouldn't have grown to accomodate the clip child. EXPECT_EQ(gfx::Rect(0, 0, 5, 5).ToString(), render_surface2->render_surface()->content_rect().ToString()); // Sanity check our num_unclipped_descendants values. EXPECT_EQ(1, render_surface1->num_unclipped_descendants()); EXPECT_EQ(0, render_surface2->num_unclipped_descendants()); } TEST_F(LayerTreeHostCommonTest, CanRenderToSeparateSurface) { FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 12345); scoped_ptr child1 = LayerImpl::Create(host_impl.active_tree(), 123456); scoped_ptr child2 = LayerImpl::Create(host_impl.active_tree(), 1234567); scoped_ptr child3 = LayerImpl::Create(host_impl.active_tree(), 12345678); gfx::Transform identity_matrix; gfx::PointF anchor; gfx::PointF position; gfx::Size bounds(100, 100); SetLayerPropertiesForTesting(root.get(), identity_matrix, anchor, position, bounds, true, false); root->SetDrawsContent(true); // This layer structure normally forces render surface due to preserves3d // behavior. SetLayerPropertiesForTesting(child1.get(), identity_matrix, anchor, position, bounds, false, true); child1->SetDrawsContent(true); SetLayerPropertiesForTesting(child2.get(), identity_matrix, anchor, position, bounds, true, false); child2->SetDrawsContent(true); SetLayerPropertiesForTesting(child3.get(), identity_matrix, anchor, position, bounds, true, false); child3->SetDrawsContent(true); child2->SetIs3dSorted(true); child3->SetIs3dSorted(true); child2->AddChild(child3.Pass()); child1->AddChild(child2.Pass()); root->AddChild(child1.Pass()); { LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_render_to_separate_surface = true; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_EQ(2u, render_surface_layer_list.size()); } { LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); inputs.can_render_to_separate_surface = false; LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_EQ(1u, render_surface_layer_list.size()); } } TEST_F(LayerTreeHostCommonTest, DoNotIncludeBackfaceInvisibleSurfaces) { scoped_refptr root = Layer::Create(); scoped_refptr render_surface = Layer::Create(); scoped_refptr child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(render_surface); render_surface->AddChild(child); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(render_surface.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), false, true); SetLayerPropertiesForTesting(child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); root->SetShouldFlattenTransform(false); root->SetIs3dSorted(true); render_surface->SetDoubleSided(false); render_surface->SetForceRenderSurface(true); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_EQ(2u, render_surface_layer_list()->size()); EXPECT_EQ(1u, render_surface_layer_list()->at(0) ->render_surface()->layer_list().size()); EXPECT_EQ(1u, render_surface_layer_list()->at(1) ->render_surface()->layer_list().size()); gfx::Transform rotation_transform = identity_transform; rotation_transform.RotateAboutXAxis(180.0); render_surface->SetTransform(rotation_transform); ExecuteCalculateDrawProperties(root.get()); EXPECT_EQ(1u, render_surface_layer_list()->size()); EXPECT_EQ(0u, render_surface_layer_list()->at(0) ->render_surface()->layer_list().size()); } TEST_F(LayerTreeHostCommonTest, ClippedByScrollParent) { // Checks that the simple case (being clipped by a scroll parent that would // have been processed before you anyhow) results in the right clips. // // + root // + scroll_parent_border // | + scroll_parent_clip // | + scroll_parent // + scroll_child // scoped_refptr root = Layer::Create(); scoped_refptr scroll_parent_border = Layer::Create(); scoped_refptr scroll_parent_clip = Layer::Create(); scoped_refptr scroll_parent = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr scroll_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(scroll_child); root->AddChild(scroll_parent_border); scroll_parent_border->AddChild(scroll_parent_clip); scroll_parent_clip->AddChild(scroll_parent); scroll_parent_clip->SetMasksToBounds(true); scroll_child->SetScrollParent(scroll_parent.get()); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_parent_border.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroll_parent_clip.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); SetLayerPropertiesForTesting(scroll_parent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->render_surface()); EXPECT_EQ(gfx::Rect(0, 0, 30, 30).ToString(), scroll_child->clip_rect().ToString()); EXPECT_TRUE(scroll_child->is_clipped()); } TEST_F(LayerTreeHostCommonTest, ClippedByOutOfOrderScrollParent) { // Checks that clipping by a scroll parent that follows you in paint order // still results in correct clipping. // // + root // + scroll_child // + scroll_parent_border // + scroll_parent_clip // + scroll_parent // scoped_refptr root = Layer::Create(); scoped_refptr scroll_parent_border = Layer::Create(); scoped_refptr scroll_parent_clip = Layer::Create(); scoped_refptr scroll_parent = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr scroll_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(scroll_parent_border); scroll_parent_border->AddChild(scroll_parent_clip); scroll_parent_clip->AddChild(scroll_parent); root->AddChild(scroll_child); scroll_parent_clip->SetMasksToBounds(true); scroll_child->SetScrollParent(scroll_parent.get()); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_parent_border.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroll_parent_clip.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); SetLayerPropertiesForTesting(scroll_parent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->render_surface()); EXPECT_EQ(gfx::Rect(0, 0, 30, 30).ToString(), scroll_child->clip_rect().ToString()); EXPECT_TRUE(scroll_child->is_clipped()); } TEST_F(LayerTreeHostCommonTest, ClippedByOutOfOrderScrollGrandparent) { // Checks that clipping by a scroll parent and scroll grandparent that follow // you in paint order still results in correct clipping. // // + root // + scroll_child // + scroll_parent_border // | + scroll_parent_clip // | + scroll_parent // + scroll_grandparent_border // + scroll_grandparent_clip // + scroll_grandparent // scoped_refptr root = Layer::Create(); scoped_refptr scroll_parent_border = Layer::Create(); scoped_refptr scroll_parent_clip = Layer::Create(); scoped_refptr scroll_parent = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr scroll_grandparent_border = Layer::Create(); scoped_refptr scroll_grandparent_clip = Layer::Create(); scoped_refptr scroll_grandparent = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr scroll_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(scroll_child); root->AddChild(scroll_parent_border); scroll_parent_border->AddChild(scroll_parent_clip); scroll_parent_clip->AddChild(scroll_parent); root->AddChild(scroll_grandparent_border); scroll_grandparent_border->AddChild(scroll_grandparent_clip); scroll_grandparent_clip->AddChild(scroll_grandparent); scroll_parent_clip->SetMasksToBounds(true); scroll_grandparent_clip->SetMasksToBounds(true); scroll_child->SetScrollParent(scroll_parent.get()); scroll_parent_border->SetScrollParent(scroll_grandparent.get()); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_grandparent_border.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroll_grandparent_clip.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); SetLayerPropertiesForTesting(scroll_grandparent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_parent_border.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroll_parent_clip.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); SetLayerPropertiesForTesting(scroll_parent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); ExecuteCalculateDrawProperties(root.get()); EXPECT_TRUE(root->render_surface()); EXPECT_EQ(gfx::Rect(0, 0, 20, 20).ToString(), scroll_child->clip_rect().ToString()); EXPECT_TRUE(scroll_child->is_clipped()); // Despite the fact that we visited the above layers out of order to get the // correct clip, the layer lists should be unaffected. EXPECT_EQ(3u, root->render_surface()->layer_list().size()); EXPECT_EQ(scroll_child.get(), root->render_surface()->layer_list().at(0)); EXPECT_EQ(scroll_parent.get(), root->render_surface()->layer_list().at(1)); EXPECT_EQ(scroll_grandparent.get(), root->render_surface()->layer_list().at(2)); } TEST_F(LayerTreeHostCommonTest, OutOfOrderClippingRequiresRSLLSorting) { // Ensures that even if we visit layers out of order, we still produce a // correctly ordered render surface layer list. // + root // + scroll_child // + scroll_parent_border // + scroll_parent_clip // + scroll_parent // + render_surface1 // + scroll_grandparent_border // + scroll_grandparent_clip // + scroll_grandparent // + render_surface2 // scoped_refptr root = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr scroll_parent_border = Layer::Create(); scoped_refptr scroll_parent_clip = Layer::Create(); scoped_refptr scroll_parent = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr render_surface1 = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr scroll_grandparent_border = Layer::Create(); scoped_refptr scroll_grandparent_clip = Layer::Create(); scoped_refptr scroll_grandparent = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr render_surface2 = make_scoped_refptr(new LayerWithForcedDrawsContent); scoped_refptr scroll_child = make_scoped_refptr(new LayerWithForcedDrawsContent); root->AddChild(scroll_child); root->AddChild(scroll_parent_border); scroll_parent_border->AddChild(scroll_parent_clip); scroll_parent_clip->AddChild(scroll_parent); scroll_parent->AddChild(render_surface2); root->AddChild(scroll_grandparent_border); scroll_grandparent_border->AddChild(scroll_grandparent_clip); scroll_grandparent_clip->AddChild(scroll_grandparent); scroll_grandparent->AddChild(render_surface1); scroll_parent_clip->SetMasksToBounds(true); scroll_grandparent_clip->SetMasksToBounds(true); scroll_child->SetScrollParent(scroll_parent.get()); scroll_parent_border->SetScrollParent(scroll_grandparent.get()); render_surface1->SetForceRenderSurface(true); render_surface2->SetForceRenderSurface(true); gfx::Transform identity_transform; SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_grandparent_border.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroll_grandparent_clip.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(20, 20), true, false); SetLayerPropertiesForTesting(scroll_grandparent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(render_surface1.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_parent_border.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroll_parent_clip.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); SetLayerPropertiesForTesting(scroll_parent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(render_surface2.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); scoped_ptr host = FakeLayerTreeHost::Create(); host->SetRootLayer(root); RenderSurfaceLayerList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsMainInputsForTesting inputs( root.get(), root->bounds(), identity_transform, &render_surface_layer_list); LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_TRUE(root->render_surface()); EXPECT_EQ(gfx::Rect(0, 0, 20, 20).ToString(), scroll_child->clip_rect().ToString()); EXPECT_TRUE(scroll_child->is_clipped()); // Despite the fact that we had to process the layers out of order to get the // right clip, our render_surface_layer_list's order should be unaffected. EXPECT_EQ(3u, render_surface_layer_list.size()); EXPECT_EQ(root.get(), render_surface_layer_list.at(0)); EXPECT_EQ(render_surface2.get(), render_surface_layer_list.at(1)); EXPECT_EQ(render_surface1.get(), render_surface_layer_list.at(2)); EXPECT_TRUE(render_surface_layer_list.at(0)->render_surface()); EXPECT_TRUE(render_surface_layer_list.at(1)->render_surface()); EXPECT_TRUE(render_surface_layer_list.at(2)->render_surface()); } TEST_F(LayerTreeHostCommonTest, DoNotClobberSorting) { // We rearrange layer list contributions if we have to visit children out of // order, but it should be a 'stable' rearrangement. That is, the layer list // additions for a single layer should not be reordered, though their position // wrt to the contributions due to a sibling may vary. // // + root // + scroll_child // + top_content // + bottom_content // + scroll_parent_border // + scroll_parent_clip // + scroll_parent // FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); scoped_ptr scroll_parent_border = LayerImpl::Create(host_impl.active_tree(), 2); scoped_ptr scroll_parent_clip = LayerImpl::Create(host_impl.active_tree(), 3); scoped_ptr scroll_parent = LayerImpl::Create(host_impl.active_tree(), 4); scoped_ptr scroll_child = LayerImpl::Create(host_impl.active_tree(), 5); scoped_ptr bottom_content = LayerImpl::Create(host_impl.active_tree(), 6); scoped_ptr top_content = LayerImpl::Create(host_impl.active_tree(), 7); scroll_parent_clip->SetMasksToBounds(true); scroll_child->SetScrollParent(scroll_parent.get()); scoped_ptr > scroll_children(new std::set); scroll_children->insert(scroll_child.get()); scroll_parent->SetScrollChildren(scroll_children.release()); scroll_child->SetDrawsContent(true); scroll_parent->SetDrawsContent(true); top_content->SetDrawsContent(true); bottom_content->SetDrawsContent(true); gfx::Transform identity_transform; gfx::Transform top_transform; top_transform.Translate3d(0.0, 0.0, 5.0); gfx::Transform bottom_transform; bottom_transform.Translate3d(0.0, 0.0, 3.0); SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_parent_border.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroll_parent_clip.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); SetLayerPropertiesForTesting(scroll_parent.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(scroll_child.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(top_content.get(), top_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), false, true); SetLayerPropertiesForTesting(bottom_content.get(), bottom_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), false, true); scroll_child->SetShouldFlattenTransform(false); scroll_child->SetIs3dSorted(true); scroll_child->AddChild(top_content.Pass()); scroll_child->AddChild(bottom_content.Pass()); root->AddChild(scroll_child.Pass()); scroll_parent_clip->AddChild(scroll_parent.Pass()); scroll_parent_border->AddChild(scroll_parent_clip.Pass()); root->AddChild(scroll_parent_border.Pass()); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_TRUE(root->render_surface()); // If we don't sort by depth and let the layers get added in the order they // would normally be visited in, then layers 6 and 7 will be out of order. In // other words, although we've had to shift 5, 6, and 7 to appear before 4 // in the list (because of the scroll parent relationship), this should not // have an effect on the the order of 5, 6, and 7 (which had been reordered // due to layer sorting). EXPECT_EQ(4u, root->render_surface()->layer_list().size()); EXPECT_EQ(5, root->render_surface()->layer_list().at(0)->id()); EXPECT_EQ(6, root->render_surface()->layer_list().at(1)->id()); EXPECT_EQ(7, root->render_surface()->layer_list().at(2)->id()); EXPECT_EQ(4, root->render_surface()->layer_list().at(3)->id()); } TEST_F(LayerTreeHostCommonTest, ScrollCompensationWithRounding) { // This test verifies that a scrolling layer that gets snapped to // integer coordinates doesn't move a fixed position child. // // + root // + container // + scroller // + fixed // FakeImplProxy proxy; TestSharedBitmapManager shared_bitmap_manager; FakeLayerTreeHostImpl host_impl(&proxy, &shared_bitmap_manager); host_impl.CreatePendingTree(); scoped_ptr root = LayerImpl::Create(host_impl.active_tree(), 1); scoped_ptr container = LayerImpl::Create(host_impl.active_tree(), 2); LayerImpl* container_layer = container.get(); scoped_ptr scroller = LayerImpl::Create(host_impl.active_tree(), 3); LayerImpl* scroll_layer = scroller.get(); scoped_ptr fixed = LayerImpl::Create(host_impl.active_tree(), 4); LayerImpl* fixed_layer = fixed.get(); container->SetIsContainerForFixedPositionLayers(true); LayerPositionConstraint constraint; constraint.set_is_fixed_position(true); fixed->SetPositionConstraint(constraint); scroller->SetScrollClipLayer(container->id()); gfx::Transform identity_transform; gfx::Transform container_transform; container_transform.Translate3d(10.0, 20.0, 0.0); gfx::Vector2dF container_offset = container_transform.To2dTranslation(); SetLayerPropertiesForTesting(root.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); SetLayerPropertiesForTesting(container.get(), container_transform, gfx::PointF(), gfx::PointF(), gfx::Size(40, 40), true, false); SetLayerPropertiesForTesting(scroller.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(30, 30), true, false); SetLayerPropertiesForTesting(fixed.get(), identity_transform, gfx::PointF(), gfx::PointF(), gfx::Size(50, 50), true, false); scroller->AddChild(fixed.Pass()); container->AddChild(scroller.Pass()); root->AddChild(container.Pass()); // Rounded to integers already. { gfx::Vector2dF scroll_delta(3.0, 5.0); scroll_layer->SetScrollDelta(scroll_delta); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_TRANSFORMATION_MATRIX_EQ( container_layer->draw_properties().screen_space_transform, fixed_layer->draw_properties().screen_space_transform); EXPECT_VECTOR_EQ( fixed_layer->draw_properties().screen_space_transform.To2dTranslation(), container_offset); EXPECT_VECTOR_EQ(scroll_layer->draw_properties() .screen_space_transform.To2dTranslation(), container_offset - scroll_delta); } // Scroll delta requiring rounding. { gfx::Vector2dF scroll_delta(4.1f, 8.1f); scroll_layer->SetScrollDelta(scroll_delta); gfx::Vector2dF rounded_scroll_delta(4.f, 8.f); LayerImplList render_surface_layer_list; LayerTreeHostCommon::CalcDrawPropsImplInputsForTesting inputs( root.get(), root->bounds(), &render_surface_layer_list); LayerTreeHostCommon::CalculateDrawProperties(&inputs); EXPECT_TRANSFORMATION_MATRIX_EQ( container_layer->draw_properties().screen_space_transform, fixed_layer->draw_properties().screen_space_transform); EXPECT_VECTOR_EQ( fixed_layer->draw_properties().screen_space_transform.To2dTranslation(), container_offset); EXPECT_VECTOR_EQ(scroll_layer->draw_properties() .screen_space_transform.To2dTranslation(), container_offset - rounded_scroll_delta); } } } // namespace } // namespace cc