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mojo / mojo-tools / 0bcbd3be16bf4b64ace59181ae6a36289e8eb95d / . / cc / trees / layer_tree_impl_unittest.cc
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// Copyright 2014 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "cc/trees/layer_tree_impl.h"
#include "cc/layers/heads_up_display_layer_impl.h"
#include "cc/layers/layer.h"
#include "cc/layers/solid_color_scrollbar_layer_impl.h"
#include "cc/test/fake_impl_proxy.h"
#include "cc/test/fake_layer_tree_host_impl.h"
#include "cc/test/fake_output_surface.h"
#include "cc/test/geometry_test_utils.h"
#include "cc/test/layer_tree_host_common_test.h"
#include "cc/test/test_shared_bitmap_manager.h"
#include "cc/trees/layer_tree_host_impl.h"
#include "ui/gfx/geometry/size_conversions.h"
namespace cc {
namespace {
class LayerTreeImplTest : public LayerTreeHostCommonTest {
public:
LayerTreeImplTest() {
LayerTreeSettings settings;
settings.layer_transforms_should_scale_layer_contents = true;
settings.scrollbar_show_scale_threshold = 1.1f;
host_impl_.reset(
new FakeLayerTreeHostImpl(settings, &proxy_, &shared_bitmap_manager_));
EXPECT_TRUE(host_impl_->InitializeRenderer(FakeOutputSurface::Create3d()));
}
FakeLayerTreeHostImpl& host_impl() { return *host_impl_; }
LayerImpl* root_layer() { return host_impl_->active_tree()->root_layer(); }
const LayerImplList& RenderSurfaceLayerList() const {
return host_impl_->active_tree()->RenderSurfaceLayerList();
}
private:
TestSharedBitmapManager shared_bitmap_manager_;
FakeImplProxy proxy_;
scoped_ptr<FakeLayerTreeHostImpl> host_impl_;
};
TEST_F(LayerTreeImplTest, HitTestingForSingleLayer) {
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), 12345);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(-1, -1);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Hit testing for a point inside should return the root layer.
test_point = gfx::Point(1, 1);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(99, 99);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingForSingleLayerAndHud) {
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), 12345);
scoped_ptr<HeadsUpDisplayLayerImpl> hud =
HeadsUpDisplayLayerImpl::Create(host_impl().active_tree(), 11111);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
// Create hud and add it as a child of root.
gfx::Size hud_bounds(200, 200);
SetLayerPropertiesForTesting(hud.get(), identity_matrix, transform_origin,
position, hud_bounds, true, false, false);
hud->SetDrawsContent(true);
host_impl().active_tree()->set_hud_layer(hud.get());
root->AddChild(hud.Pass());
host_impl().SetViewportSize(hud_bounds);
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(2u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(-1, -1);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(99, 99);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingForUninvertibleTransform) {
scoped_ptr<LayerImpl> 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::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), uninvertible_transform,
transform_origin, position, bounds, true, false,
true);
root->SetDrawsContent(true);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->render_surface()->layer_list().size());
ASSERT_FALSE(root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(10, 10);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(10, 30);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(50, 50);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(67, 48);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(99, 99);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(-1, -1);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
}
TEST_F(LayerTreeImplTest, HitTestingForSinglePositionedLayer) {
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), 12345);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
// 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, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Hit testing for a point inside should return the root layer.
test_point = gfx::Point(51, 51);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(99, 99);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingForSingleRotatedLayer) {
scoped_ptr<LayerImpl> 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::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), rotation45_degrees_about_center,
transform_origin, position, bounds, true, false,
true);
root->SetDrawsContent(true);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(1, 1);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Hit testing for a point inside should return the root layer.
test_point = gfx::Point(1, 50);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_FALSE(result_layer);
test_point = gfx::Point(-1, 50);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_FALSE(result_layer);
}
TEST_F(LayerTreeImplTest, HitTestingForSinglePerspectiveLayer) {
scoped_ptr<LayerImpl> 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::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(
root.get(), perspective_projection_about_center * translation_by_z,
transform_origin, position, bounds, true, false, true);
root->SetDrawsContent(true);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(76, 76);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Hit testing for a point inside should return the root layer.
test_point = gfx::Point(26, 26);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(74, 74);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest, 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.
//
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
gfx::PointF(), gfx::Size(100, 100), true, false,
true);
{
gfx::PointF position(25.f, 25.f);
gfx::Size bounds(50, 50);
scoped_ptr<LayerImpl> test_layer =
LayerImpl::Create(host_impl().active_tree(), 12345);
SetLayerPropertiesForTesting(test_layer.get(), identity_matrix,
transform_origin, position, bounds, true,
false, 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());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// 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 =
host_impl().active_tree()->root_layer()->children()[0];
EXPECT_EQ(gfx::Rect(0, 0, 100, 100), test_layer->visible_content_rect());
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(24, 24);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(76, 76);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Hit testing for a point inside should return the test layer.
test_point = gfx::Point(26, 26);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(74, 74);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest, 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::Point3F transform_origin;
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
gfx::PointF(), gfx::Size(100, 100), true, false,
true);
{
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, false);
clipping_layer->SetMasksToBounds(true);
scoped_ptr<LayerImpl> 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, transform_origin,
position, bounds, true, false, false);
child->SetDrawsContent(true);
clipping_layer->AddChild(child.Pass());
root->AddChild(clipping_layer.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->render_surface()->layer_list().size());
ASSERT_EQ(456, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Hit testing for a point inside should return the child layer.
test_point = gfx::Point(26, 26);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(456, result_layer->id());
test_point = gfx::Point(74, 74);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(456, result_layer->id());
}
TEST_F(LayerTreeImplTest, 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.
//
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), 123);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetMasksToBounds(true);
{
scoped_ptr<LayerImpl> child =
LayerImpl::Create(host_impl().active_tree(), 456);
scoped_ptr<LayerImpl> grand_child =
LayerImpl::Create(host_impl().active_tree(), 789);
scoped_ptr<LayerImpl> 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, transform_origin,
position, bounds, true, false, 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, transform_origin,
position, bounds, true, false, 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,
transform_origin, position, bounds, true,
false, false);
rotated_leaf->SetDrawsContent(true);
grand_child->AddChild(rotated_leaf.Pass());
child->AddChild(grand_child.Pass());
root->AddChild(child.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// (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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Closer inwards from the bottom left will overlap the layer.
test_point = gfx::Point(25, 75);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// (11, 50) is inside the layer and within the clipped area.
test_point = gfx::Point(11, 50);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(2468, result_layer->id());
}
TEST_F(LayerTreeImplTest, 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::Point3F transform_origin;
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
gfx::PointF(), gfx::Size(100, 100), true, false,
true);
{
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, 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<LayerImpl> 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, transform_origin,
position, bounds, true, false, false);
child->SetDrawsContent(true);
intermediate_layer->AddChild(child.Pass());
root->AddChild(intermediate_layer.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->render_surface()->layer_list().size());
ASSERT_EQ(456, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(91, 91);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
EXPECT_FALSE(result_layer);
// Hit testing for a point inside should return the child layer.
test_point = gfx::Point(71, 71);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(456, result_layer->id());
test_point = gfx::Point(89, 89);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(456, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingForMultipleLayers) {
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
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<LayerImpl> child1 =
LayerImpl::Create(host_impl().active_tree(), 2);
scoped_ptr<LayerImpl> child2 =
LayerImpl::Create(host_impl().active_tree(), 3);
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, false);
child1->SetDrawsContent(true);
position = gfx::PointF(50.f, 10.f);
bounds = gfx::Size(50, 50);
SetLayerPropertiesForTesting(child2.get(), identity_matrix,
transform_origin, position, bounds, true,
false, 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,
transform_origin, position, bounds, true,
false, 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];
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_TRUE(child1);
ASSERT_TRUE(child2);
ASSERT_TRUE(grand_child1);
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
RenderSurfaceImpl* root_render_surface = root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(4, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingForMultipleLayersAtVaryingDepths) {
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
root->SetShouldFlattenTransform(false);
root->Set3dSortingContextId(1);
{
// 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<LayerImpl> child1 =
LayerImpl::Create(host_impl().active_tree(), 2);
scoped_ptr<LayerImpl> child2 =
LayerImpl::Create(host_impl().active_tree(), 3);
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, false);
child1->SetDrawsContent(true);
child1->SetShouldFlattenTransform(false);
child1->Set3dSortingContextId(1);
position = gfx::PointF(50.f, 10.f);
bounds = gfx::Size(50, 50);
gfx::Transform translate_z;
translate_z.Translate3d(0, 0, -10.f);
SetLayerPropertiesForTesting(child2.get(), translate_z, transform_origin,
position, bounds, true, false, false);
child2->SetDrawsContent(true);
child2->SetShouldFlattenTransform(false);
child2->Set3dSortingContextId(1);
// 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,
transform_origin, position, bounds, true,
false, false);
grand_child1->SetDrawsContent(true);
grand_child1->SetShouldFlattenTransform(false);
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];
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_TRUE(child1);
ASSERT_TRUE(child2);
ASSERT_TRUE(grand_child1);
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
// 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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(2, result_layer->id());
// At (51, 20), child1 and child2 overlap. child2 is expected to be on top.
// (because 3 is transformed to the back).
test_point = gfx::Point(51, 20);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(2, result_layer->id());
// 3 Would have been on top if it hadn't been transformed to the background.
// Make sure that it isn't hit.
test_point = gfx::Point(80, 51);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(4, result_layer->id());
// 3 Would have been on top if it hadn't been transformed to the background.
// Make sure that it isn't hit.
test_point = gfx::Point(51, 51);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(4, 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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(4, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingRespectsClipParents) {
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
{
scoped_ptr<LayerImpl> child =
LayerImpl::Create(host_impl().active_tree(), 2);
scoped_ptr<LayerImpl> grand_child =
LayerImpl::Create(host_impl().active_tree(), 4);
position = gfx::PointF(10.f, 10.f);
bounds = gfx::Size(1, 1);
SetLayerPropertiesForTesting(child.get(), identity_matrix, transform_origin,
position, bounds, true, false, false);
child->SetDrawsContent(true);
child->SetMasksToBounds(true);
position = gfx::PointF(0.f, 40.f);
bounds = gfx::Size(100, 50);
SetLayerPropertiesForTesting(grand_child.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
grand_child->SetDrawsContent(true);
grand_child->SetHasRenderSurface(true);
// This should let |grand_child| "escape" |child|'s clip.
grand_child->SetClipParent(root.get());
child->AddChild(grand_child.Pass());
root->AddChild(child.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
gfx::Point test_point = gfx::Point(12, 52);
LayerImpl* result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(4, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingRespectsScrollParents) {
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
{
scoped_ptr<LayerImpl> child =
LayerImpl::Create(host_impl().active_tree(), 2);
scoped_ptr<LayerImpl> scroll_child =
LayerImpl::Create(host_impl().active_tree(), 3);
scoped_ptr<LayerImpl> grand_child =
LayerImpl::Create(host_impl().active_tree(), 4);
position = gfx::PointF(10.f, 10.f);
bounds = gfx::Size(1, 1);
SetLayerPropertiesForTesting(child.get(), identity_matrix, transform_origin,
position, bounds, true, false, false);
child->SetDrawsContent(true);
child->SetMasksToBounds(true);
position = gfx::PointF();
bounds = gfx::Size(200, 200);
SetLayerPropertiesForTesting(scroll_child.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
scroll_child->SetDrawsContent(true);
// This should cause scroll child and its descendants to be affected by
// |child|'s clip.
scroll_child->SetScrollParent(child.get());
SetLayerPropertiesForTesting(grand_child.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
grand_child->SetDrawsContent(true);
grand_child->SetHasRenderSurface(true);
scroll_child->AddChild(grand_child.Pass());
root->AddChild(scroll_child.Pass());
root->AddChild(child.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
gfx::Point test_point = gfx::Point(12, 52);
LayerImpl* result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
// The |test_point| should have been clipped away by |child|, the scroll
// parent, so the only thing that should be hit is |root|.
ASSERT_TRUE(result_layer);
ASSERT_EQ(1, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitTestingForMultipleLayerLists) {
//
// The geometry is set up similarly to the previous case, but
// all layers are forced to be render surfaces now.
//
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
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<LayerImpl> child1 =
LayerImpl::Create(host_impl().active_tree(), 2);
scoped_ptr<LayerImpl> child2 =
LayerImpl::Create(host_impl().active_tree(), 3);
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, false);
child1->SetDrawsContent(true);
child1->SetHasRenderSurface(true);
position = gfx::PointF(50.f, 10.f);
bounds = gfx::Size(50, 50);
SetLayerPropertiesForTesting(child2.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
child2->SetDrawsContent(true);
child2->SetHasRenderSurface(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,
transform_origin, position, bounds, true,
false, false);
grand_child1->SetDrawsContent(true);
grand_child1->SetHasRenderSurface(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];
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// 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, RenderSurfaceLayerList().size());
// The root surface has the root layer, and child1's and child2's render
// surfaces.
ASSERT_EQ(3u, root_layer()->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, RenderSurfaceLayerList().at(0)->id()); // root layer
ASSERT_EQ(2, RenderSurfaceLayerList()[1]->id()); // child1
ASSERT_EQ(4, RenderSurfaceLayerList().at(2)->id()); // grand_child1
ASSERT_EQ(3, RenderSurfaceLayerList()[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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPoint(test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(4, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitCheckingTouchHandlerRegionsForSingleLayer) {
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), 12345);
gfx::Transform identity_matrix;
Region touch_handler_region(gfx::Rect(10, 10, 50, 50));
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
host_impl().active_tree()->root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(-1, -1);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(99, 99);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(59, 59);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest,
HitCheckingTouchHandlerRegionsForUninvertibleTransform) {
scoped_ptr<LayerImpl> 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::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), uninvertible_transform,
transform_origin, position, bounds, true, false,
true);
root->SetDrawsContent(true);
root->SetTouchEventHandlerRegion(touch_handler_region);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->render_surface()->layer_list().size());
ASSERT_FALSE(root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(10, 10);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(10, 30);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(50, 50);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(67, 48);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(99, 99);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(-1, -1);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
}
TEST_F(LayerTreeImplTest, MakeScrollbarsInvisibleNearMinPageScale) {
const int kThumbThickness = 10;
const int kTrackStart = 0;
const bool kIsLeftSideVerticalScrollbar = false;
const bool kIsOverlayScrollbar = true;
LayerTreeImpl* active_tree = host_impl().active_tree();
scoped_ptr<LayerImpl> scroll_layer = LayerImpl::Create(active_tree, 1);
scoped_ptr<SolidColorScrollbarLayerImpl> vertical_scrollbar_layer =
SolidColorScrollbarLayerImpl::Create(active_tree,
2,
VERTICAL,
kThumbThickness,
kTrackStart,
kIsLeftSideVerticalScrollbar,
kIsOverlayScrollbar);
scoped_ptr<SolidColorScrollbarLayerImpl> horizontal_scrollbar_layer =
SolidColorScrollbarLayerImpl::Create(active_tree,
3,
HORIZONTAL,
kThumbThickness,
kTrackStart,
kIsLeftSideVerticalScrollbar,
kIsOverlayScrollbar);
scoped_ptr<LayerImpl> clip_layer = LayerImpl::Create(active_tree, 4);
scoped_ptr<LayerImpl> page_scale_layer = LayerImpl::Create(active_tree, 5);
scroll_layer->SetScrollClipLayer(clip_layer->id());
LayerImpl* scroll_layer_ptr = scroll_layer.get();
LayerImpl* page_scale_layer_ptr = page_scale_layer.get();
clip_layer->AddChild(page_scale_layer.Pass());
page_scale_layer_ptr->AddChild(scroll_layer.Pass());
vertical_scrollbar_layer->SetScrollLayerAndClipLayerByIds(
scroll_layer_ptr->id(),
clip_layer->id());
horizontal_scrollbar_layer->SetScrollLayerAndClipLayerByIds(
scroll_layer_ptr->id(),
clip_layer->id());
active_tree->PushPageScaleFromMainThread(1.0f, 1.0f, 4.0f);
active_tree->SetViewportLayersFromIds(
Layer::INVALID_ID, // Overscroll
page_scale_layer_ptr->id(),
scroll_layer_ptr->id(),
Layer::INVALID_ID); // Outer Scroll
EXPECT_TRUE(vertical_scrollbar_layer->hide_layer_and_subtree());
EXPECT_TRUE(horizontal_scrollbar_layer->hide_layer_and_subtree());
active_tree->PushPageScaleFromMainThread(1.05f, 1.0f, 4.0f);
EXPECT_TRUE(vertical_scrollbar_layer->hide_layer_and_subtree());
EXPECT_TRUE(horizontal_scrollbar_layer->hide_layer_and_subtree());
active_tree->PushPageScaleFromMainThread(1.1f, 1.0f, 4.0f);
EXPECT_FALSE(vertical_scrollbar_layer->hide_layer_and_subtree());
EXPECT_FALSE(horizontal_scrollbar_layer->hide_layer_and_subtree());
active_tree->PushPageScaleFromMainThread(1.5f, 1.0f, 4.0f);
EXPECT_FALSE(vertical_scrollbar_layer->hide_layer_and_subtree());
EXPECT_FALSE(horizontal_scrollbar_layer->hide_layer_and_subtree());
}
TEST_F(LayerTreeImplTest,
HitCheckingTouchHandlerRegionsForSinglePositionedLayer) {
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), 12345);
gfx::Transform identity_matrix;
Region touch_handler_region(gfx::Rect(10, 10, 50, 50));
gfx::Point3F transform_origin;
// 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, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
root->SetTouchEventHandlerRegion(touch_handler_region);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(99, 99);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest,
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.
//
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
gfx::PointF(), gfx::Size(100, 100), true, false,
true);
{
Region touch_handler_region(gfx::Rect(10, 10, 30, 30));
gfx::PointF position(25.f, 25.f);
gfx::Size bounds(50, 50);
scoped_ptr<LayerImpl> test_layer =
LayerImpl::Create(host_impl().active_tree(), 12345);
SetLayerPropertiesForTesting(test_layer.get(), identity_matrix,
transform_origin, position, bounds, true,
false, 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());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// 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 =
host_impl().active_tree()->root_layer()->children()[0];
EXPECT_EQ(gfx::Rect(0, 0, 100, 100), test_layer->visible_content_rect());
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(34, 34);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(65, 65);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(74, 74);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
test_point = gfx::Point(64, 64);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest,
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.
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
// Set the bounds of the root layer big enough to fit the child when scaled.
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
gfx::PointF(), gfx::Size(100, 100), true, false,
true);
{
Region touch_handler_region(gfx::Rect(10, 10, 30, 30));
gfx::PointF position(25.f, 25.f);
gfx::Size bounds(50, 50);
scoped_ptr<LayerImpl> test_layer =
LayerImpl::Create(host_impl().active_tree(), 12345);
SetLayerPropertiesForTesting(test_layer.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
test_layer->SetDrawsContent(true);
test_layer->SetTouchEventHandlerRegion(touch_handler_region);
root->AddChild(test_layer.Pass());
}
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));
host_impl().SetViewportSize(scaled_bounds_for_root);
host_impl().SetDeviceScaleFactor(device_scale_factor);
host_impl().active_tree()->PushPageScaleFromMainThread(
page_scale_factor, page_scale_factor, page_scale_factor);
host_impl().SetPageScaleOnActiveTree(page_scale_factor);
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().active_tree()->SetViewportLayersFromIds(Layer::INVALID_ID, 1, 1,
Layer::INVALID_ID);
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// 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 =
host_impl().active_tree()->root_layer()->children()[0];
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->render_surface()->layer_list().size());
// Check whether the child layer fits into the root after scaled.
EXPECT_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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(34, 34);
test_point =
gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(65, 65);
test_point =
gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(74, 74);
test_point =
gfx::ScalePoint(test_point, device_scale_factor * page_scale_factor);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(12345, result_layer->id());
}
TEST_F(LayerTreeImplTest, 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::Point3F transform_origin;
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
gfx::PointF(), gfx::Size(100, 100), true, false,
true);
{
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, false);
clipping_layer->SetMasksToBounds(true);
scoped_ptr<LayerImpl> 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, transform_origin,
position, bounds, true, false, false);
child->SetDrawsContent(true);
child->SetTouchEventHandlerRegion(touch_handler_region);
clipping_layer->AddChild(child.Pass());
root->AddChild(clipping_layer.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->render_surface()->layer_list().size());
ASSERT_EQ(456, root_layer()->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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
test_point = gfx::Point(74, 74);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
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 =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(456, result_layer->id());
test_point = gfx::Point(34, 34);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(456, result_layer->id());
}
TEST_F(LayerTreeImplTest, HitCheckingTouchHandlerOverlappingRegions) {
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
gfx::PointF(), gfx::Size(100, 100), true, false,
true);
{
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, false);
touch_layer->SetDrawsContent(true);
touch_layer->SetTouchEventHandlerRegion(gfx::Rect(0, 0, 50, 50));
root->AddChild(touch_layer.Pass());
}
{
scoped_ptr<LayerImpl> 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,
transform_origin, position, bounds, true,
false, false);
notouch_layer->SetDrawsContent(true);
root->AddChild(notouch_layer.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(2u, root_layer()->render_surface()->layer_list().size());
ASSERT_EQ(123, root_layer()->render_surface()->layer_list().at(0)->id());
ASSERT_EQ(1234, root_layer()->render_surface()->layer_list().at(1)->id());
gfx::Point test_point(35, 35);
LayerImpl* result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
// We should have passed through the no-touch layer and found the layer
// behind it.
EXPECT_TRUE(result_layer);
host_impl().active_tree()->LayerById(1234)->SetContentsOpaque(true);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
// Even with an opaque layer in the middle, we should still find the layer
// with
// the touch handler behind it (since we can't assume that opaque layers are
// opaque to hit testing).
EXPECT_TRUE(result_layer);
test_point = gfx::Point(35, 15);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
ASSERT_TRUE(result_layer);
EXPECT_EQ(123, result_layer->id());
test_point = gfx::Point(35, 65);
result_layer =
host_impl().active_tree()->FindLayerThatIsHitByPointInTouchHandlerRegion(
test_point);
EXPECT_FALSE(result_layer);
}
TEST_F(LayerTreeImplTest, SelectionBoundsForSingleLayer) {
int root_layer_id = 12345;
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), root_layer_id);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
root->SetDrawsContent(true);
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
ASSERT_EQ(1u, root_layer()->render_surface()->layer_list().size());
LayerSelectionBound left_input;
left_input.type = SELECTION_BOUND_LEFT;
left_input.edge_top = gfx::PointF(10, 10);
left_input.edge_bottom = gfx::PointF(10, 20);
left_input.layer_id = root_layer_id;
LayerSelectionBound right_input;
right_input.type = SELECTION_BOUND_RIGHT;
right_input.edge_top = gfx::PointF(50, 10);
right_input.edge_bottom = gfx::PointF(50, 30);
right_input.layer_id = root_layer_id;
ViewportSelectionBound left_output, right_output;
// Empty input bounds should produce empty output bounds.
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_EQ(ViewportSelectionBound(), left_output);
EXPECT_EQ(ViewportSelectionBound(), right_output);
// Selection bounds should produce distinct left and right bounds.
host_impl().active_tree()->RegisterSelection(left_input, right_input);
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_EQ(left_input.type, left_output.type);
EXPECT_EQ(left_input.edge_bottom, left_output.edge_bottom);
EXPECT_EQ(left_input.edge_top, left_output.edge_top);
EXPECT_TRUE(left_output.visible);
EXPECT_EQ(right_input.type, right_output.type);
EXPECT_EQ(right_input.edge_bottom, right_output.edge_bottom);
EXPECT_EQ(right_input.edge_top, right_output.edge_top);
EXPECT_TRUE(right_output.visible);
// Insertion bounds should produce identical left and right bounds.
LayerSelectionBound insertion_input;
insertion_input.type = SELECTION_BOUND_CENTER;
insertion_input.edge_top = gfx::PointF(15, 10);
insertion_input.edge_bottom = gfx::PointF(15, 30);
insertion_input.layer_id = root_layer_id;
host_impl().active_tree()->RegisterSelection(insertion_input,
LayerSelectionBound());
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_EQ(insertion_input.type, left_output.type);
EXPECT_EQ(insertion_input.edge_bottom, left_output.edge_bottom);
EXPECT_EQ(insertion_input.edge_top, left_output.edge_top);
EXPECT_TRUE(left_output.visible);
EXPECT_EQ(left_output, right_output);
}
TEST_F(LayerTreeImplTest, SelectionBoundsForPartialOccludedLayers) {
int root_layer_id = 12345;
int clip_layer_id = 1234;
int clipped_layer_id = 123;
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), root_layer_id);
root->SetDrawsContent(true);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
gfx::Vector2dF clipping_offset(10, 10);
{
scoped_ptr<LayerImpl> clipping_layer =
LayerImpl::Create(host_impl().active_tree(), clip_layer_id);
// The clipping layer should occlude the right selection bound.
gfx::PointF position = gfx::PointF() + clipping_offset;
gfx::Size bounds(50, 50);
SetLayerPropertiesForTesting(clipping_layer.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
clipping_layer->SetMasksToBounds(true);
scoped_ptr<LayerImpl> clipped_layer =
LayerImpl::Create(host_impl().active_tree(), clipped_layer_id);
position = gfx::PointF();
bounds = gfx::Size(100, 100);
SetLayerPropertiesForTesting(clipped_layer.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
clipped_layer->SetDrawsContent(true);
clipping_layer->AddChild(clipped_layer.Pass());
root->AddChild(clipping_layer.Pass());
}
host_impl().SetViewportSize(root->bounds());
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
LayerSelectionBound left_input;
left_input.type = SELECTION_BOUND_LEFT;
left_input.edge_top = gfx::PointF(25, 10);
left_input.edge_bottom = gfx::PointF(25, 30);
left_input.layer_id = clipped_layer_id;
LayerSelectionBound right_input;
right_input.type = SELECTION_BOUND_RIGHT;
right_input.edge_top = gfx::PointF(75, 10);
right_input.edge_bottom = gfx::PointF(75, 30);
right_input.layer_id = clipped_layer_id;
host_impl().active_tree()->RegisterSelection(left_input, right_input);
// The left bound should be occluded by the clip layer.
ViewportSelectionBound left_output, right_output;
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_EQ(left_input.type, left_output.type);
gfx::PointF expected_left_output_top = left_input.edge_top;
gfx::PointF expected_left_output_bottom = left_input.edge_bottom;
expected_left_output_top.Offset(clipping_offset.x(), clipping_offset.y());
expected_left_output_bottom.Offset(clipping_offset.x(), clipping_offset.y());
EXPECT_EQ(expected_left_output_top, left_output.edge_top);
EXPECT_EQ(expected_left_output_bottom, left_output.edge_bottom);
EXPECT_TRUE(left_output.visible);
EXPECT_EQ(right_input.type, right_output.type);
gfx::PointF expected_right_output_top = right_input.edge_top;
gfx::PointF expected_right_output_bottom = right_input.edge_bottom;
expected_right_output_bottom.Offset(clipping_offset.x(), clipping_offset.y());
expected_right_output_top.Offset(clipping_offset.x(), clipping_offset.y());
EXPECT_EQ(expected_right_output_top, right_output.edge_top);
EXPECT_EQ(expected_right_output_bottom, right_output.edge_bottom);
EXPECT_FALSE(right_output.visible);
// Handles outside the viewport bounds should be marked invisible.
left_input.edge_top = gfx::PointF(-25, 0);
left_input.edge_bottom = gfx::PointF(-25, 20);
host_impl().active_tree()->RegisterSelection(left_input, right_input);
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_FALSE(left_output.visible);
left_input.edge_top = gfx::PointF(0, -25);
left_input.edge_bottom = gfx::PointF(0, -5);
host_impl().active_tree()->RegisterSelection(left_input, right_input);
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_FALSE(left_output.visible);
// If the handle bottom is partially visible, the handle is marked visible.
left_input.edge_top = gfx::PointF(0, -20);
left_input.edge_bottom = gfx::PointF(0, 1);
host_impl().active_tree()->RegisterSelection(left_input, right_input);
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_TRUE(left_output.visible);
}
TEST_F(LayerTreeImplTest, SelectionBoundsForScaledLayers) {
int root_layer_id = 1;
int sub_layer_id = 2;
scoped_ptr<LayerImpl> root =
LayerImpl::Create(host_impl().active_tree(), root_layer_id);
root->SetDrawsContent(true);
gfx::Transform identity_matrix;
gfx::Point3F transform_origin;
gfx::PointF position;
gfx::Size bounds(100, 100);
SetLayerPropertiesForTesting(root.get(), identity_matrix, transform_origin,
position, bounds, true, false, true);
gfx::Vector2dF sub_layer_offset(10, 0);
{
scoped_ptr<LayerImpl> sub_layer =
LayerImpl::Create(host_impl().active_tree(), sub_layer_id);
gfx::PointF position = gfx::PointF() + sub_layer_offset;
gfx::Size bounds(50, 50);
SetLayerPropertiesForTesting(sub_layer.get(), identity_matrix,
transform_origin, position, bounds, true,
false, false);
sub_layer->SetDrawsContent(true);
root->AddChild(sub_layer.Pass());
}
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));
host_impl().SetViewportSize(scaled_bounds_for_root);
host_impl().SetDeviceScaleFactor(device_scale_factor);
host_impl().active_tree()->PushPageScaleFromMainThread(
page_scale_factor, page_scale_factor, page_scale_factor);
host_impl().SetPageScaleOnActiveTree(page_scale_factor);
host_impl().active_tree()->SetRootLayer(root.Pass());
host_impl().active_tree()->SetViewportLayersFromIds(Layer::INVALID_ID, 1, 1,
Layer::INVALID_ID);
host_impl().UpdateNumChildrenAndDrawPropertiesForActiveTree();
// Sanity check the scenario we just created.
ASSERT_EQ(1u, RenderSurfaceLayerList().size());
LayerSelectionBound left_input;
left_input.type = SELECTION_BOUND_LEFT;
left_input.edge_top = gfx::PointF(10, 10);
left_input.edge_bottom = gfx::PointF(10, 30);
left_input.layer_id = root_layer_id;
LayerSelectionBound right_input;
right_input.type = SELECTION_BOUND_RIGHT;
right_input.edge_top = gfx::PointF(0, 0);
right_input.edge_bottom = gfx::PointF(0, 20);
right_input.layer_id = sub_layer_id;
host_impl().active_tree()->RegisterSelection(left_input, right_input);
// The viewport bounds should be properly scaled by the page scale, but should
// remain in DIP coordinates.
ViewportSelectionBound left_output, right_output;
host_impl().active_tree()->GetViewportSelection(&left_output, &right_output);
EXPECT_EQ(left_input.type, left_output.type);
gfx::PointF expected_left_output_top = left_input.edge_top;
gfx::PointF expected_left_output_bottom = left_input.edge_bottom;
expected_left_output_top.Scale(page_scale_factor);
expected_left_output_bottom.Scale(page_scale_factor);
EXPECT_EQ(left_input.edge_top, left_output.edge_top);
EXPECT_EQ(left_input.edge_bottom, left_output.edge_bottom);
EXPECT_TRUE(left_output.visible);
EXPECT_EQ(right_input.type, right_output.type);
gfx::PointF expected_right_output_top = right_input.edge_top;
gfx::PointF expected_right_output_bottom = right_input.edge_bottom;
expected_right_output_top.Offset(sub_layer_offset.x(), sub_layer_offset.y());
expected_right_output_bottom.Offset(sub_layer_offset.x(),
sub_layer_offset.y());
expected_right_output_top.Scale(page_scale_factor);
expected_right_output_bottom.Scale(page_scale_factor);
EXPECT_EQ(expected_right_output_top, right_output.edge_top);
EXPECT_EQ(expected_right_output_bottom, right_output.edge_bottom);
EXPECT_TRUE(right_output.visible);
}
TEST_F(LayerTreeImplTest, NumLayersTestOne) {
EXPECT_EQ(0u, host_impl().active_tree()->NumLayers());
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
EXPECT_EQ(1u, host_impl().active_tree()->NumLayers());
}
TEST_F(LayerTreeImplTest, NumLayersSmallTree) {
EXPECT_EQ(0u, host_impl().active_tree()->NumLayers());
scoped_ptr<LayerImpl> root = LayerImpl::Create(host_impl().active_tree(), 1);
root->AddChild(LayerImpl::Create(host_impl().active_tree(), 2));
root->AddChild(LayerImpl::Create(host_impl().active_tree(), 3));
root->child_at(1)->AddChild(LayerImpl::Create(host_impl().active_tree(), 4));
EXPECT_EQ(4u, host_impl().active_tree()->NumLayers());
}
} // namespace
} // namespace cc