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// Copyright 2013 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 <stddef.h>
#include <stdint.h>
#include "base/memory/ptr_util.h"
#include "base/run_loop.h"
#include "base/threading/thread_task_runner_handle.h"
#include "cc/playback/raster_source.h"
#include "cc/playback/recording_source.h"
#include "cc/raster/raster_buffer.h"
#include "cc/raster/synchronous_task_graph_runner.h"
#include "cc/resources/resource_pool.h"
#include "cc/test/begin_frame_args_test.h"
#include "cc/test/fake_impl_task_runner_provider.h"
#include "cc/test/fake_layer_tree_host_impl.h"
#include "cc/test/fake_output_surface.h"
#include "cc/test/fake_output_surface_client.h"
#include "cc/test/fake_picture_layer_impl.h"
#include "cc/test/fake_picture_layer_tiling_client.h"
#include "cc/test/fake_raster_source.h"
#include "cc/test/fake_recording_source.h"
#include "cc/test/fake_tile_manager.h"
#include "cc/test/fake_tile_task_manager.h"
#include "cc/test/layer_tree_settings_for_testing.h"
#include "cc/test/test_gpu_memory_buffer_manager.h"
#include "cc/test/test_layer_tree_host_base.h"
#include "cc/test/test_shared_bitmap_manager.h"
#include "cc/test/test_task_graph_runner.h"
#include "cc/test/test_tile_priorities.h"
#include "cc/tiles/eviction_tile_priority_queue.h"
#include "cc/tiles/raster_tile_priority_queue.h"
#include "cc/tiles/tile.h"
#include "cc/tiles/tile_priority.h"
#include "cc/tiles/tiling_set_raster_queue_all.h"
#include "cc/trees/layer_tree_impl.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "third_party/skia/include/core/SkRefCnt.h"
#include "third_party/skia/include/core/SkSurface.h"
namespace cc {
namespace {
class TileManagerTilePriorityQueueTest : public TestLayerTreeHostBase {
public:
LayerTreeSettings CreateSettings() override {
LayerTreeSettingsForTesting settings;
settings.create_low_res_tiling = true;
settings.renderer_settings.buffer_to_texture_target_map =
DefaultBufferToTextureTargetMapForTesting();
return settings;
}
TileManager* tile_manager() { return host_impl()->tile_manager(); }
};
TEST_F(TileManagerTilePriorityQueueTest, RasterTilePriorityQueue) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
size_t tile_count = 0;
std::set<Tile*> all_tiles;
while (!queue->IsEmpty()) {
EXPECT_TRUE(queue->Top().tile());
all_tiles.insert(queue->Top().tile());
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, all_tiles.size());
EXPECT_EQ(16u, tile_count);
// Sanity check, all tiles should be visible.
std::set<Tile*> smoothness_tiles;
queue = host_impl()->BuildRasterQueue(SMOOTHNESS_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::ALL);
bool had_low_res = false;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile());
EXPECT_EQ(TilePriority::NOW, prioritized_tile.priority().priority_bin);
if (prioritized_tile.priority().resolution == LOW_RESOLUTION)
had_low_res = true;
else
smoothness_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(all_tiles, smoothness_tiles);
EXPECT_TRUE(had_low_res);
// Check that everything is required for activation.
queue = host_impl()->BuildRasterQueue(
SMOOTHNESS_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::REQUIRED_FOR_ACTIVATION);
std::set<Tile*> required_for_activation_tiles;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile()->required_for_activation());
required_for_activation_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(all_tiles, required_for_activation_tiles);
// Check that everything is required for draw.
queue = host_impl()->BuildRasterQueue(
SMOOTHNESS_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::REQUIRED_FOR_DRAW);
std::set<Tile*> required_for_draw_tiles;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile()->required_for_draw());
required_for_draw_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(all_tiles, required_for_draw_tiles);
Region invalidation(gfx::Rect(0, 0, 500, 500));
// Invalidate the pending tree.
pending_layer()->set_invalidation(invalidation);
pending_layer()->HighResTiling()->Invalidate(invalidation);
// Renew all of the tile priorities.
gfx::Rect viewport(50, 50, 100, 100);
pending_layer()->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
active_layer()->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
// Populate all tiles directly from the tilings.
all_tiles.clear();
std::set<Tile*> high_res_tiles;
std::vector<Tile*> pending_high_res_tiles =
pending_layer()->HighResTiling()->AllTilesForTesting();
for (size_t i = 0; i < pending_high_res_tiles.size(); ++i) {
all_tiles.insert(pending_high_res_tiles[i]);
high_res_tiles.insert(pending_high_res_tiles[i]);
}
std::vector<Tile*> active_high_res_tiles =
active_layer()->HighResTiling()->AllTilesForTesting();
for (size_t i = 0; i < active_high_res_tiles.size(); ++i) {
all_tiles.insert(active_high_res_tiles[i]);
high_res_tiles.insert(active_high_res_tiles[i]);
}
std::vector<Tile*> active_low_res_tiles =
active_layer()->LowResTiling()->AllTilesForTesting();
for (size_t i = 0; i < active_low_res_tiles.size(); ++i)
all_tiles.insert(active_low_res_tiles[i]);
PrioritizedTile last_tile;
smoothness_tiles.clear();
tile_count = 0;
size_t correct_order_tiles = 0u;
// Here we expect to get increasing ACTIVE_TREE priority_bin.
queue = host_impl()->BuildRasterQueue(SMOOTHNESS_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::ALL);
std::set<Tile*> expected_required_for_draw_tiles;
std::set<Tile*> expected_required_for_activation_tiles;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile());
if (!last_tile.tile())
last_tile = prioritized_tile;
EXPECT_LE(last_tile.priority().priority_bin,
prioritized_tile.priority().priority_bin);
bool skip_updating_last_tile = false;
if (last_tile.priority().priority_bin ==
prioritized_tile.priority().priority_bin) {
correct_order_tiles += last_tile.priority().distance_to_visible <=
prioritized_tile.priority().distance_to_visible;
} else if (prioritized_tile.priority().priority_bin == TilePriority::NOW) {
// Since we'd return pending tree now tiles before the eventually tiles on
// the active tree, update the value.
++correct_order_tiles;
skip_updating_last_tile = true;
}
if (prioritized_tile.priority().priority_bin == TilePriority::NOW &&
last_tile.priority().resolution !=
prioritized_tile.priority().resolution) {
// Low resolution should come first.
EXPECT_EQ(LOW_RESOLUTION, last_tile.priority().resolution);
}
if (!skip_updating_last_tile)
last_tile = prioritized_tile;
++tile_count;
smoothness_tiles.insert(prioritized_tile.tile());
if (prioritized_tile.tile()->required_for_draw())
expected_required_for_draw_tiles.insert(prioritized_tile.tile());
if (prioritized_tile.tile()->required_for_activation())
expected_required_for_activation_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(tile_count, smoothness_tiles.size());
EXPECT_EQ(all_tiles, smoothness_tiles);
// Since we don't guarantee increasing distance due to spiral iterator, we
// should check that we're _mostly_ right.
EXPECT_GT(correct_order_tiles, 3 * tile_count / 4);
// Check that we have consistent required_for_activation tiles.
queue = host_impl()->BuildRasterQueue(
SMOOTHNESS_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::REQUIRED_FOR_ACTIVATION);
required_for_activation_tiles.clear();
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile()->required_for_activation());
required_for_activation_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(expected_required_for_activation_tiles,
required_for_activation_tiles);
EXPECT_NE(all_tiles, required_for_activation_tiles);
// Check that we have consistent required_for_draw tiles.
queue = host_impl()->BuildRasterQueue(
SMOOTHNESS_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::REQUIRED_FOR_DRAW);
required_for_draw_tiles.clear();
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile()->required_for_draw());
required_for_draw_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(expected_required_for_draw_tiles, required_for_draw_tiles);
EXPECT_NE(all_tiles, required_for_draw_tiles);
std::set<Tile*> new_content_tiles;
last_tile = PrioritizedTile();
size_t increasing_distance_tiles = 0u;
// Here we expect to get increasing PENDING_TREE priority_bin.
queue = host_impl()->BuildRasterQueue(NEW_CONTENT_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::ALL);
tile_count = 0;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile());
if (!last_tile.tile())
last_tile = prioritized_tile;
EXPECT_LE(last_tile.priority().priority_bin,
prioritized_tile.priority().priority_bin);
if (last_tile.priority().priority_bin ==
prioritized_tile.priority().priority_bin) {
increasing_distance_tiles +=
last_tile.priority().distance_to_visible <=
prioritized_tile.priority().distance_to_visible;
}
if (prioritized_tile.priority().priority_bin == TilePriority::NOW &&
last_tile.priority().resolution !=
prioritized_tile.priority().resolution) {
// High resolution should come first.
EXPECT_EQ(HIGH_RESOLUTION, last_tile.priority().resolution);
}
last_tile = prioritized_tile;
new_content_tiles.insert(prioritized_tile.tile());
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, new_content_tiles.size());
EXPECT_EQ(high_res_tiles, new_content_tiles);
// Since we don't guarantee increasing distance due to spiral iterator, we
// should check that we're _mostly_ right.
EXPECT_GE(increasing_distance_tiles, 3 * tile_count / 4);
// Check that we have consistent required_for_activation tiles.
queue = host_impl()->BuildRasterQueue(
NEW_CONTENT_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::REQUIRED_FOR_ACTIVATION);
required_for_activation_tiles.clear();
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile()->required_for_activation());
required_for_activation_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(expected_required_for_activation_tiles,
required_for_activation_tiles);
EXPECT_NE(new_content_tiles, required_for_activation_tiles);
// Check that we have consistent required_for_draw tiles.
queue = host_impl()->BuildRasterQueue(
NEW_CONTENT_TAKES_PRIORITY,
RasterTilePriorityQueue::Type::REQUIRED_FOR_DRAW);
required_for_draw_tiles.clear();
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile()->required_for_draw());
required_for_draw_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(expected_required_for_draw_tiles, required_for_draw_tiles);
EXPECT_NE(new_content_tiles, required_for_draw_tiles);
}
TEST_F(TileManagerTilePriorityQueueTest,
RasterTilePriorityQueueHighNonIdealTilings) {
const gfx::Size layer_bounds(1000, 1000);
const gfx::Size viewport(800, 800);
host_impl()->SetViewportSize(viewport);
SetupDefaultTrees(layer_bounds);
pending_layer()->tilings()->AddTiling(1.5f, pending_layer()->raster_source());
active_layer()->tilings()->AddTiling(1.5f, active_layer()->raster_source());
pending_layer()->tilings()->AddTiling(1.7f, pending_layer()->raster_source());
active_layer()->tilings()->AddTiling(1.7f, active_layer()->raster_source());
pending_layer()->tilings()->UpdateTilePriorities(gfx::Rect(viewport), 1.f,
5.0, Occlusion(), true);
active_layer()->tilings()->UpdateTilePriorities(gfx::Rect(viewport), 1.f, 5.0,
Occlusion(), true);
std::set<Tile*> all_expected_tiles;
for (size_t i = 0; i < pending_layer()->num_tilings(); ++i) {
PictureLayerTiling* tiling = pending_layer()->tilings()->tiling_at(i);
if (tiling->contents_scale() == 1.f) {
tiling->set_resolution(HIGH_RESOLUTION);
const auto& all_tiles = tiling->AllTilesForTesting();
all_expected_tiles.insert(all_tiles.begin(), all_tiles.end());
} else {
tiling->set_resolution(NON_IDEAL_RESOLUTION);
}
}
for (size_t i = 0; i < active_layer()->num_tilings(); ++i) {
PictureLayerTiling* tiling = active_layer()->tilings()->tiling_at(i);
if (tiling->contents_scale() == 1.5f) {
tiling->set_resolution(HIGH_RESOLUTION);
const auto& all_tiles = tiling->AllTilesForTesting();
all_expected_tiles.insert(all_tiles.begin(), all_tiles.end());
} else {
tiling->set_resolution(NON_IDEAL_RESOLUTION);
// Non ideal tilings with a high res pending twin have to be processed
// because of possible activation tiles.
if (tiling->contents_scale() == 1.f) {
tiling->UpdateAndGetAllPrioritizedTilesForTesting();
const auto& all_tiles = tiling->AllTilesForTesting();
for (auto* tile : all_tiles)
EXPECT_TRUE(tile->required_for_activation());
all_expected_tiles.insert(all_tiles.begin(), all_tiles.end());
}
}
}
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SMOOTHNESS_TAKES_PRIORITY, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
size_t tile_count = 0;
std::set<Tile*> all_actual_tiles;
while (!queue->IsEmpty()) {
EXPECT_TRUE(queue->Top().tile());
all_actual_tiles.insert(queue->Top().tile());
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, all_actual_tiles.size());
EXPECT_EQ(all_expected_tiles.size(), all_actual_tiles.size());
EXPECT_EQ(all_expected_tiles, all_actual_tiles);
}
TEST_F(TileManagerTilePriorityQueueTest,
RasterTilePriorityQueueHighLowTilings) {
const gfx::Size layer_bounds(1000, 1000);
const gfx::Size viewport(800, 800);
host_impl()->SetViewportSize(viewport);
SetupDefaultTrees(layer_bounds);
pending_layer()->tilings()->AddTiling(1.5f, pending_layer()->raster_source());
active_layer()->tilings()->AddTiling(1.5f, active_layer()->raster_source());
pending_layer()->tilings()->AddTiling(1.7f, pending_layer()->raster_source());
active_layer()->tilings()->AddTiling(1.7f, active_layer()->raster_source());
pending_layer()->tilings()->UpdateTilePriorities(gfx::Rect(viewport), 1.f,
5.0, Occlusion(), true);
active_layer()->tilings()->UpdateTilePriorities(gfx::Rect(viewport), 1.f, 5.0,
Occlusion(), true);
std::set<Tile*> all_expected_tiles;
for (size_t i = 0; i < pending_layer()->num_tilings(); ++i) {
PictureLayerTiling* tiling = pending_layer()->tilings()->tiling_at(i);
if (tiling->contents_scale() == 1.f) {
tiling->set_resolution(HIGH_RESOLUTION);
const auto& all_tiles = tiling->AllTilesForTesting();
all_expected_tiles.insert(all_tiles.begin(), all_tiles.end());
} else {
tiling->set_resolution(NON_IDEAL_RESOLUTION);
}
}
for (size_t i = 0; i < active_layer()->num_tilings(); ++i) {
PictureLayerTiling* tiling = active_layer()->tilings()->tiling_at(i);
if (tiling->contents_scale() == 1.5f) {
tiling->set_resolution(HIGH_RESOLUTION);
const auto& all_tiles = tiling->AllTilesForTesting();
all_expected_tiles.insert(all_tiles.begin(), all_tiles.end());
} else {
tiling->set_resolution(LOW_RESOLUTION);
// Low res tilings with a high res pending twin have to be processed
// because of possible activation tiles.
if (tiling->contents_scale() == 1.f) {
tiling->UpdateAndGetAllPrioritizedTilesForTesting();
const auto& all_tiles = tiling->AllTilesForTesting();
for (auto* tile : all_tiles)
EXPECT_TRUE(tile->required_for_activation());
all_expected_tiles.insert(all_tiles.begin(), all_tiles.end());
}
}
}
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
size_t tile_count = 0;
std::set<Tile*> all_actual_tiles;
while (!queue->IsEmpty()) {
EXPECT_TRUE(queue->Top().tile());
all_actual_tiles.insert(queue->Top().tile());
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, all_actual_tiles.size());
EXPECT_EQ(all_expected_tiles.size(), all_actual_tiles.size());
EXPECT_EQ(all_expected_tiles, all_actual_tiles);
}
TEST_F(TileManagerTilePriorityQueueTest, RasterTilePriorityQueueInvalidation) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(gfx::Size(500, 500));
SetupDefaultTrees(layer_bounds);
// Use a tile's content rect as an invalidation. We should inset it a bit to
// ensure that border math doesn't invalidate neighbouring tiles.
gfx::Rect invalidation =
active_layer()->HighResTiling()->TileAt(1, 0)->content_rect();
invalidation.Inset(2, 2);
pending_layer()->set_invalidation(invalidation);
pending_layer()->HighResTiling()->Invalidate(invalidation);
pending_layer()->HighResTiling()->CreateMissingTilesInLiveTilesRect();
// Sanity checks: Tile at 0, 0 not exist on the pending tree (it's not
// invalidated). Tile 1, 0 should exist on both.
EXPECT_FALSE(pending_layer()->HighResTiling()->TileAt(0, 0));
EXPECT_TRUE(active_layer()->HighResTiling()->TileAt(0, 0));
EXPECT_TRUE(pending_layer()->HighResTiling()->TileAt(1, 0));
EXPECT_TRUE(active_layer()->HighResTiling()->TileAt(1, 0));
EXPECT_NE(pending_layer()->HighResTiling()->TileAt(1, 0),
active_layer()->HighResTiling()->TileAt(1, 0));
std::set<Tile*> expected_now_tiles;
std::set<Tile*> expected_required_for_draw_tiles;
std::set<Tile*> expected_required_for_activation_tiles;
for (int i = 0; i <= 1; ++i) {
for (int j = 0; j <= 1; ++j) {
bool have_pending_tile = false;
if (pending_layer()->HighResTiling()->TileAt(i, j)) {
expected_now_tiles.insert(
pending_layer()->HighResTiling()->TileAt(i, j));
expected_required_for_activation_tiles.insert(
pending_layer()->HighResTiling()->TileAt(i, j));
have_pending_tile = true;
}
Tile* active_tile = active_layer()->HighResTiling()->TileAt(i, j);
EXPECT_TRUE(active_tile);
expected_now_tiles.insert(active_tile);
expected_required_for_draw_tiles.insert(active_tile);
if (!have_pending_tile)
expected_required_for_activation_tiles.insert(active_tile);
}
}
// Expect 3 shared tiles and 1 unshared tile in total.
EXPECT_EQ(5u, expected_now_tiles.size());
// Expect 4 tiles for each draw and activation, but not all the same.
EXPECT_EQ(4u, expected_required_for_activation_tiles.size());
EXPECT_EQ(4u, expected_required_for_draw_tiles.size());
EXPECT_NE(expected_required_for_draw_tiles,
expected_required_for_activation_tiles);
std::set<Tile*> expected_all_tiles;
for (int i = 0; i <= 3; ++i) {
for (int j = 0; j <= 3; ++j) {
if (pending_layer()->HighResTiling()->TileAt(i, j))
expected_all_tiles.insert(
pending_layer()->HighResTiling()->TileAt(i, j));
EXPECT_TRUE(active_layer()->HighResTiling()->TileAt(i, j));
expected_all_tiles.insert(active_layer()->HighResTiling()->TileAt(i, j));
}
}
// Expect 15 shared tiles and 1 unshared tile.
EXPECT_EQ(17u, expected_all_tiles.size());
// The actual test will now build different queues and verify that the queues
// return the same information as computed manually above.
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
std::set<Tile*> actual_now_tiles;
std::set<Tile*> actual_all_tiles;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
queue->Pop();
if (prioritized_tile.priority().priority_bin == TilePriority::NOW)
actual_now_tiles.insert(prioritized_tile.tile());
actual_all_tiles.insert(prioritized_tile.tile());
}
EXPECT_EQ(expected_now_tiles, actual_now_tiles);
EXPECT_EQ(expected_all_tiles, actual_all_tiles);
queue = host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES,
RasterTilePriorityQueue::Type::REQUIRED_FOR_DRAW);
std::set<Tile*> actual_required_for_draw_tiles;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
queue->Pop();
actual_required_for_draw_tiles.insert(prioritized_tile.tile());
}
EXPECT_EQ(expected_required_for_draw_tiles, actual_required_for_draw_tiles);
queue = host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES,
RasterTilePriorityQueue::Type::REQUIRED_FOR_ACTIVATION);
std::set<Tile*> actual_required_for_activation_tiles;
while (!queue->IsEmpty()) {
Tile* tile = queue->Top().tile();
queue->Pop();
actual_required_for_activation_tiles.insert(tile);
}
EXPECT_EQ(expected_required_for_activation_tiles,
actual_required_for_activation_tiles);
}
TEST_F(TileManagerTilePriorityQueueTest, ActivationComesBeforeEventually) {
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
gfx::Size layer_bounds(1000, 1000);
SetupDefaultTrees(layer_bounds);
// Create a pending child layer.
scoped_refptr<FakeRasterSource> pending_raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
std::unique_ptr<FakePictureLayerImpl> pending_child =
FakePictureLayerImpl::CreateWithRasterSource(
host_impl()->pending_tree(), layer_id() + 1, pending_raster_source);
FakePictureLayerImpl* pending_child_raw = pending_child.get();
pending_child_raw->SetDrawsContent(true);
pending_layer()->test_properties()->AddChild(std::move(pending_child));
// Set a small viewport, so we have soon and eventually tiles.
host_impl()->SetViewportSize(gfx::Size(200, 200));
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
bool update_lcd_text = false;
host_impl()->pending_tree()->property_trees()->needs_rebuild = true;
host_impl()->pending_tree()->BuildLayerListAndPropertyTreesForTesting();
host_impl()->pending_tree()->UpdateDrawProperties(update_lcd_text);
host_impl()->SetRequiresHighResToDraw();
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SMOOTHNESS_TAKES_PRIORITY, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
// Get all the tiles that are NOW or SOON and make sure they are ready to
// draw.
std::vector<Tile*> all_tiles;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
if (prioritized_tile.priority().priority_bin >= TilePriority::EVENTUALLY)
break;
all_tiles.push_back(prioritized_tile.tile());
queue->Pop();
}
tile_manager()->InitializeTilesWithResourcesForTesting(
std::vector<Tile*>(all_tiles.begin(), all_tiles.end()));
// Ensure we can activate.
EXPECT_TRUE(tile_manager()->IsReadyToActivate());
}
TEST_F(TileManagerTilePriorityQueueTest, EvictionTilePriorityQueue) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
ASSERT_TRUE(active_layer()->HighResTiling());
ASSERT_TRUE(active_layer()->LowResTiling());
ASSERT_TRUE(pending_layer()->HighResTiling());
EXPECT_FALSE(pending_layer()->LowResTiling());
std::unique_ptr<EvictionTilePriorityQueue> empty_queue(
host_impl()->BuildEvictionQueue(SAME_PRIORITY_FOR_BOTH_TREES));
EXPECT_TRUE(empty_queue->IsEmpty());
std::set<Tile*> all_tiles;
size_t tile_count = 0;
std::unique_ptr<RasterTilePriorityQueue> raster_queue(
host_impl()->BuildRasterQueue(SAME_PRIORITY_FOR_BOTH_TREES,
RasterTilePriorityQueue::Type::ALL));
while (!raster_queue->IsEmpty()) {
++tile_count;
EXPECT_TRUE(raster_queue->Top().tile());
all_tiles.insert(raster_queue->Top().tile());
raster_queue->Pop();
}
EXPECT_EQ(tile_count, all_tiles.size());
EXPECT_EQ(16u, tile_count);
tile_manager()->InitializeTilesWithResourcesForTesting(
std::vector<Tile*>(all_tiles.begin(), all_tiles.end()));
std::unique_ptr<EvictionTilePriorityQueue> queue(
host_impl()->BuildEvictionQueue(SMOOTHNESS_TAKES_PRIORITY));
EXPECT_FALSE(queue->IsEmpty());
// Sanity check, all tiles should be visible.
std::set<Tile*> smoothness_tiles;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
EXPECT_TRUE(prioritized_tile.tile());
EXPECT_EQ(TilePriority::NOW, prioritized_tile.priority().priority_bin);
EXPECT_TRUE(prioritized_tile.tile()->draw_info().has_resource());
smoothness_tiles.insert(prioritized_tile.tile());
queue->Pop();
}
EXPECT_EQ(all_tiles, smoothness_tiles);
tile_manager()->ReleaseTileResourcesForTesting(
std::vector<Tile*>(all_tiles.begin(), all_tiles.end()));
Region invalidation(gfx::Rect(0, 0, 500, 500));
// Invalidate the pending tree.
pending_layer()->set_invalidation(invalidation);
pending_layer()->HighResTiling()->Invalidate(invalidation);
pending_layer()->HighResTiling()->CreateMissingTilesInLiveTilesRect();
EXPECT_FALSE(pending_layer()->LowResTiling());
// Renew all of the tile priorities.
gfx::Rect viewport(50, 50, 100, 100);
pending_layer()->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
active_layer()->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
// Populate all tiles directly from the tilings.
all_tiles.clear();
std::vector<Tile*> pending_high_res_tiles =
pending_layer()->HighResTiling()->AllTilesForTesting();
for (size_t i = 0; i < pending_high_res_tiles.size(); ++i)
all_tiles.insert(pending_high_res_tiles[i]);
std::vector<Tile*> active_high_res_tiles =
active_layer()->HighResTiling()->AllTilesForTesting();
for (size_t i = 0; i < active_high_res_tiles.size(); ++i)
all_tiles.insert(active_high_res_tiles[i]);
std::vector<Tile*> active_low_res_tiles =
active_layer()->LowResTiling()->AllTilesForTesting();
for (size_t i = 0; i < active_low_res_tiles.size(); ++i)
all_tiles.insert(active_low_res_tiles[i]);
tile_manager()->InitializeTilesWithResourcesForTesting(
std::vector<Tile*>(all_tiles.begin(), all_tiles.end()));
PrioritizedTile last_tile;
smoothness_tiles.clear();
tile_count = 0;
// Here we expect to get increasing combined priority_bin.
queue = host_impl()->BuildEvictionQueue(SMOOTHNESS_TAKES_PRIORITY);
int distance_increasing = 0;
int distance_decreasing = 0;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
Tile* tile = prioritized_tile.tile();
EXPECT_TRUE(tile);
EXPECT_TRUE(tile->draw_info().has_resource());
if (!last_tile.tile())
last_tile = prioritized_tile;
const TilePriority& last_priority = last_tile.priority();
const TilePriority& priority = prioritized_tile.priority();
EXPECT_GE(last_priority.priority_bin, priority.priority_bin);
if (last_priority.priority_bin == priority.priority_bin) {
EXPECT_LE(last_tile.tile()->required_for_activation(),
tile->required_for_activation());
if (last_tile.tile()->required_for_activation() ==
tile->required_for_activation()) {
if (last_priority.distance_to_visible >= priority.distance_to_visible)
++distance_decreasing;
else
++distance_increasing;
}
}
last_tile = prioritized_tile;
++tile_count;
smoothness_tiles.insert(tile);
queue->Pop();
}
// Ensure that the distance is decreasing many more times than increasing.
EXPECT_EQ(3, distance_increasing);
EXPECT_EQ(16, distance_decreasing);
EXPECT_EQ(tile_count, smoothness_tiles.size());
EXPECT_EQ(all_tiles, smoothness_tiles);
std::set<Tile*> new_content_tiles;
last_tile = PrioritizedTile();
// Again, we expect to get increasing combined priority_bin.
queue = host_impl()->BuildEvictionQueue(NEW_CONTENT_TAKES_PRIORITY);
distance_decreasing = 0;
distance_increasing = 0;
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
Tile* tile = prioritized_tile.tile();
EXPECT_TRUE(tile);
if (!last_tile.tile())
last_tile = prioritized_tile;
const TilePriority& last_priority = last_tile.priority();
const TilePriority& priority = prioritized_tile.priority();
EXPECT_GE(last_priority.priority_bin, priority.priority_bin);
if (last_priority.priority_bin == priority.priority_bin) {
EXPECT_LE(last_tile.tile()->required_for_activation(),
tile->required_for_activation());
if (last_tile.tile()->required_for_activation() ==
tile->required_for_activation()) {
if (last_priority.distance_to_visible >= priority.distance_to_visible)
++distance_decreasing;
else
++distance_increasing;
}
}
last_tile = prioritized_tile;
new_content_tiles.insert(tile);
queue->Pop();
}
// Ensure that the distance is decreasing many more times than increasing.
EXPECT_EQ(3, distance_increasing);
EXPECT_EQ(16, distance_decreasing);
EXPECT_EQ(tile_count, new_content_tiles.size());
EXPECT_EQ(all_tiles, new_content_tiles);
}
TEST_F(TileManagerTilePriorityQueueTest,
EvictionTilePriorityQueueWithOcclusion) {
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
scoped_refptr<FakeRasterSource> pending_raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
SetupPendingTree(pending_raster_source);
std::unique_ptr<FakePictureLayerImpl> pending_child =
FakePictureLayerImpl::CreateWithRasterSource(host_impl()->pending_tree(),
2, pending_raster_source);
int child_id = pending_child->id();
pending_layer()->test_properties()->AddChild(std::move(pending_child));
FakePictureLayerImpl* pending_child_layer =
static_cast<FakePictureLayerImpl*>(
pending_layer()->test_properties()->children[0]);
pending_child_layer->SetDrawsContent(true);
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
bool update_lcd_text = false;
host_impl()->pending_tree()->property_trees()->needs_rebuild = true;
host_impl()->pending_tree()->BuildLayerListAndPropertyTreesForTesting();
host_impl()->pending_tree()->UpdateDrawProperties(update_lcd_text);
ActivateTree();
SetupPendingTree(pending_raster_source);
FakePictureLayerImpl* active_child_layer = static_cast<FakePictureLayerImpl*>(
host_impl()->active_tree()->LayerById(child_id));
std::set<Tile*> all_tiles;
size_t tile_count = 0;
std::unique_ptr<RasterTilePriorityQueue> raster_queue(
host_impl()->BuildRasterQueue(SAME_PRIORITY_FOR_BOTH_TREES,
RasterTilePriorityQueue::Type::ALL));
while (!raster_queue->IsEmpty()) {
++tile_count;
EXPECT_TRUE(raster_queue->Top().tile());
all_tiles.insert(raster_queue->Top().tile());
raster_queue->Pop();
}
EXPECT_EQ(tile_count, all_tiles.size());
EXPECT_EQ(32u, tile_count);
// Renew all of the tile priorities.
gfx::Rect viewport(layer_bounds);
pending_layer()->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
pending_child_layer->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
active_layer()->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
active_child_layer->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
// Populate all tiles directly from the tilings.
all_tiles.clear();
std::vector<Tile*> pending_high_res_tiles =
pending_layer()->HighResTiling()->AllTilesForTesting();
all_tiles.insert(pending_high_res_tiles.begin(),
pending_high_res_tiles.end());
// Set all tiles on the pending_child_layer as occluded on the pending tree.
std::vector<Tile*> pending_child_high_res_tiles =
pending_child_layer->HighResTiling()->AllTilesForTesting();
pending_child_layer->HighResTiling()->SetAllTilesOccludedForTesting();
active_child_layer->HighResTiling()->SetAllTilesOccludedForTesting();
active_child_layer->LowResTiling()->SetAllTilesOccludedForTesting();
tile_manager()->InitializeTilesWithResourcesForTesting(
std::vector<Tile*>(all_tiles.begin(), all_tiles.end()));
// Verify occlusion is considered by EvictionTilePriorityQueue.
TreePriority tree_priority = NEW_CONTENT_TAKES_PRIORITY;
size_t occluded_count = 0u;
PrioritizedTile last_tile;
std::unique_ptr<EvictionTilePriorityQueue> queue(
host_impl()->BuildEvictionQueue(tree_priority));
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
if (!last_tile.tile())
last_tile = prioritized_tile;
bool tile_is_occluded = prioritized_tile.is_occluded();
// The only way we will encounter an occluded tile after an unoccluded
// tile is if the priorty bin decreased, the tile is required for
// activation, or the scale changed.
if (tile_is_occluded) {
occluded_count++;
bool last_tile_is_occluded = last_tile.is_occluded();
if (!last_tile_is_occluded) {
TilePriority::PriorityBin tile_priority_bin =
prioritized_tile.priority().priority_bin;
TilePriority::PriorityBin last_tile_priority_bin =
last_tile.priority().priority_bin;
EXPECT_TRUE((tile_priority_bin < last_tile_priority_bin) ||
prioritized_tile.tile()->required_for_activation() ||
(prioritized_tile.tile()->contents_scale() !=
last_tile.tile()->contents_scale()));
}
}
last_tile = prioritized_tile;
queue->Pop();
}
size_t expected_occluded_count = pending_child_high_res_tiles.size();
EXPECT_EQ(expected_occluded_count, occluded_count);
}
TEST_F(TileManagerTilePriorityQueueTest,
EvictionTilePriorityQueueWithTransparentLayer) {
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
gfx::Size layer_bounds(1000, 1000);
scoped_refptr<FakeRasterSource> pending_raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
SetupPendingTree(pending_raster_source);
std::unique_ptr<FakePictureLayerImpl> pending_child =
FakePictureLayerImpl::CreateWithRasterSource(host_impl()->pending_tree(),
2, pending_raster_source);
FakePictureLayerImpl* pending_child_layer = pending_child.get();
pending_layer()->test_properties()->AddChild(std::move(pending_child));
// Create a fully transparent child layer so that its tile priorities are not
// considered to be valid.
pending_child_layer->SetDrawsContent(true);
pending_child_layer->test_properties()->force_render_surface = true;
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
bool update_lcd_text = false;
host_impl()->pending_tree()->property_trees()->needs_rebuild = true;
host_impl()->pending_tree()->BuildLayerListAndPropertyTreesForTesting();
host_impl()->pending_tree()->UpdateDrawProperties(update_lcd_text);
host_impl()->pending_tree()->property_trees()->effect_tree.OnOpacityAnimated(
0.0f, pending_child_layer->effect_tree_index(),
host_impl()->pending_tree());
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
host_impl()->pending_tree()->UpdateDrawProperties(update_lcd_text);
// Renew all of the tile priorities.
gfx::Rect viewport(layer_bounds);
pending_layer()->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
pending_child_layer->picture_layer_tiling_set()->UpdateTilePriorities(
viewport, 1.0f, 1.0, Occlusion(), true);
// Populate all tiles directly from the tilings.
std::set<Tile*> all_pending_tiles;
std::vector<Tile*> pending_high_res_tiles =
pending_layer()->HighResTiling()->AllTilesForTesting();
all_pending_tiles.insert(pending_high_res_tiles.begin(),
pending_high_res_tiles.end());
EXPECT_EQ(16u, pending_high_res_tiles.size());
std::set<Tile*> all_pending_child_tiles;
std::vector<Tile*> pending_child_high_res_tiles =
pending_child_layer->HighResTiling()->AllTilesForTesting();
all_pending_child_tiles.insert(pending_child_high_res_tiles.begin(),
pending_child_high_res_tiles.end());
EXPECT_EQ(16u, pending_child_high_res_tiles.size());
std::set<Tile*> all_tiles = all_pending_tiles;
all_tiles.insert(all_pending_child_tiles.begin(),
all_pending_child_tiles.end());
tile_manager()->InitializeTilesWithResourcesForTesting(
std::vector<Tile*>(all_tiles.begin(), all_tiles.end()));
EXPECT_TRUE(pending_layer()->HasValidTilePriorities());
EXPECT_FALSE(pending_child_layer->HasValidTilePriorities());
// Verify that eviction queue returns tiles also from layers without valid
// tile priorities and that the tile priority bin of those tiles is (at most)
// EVENTUALLY.
TreePriority tree_priority = NEW_CONTENT_TAKES_PRIORITY;
std::set<Tile*> new_content_tiles;
size_t tile_count = 0;
std::unique_ptr<EvictionTilePriorityQueue> queue(
host_impl()->BuildEvictionQueue(tree_priority));
while (!queue->IsEmpty()) {
PrioritizedTile prioritized_tile = queue->Top();
Tile* tile = prioritized_tile.tile();
const TilePriority& pending_priority = prioritized_tile.priority();
EXPECT_NE(std::numeric_limits<float>::infinity(),
pending_priority.distance_to_visible);
if (all_pending_child_tiles.find(tile) != all_pending_child_tiles.end())
EXPECT_EQ(TilePriority::EVENTUALLY, pending_priority.priority_bin);
else
EXPECT_EQ(TilePriority::NOW, pending_priority.priority_bin);
new_content_tiles.insert(tile);
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, new_content_tiles.size());
EXPECT_EQ(all_tiles, new_content_tiles);
}
TEST_F(TileManagerTilePriorityQueueTest, RasterTilePriorityQueueEmptyLayers) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
size_t tile_count = 0;
std::set<Tile*> all_tiles;
while (!queue->IsEmpty()) {
EXPECT_TRUE(queue->Top().tile());
all_tiles.insert(queue->Top().tile());
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, all_tiles.size());
EXPECT_EQ(16u, tile_count);
for (int i = 1; i < 10; ++i) {
std::unique_ptr<FakePictureLayerImpl> pending_child_layer =
FakePictureLayerImpl::Create(host_impl()->pending_tree(),
layer_id() + i);
pending_child_layer->SetDrawsContent(true);
pending_child_layer->set_has_valid_tile_priorities(true);
pending_layer()->test_properties()->AddChild(
std::move(pending_child_layer));
}
queue = host_impl()->BuildRasterQueue(SAME_PRIORITY_FOR_BOTH_TREES,
RasterTilePriorityQueue::Type::ALL);
EXPECT_FALSE(queue->IsEmpty());
tile_count = 0;
all_tiles.clear();
while (!queue->IsEmpty()) {
EXPECT_TRUE(queue->Top().tile());
all_tiles.insert(queue->Top().tile());
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, all_tiles.size());
EXPECT_EQ(16u, tile_count);
}
TEST_F(TileManagerTilePriorityQueueTest, EvictionTilePriorityQueueEmptyLayers) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
std::unique_ptr<RasterTilePriorityQueue> raster_queue(
host_impl()->BuildRasterQueue(SAME_PRIORITY_FOR_BOTH_TREES,
RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(raster_queue->IsEmpty());
size_t tile_count = 0;
std::set<Tile*> all_tiles;
while (!raster_queue->IsEmpty()) {
EXPECT_TRUE(raster_queue->Top().tile());
all_tiles.insert(raster_queue->Top().tile());
++tile_count;
raster_queue->Pop();
}
EXPECT_EQ(tile_count, all_tiles.size());
EXPECT_EQ(16u, tile_count);
std::vector<Tile*> tiles(all_tiles.begin(), all_tiles.end());
host_impl()->tile_manager()->InitializeTilesWithResourcesForTesting(tiles);
for (int i = 1; i < 10; ++i) {
std::unique_ptr<FakePictureLayerImpl> pending_child_layer =
FakePictureLayerImpl::Create(host_impl()->pending_tree(),
layer_id() + i);
pending_child_layer->SetDrawsContent(true);
pending_child_layer->set_has_valid_tile_priorities(true);
pending_layer()->test_properties()->AddChild(
std::move(pending_child_layer));
}
std::unique_ptr<EvictionTilePriorityQueue> queue(
host_impl()->BuildEvictionQueue(SAME_PRIORITY_FOR_BOTH_TREES));
EXPECT_FALSE(queue->IsEmpty());
tile_count = 0;
all_tiles.clear();
while (!queue->IsEmpty()) {
EXPECT_TRUE(queue->Top().tile());
all_tiles.insert(queue->Top().tile());
++tile_count;
queue->Pop();
}
EXPECT_EQ(tile_count, all_tiles.size());
EXPECT_EQ(16u, tile_count);
}
TEST_F(TileManagerTilePriorityQueueTest,
RasterTilePriorityQueueStaticViewport) {
FakePictureLayerTilingClient client;
gfx::Rect viewport(50, 50, 500, 500);
gfx::Size layer_bounds(1600, 1600);
const int soon_border_outset = 312;
gfx::Rect soon_rect = viewport;
soon_rect.Inset(-soon_border_outset, -soon_border_outset);
client.SetTileSize(gfx::Size(30, 30));
LayerTreeSettings settings;
settings.verify_clip_tree_calculations = true;
settings.verify_transform_tree_calculations = true;
std::unique_ptr<PictureLayerTilingSet> tiling_set =
PictureLayerTilingSet::Create(
ACTIVE_TREE, &client, settings.tiling_interest_area_padding,
settings.skewport_target_time_in_seconds,
settings.skewport_extrapolation_limit_in_screen_pixels);
scoped_refptr<FakeRasterSource> raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
PictureLayerTiling* tiling = tiling_set->AddTiling(1.0f, raster_source);
tiling->set_resolution(HIGH_RESOLUTION);
tiling_set->UpdateTilePriorities(viewport, 1.0f, 1.0, Occlusion(), true);
std::vector<Tile*> all_tiles = tiling->AllTilesForTesting();
// Sanity check.
EXPECT_EQ(3364u, all_tiles.size());
// The explanation of each iteration is as follows:
// 1. First iteration tests that we can get all of the tiles correctly.
// 2. Second iteration ensures that we can get all of the tiles again (first
// iteration didn't change any tiles), as well set all tiles to be ready to
// draw.
// 3. Third iteration ensures that no tiles are returned, since they were all
// marked as ready to draw.
for (int i = 0; i < 3; ++i) {
std::unique_ptr<TilingSetRasterQueueAll> queue(
new TilingSetRasterQueueAll(tiling_set.get(), false));
// There are 3 bins in TilePriority.
bool have_tiles[3] = {};
// On the third iteration, we should get no tiles since everything was
// marked as ready to draw.
if (i == 2) {
EXPECT_TRUE(queue->IsEmpty());
continue;
}
EXPECT_FALSE(queue->IsEmpty());
std::set<Tile*> unique_tiles;
unique_tiles.insert(queue->Top().tile());
PrioritizedTile last_tile = queue->Top();
have_tiles[last_tile.priority().priority_bin] = true;
// On the second iteration, mark everything as ready to draw (solid color).
if (i == 1) {
TileDrawInfo& draw_info = last_tile.tile()->draw_info();
draw_info.SetSolidColorForTesting(SK_ColorRED);
}
queue->Pop();
int eventually_bin_order_correct_count = 0;
int eventually_bin_order_incorrect_count = 0;
while (!queue->IsEmpty()) {
PrioritizedTile new_tile = queue->Top();
queue->Pop();
unique_tiles.insert(new_tile.tile());
TilePriority last_priority = last_tile.priority();
TilePriority new_priority = new_tile.priority();
EXPECT_LE(last_priority.priority_bin, new_priority.priority_bin);
if (last_priority.priority_bin == new_priority.priority_bin) {
if (last_priority.priority_bin == TilePriority::EVENTUALLY) {
bool order_correct = last_priority.distance_to_visible <=
new_priority.distance_to_visible;
eventually_bin_order_correct_count += order_correct;
eventually_bin_order_incorrect_count += !order_correct;
} else if (!soon_rect.Intersects(new_tile.tile()->content_rect()) &&
!soon_rect.Intersects(last_tile.tile()->content_rect())) {
EXPECT_LE(last_priority.distance_to_visible,
new_priority.distance_to_visible);
EXPECT_EQ(TilePriority::NOW, new_priority.priority_bin);
} else if (new_priority.distance_to_visible > 0.f) {
EXPECT_EQ(TilePriority::SOON, new_priority.priority_bin);
}
}
have_tiles[new_priority.priority_bin] = true;
last_tile = new_tile;
// On the second iteration, mark everything as ready to draw (solid
// color).
if (i == 1) {
TileDrawInfo& draw_info = last_tile.tile()->draw_info();
draw_info.SetSolidColorForTesting(SK_ColorRED);
}
}
EXPECT_GT(eventually_bin_order_correct_count,
eventually_bin_order_incorrect_count);
// We should have now and eventually tiles, as well as soon tiles from
// the border region.
EXPECT_TRUE(have_tiles[TilePriority::NOW]);
EXPECT_TRUE(have_tiles[TilePriority::SOON]);
EXPECT_TRUE(have_tiles[TilePriority::EVENTUALLY]);
EXPECT_EQ(unique_tiles.size(), all_tiles.size());
}
}
TEST_F(TileManagerTilePriorityQueueTest,
RasterTilePriorityQueueMovingViewport) {
FakePictureLayerTilingClient client;
gfx::Rect viewport(50, 0, 100, 100);
gfx::Rect moved_viewport(50, 0, 100, 500);
gfx::Size layer_bounds(1000, 1000);
client.SetTileSize(gfx::Size(30, 30));
LayerTreeSettings settings;
settings.verify_clip_tree_calculations = true;
settings.verify_transform_tree_calculations = true;
std::unique_ptr<PictureLayerTilingSet> tiling_set =
PictureLayerTilingSet::Create(
ACTIVE_TREE, &client, settings.tiling_interest_area_padding,
settings.skewport_target_time_in_seconds,
settings.skewport_extrapolation_limit_in_screen_pixels);
scoped_refptr<FakeRasterSource> raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
PictureLayerTiling* tiling = tiling_set->AddTiling(1.0f, raster_source);
tiling->set_resolution(HIGH_RESOLUTION);
tiling_set->UpdateTilePriorities(viewport, 1.0f, 1.0, Occlusion(), true);
tiling_set->UpdateTilePriorities(moved_viewport, 1.0f, 2.0, Occlusion(),
true);
const int soon_border_outset = 312;
gfx::Rect soon_rect = moved_viewport;
soon_rect.Inset(-soon_border_outset, -soon_border_outset);
// There are 3 bins in TilePriority.
bool have_tiles[3] = {};
PrioritizedTile last_tile;
int eventually_bin_order_correct_count = 0;
int eventually_bin_order_incorrect_count = 0;
std::unique_ptr<TilingSetRasterQueueAll> queue(
new TilingSetRasterQueueAll(tiling_set.get(), false));
for (; !queue->IsEmpty(); queue->Pop()) {
if (!last_tile.tile())
last_tile = queue->Top();
const PrioritizedTile& new_tile = queue->Top();
TilePriority last_priority = last_tile.priority();
TilePriority new_priority = new_tile.priority();
have_tiles[new_priority.priority_bin] = true;
EXPECT_LE(last_priority.priority_bin, new_priority.priority_bin);
if (last_priority.priority_bin == new_priority.priority_bin) {
if (last_priority.priority_bin == TilePriority::EVENTUALLY) {
bool order_correct = last_priority.distance_to_visible <=
new_priority.distance_to_visible;
eventually_bin_order_correct_count += order_correct;
eventually_bin_order_incorrect_count += !order_correct;
} else if (!soon_rect.Intersects(new_tile.tile()->content_rect()) &&
!soon_rect.Intersects(last_tile.tile()->content_rect())) {
EXPECT_LE(last_priority.distance_to_visible,
new_priority.distance_to_visible);
} else if (new_priority.distance_to_visible > 0.f) {
EXPECT_EQ(TilePriority::SOON, new_priority.priority_bin);
}
}
last_tile = new_tile;
}
EXPECT_GT(eventually_bin_order_correct_count,
eventually_bin_order_incorrect_count);
EXPECT_TRUE(have_tiles[TilePriority::NOW]);
EXPECT_TRUE(have_tiles[TilePriority::SOON]);
EXPECT_TRUE(have_tiles[TilePriority::EVENTUALLY]);
}
TEST_F(TileManagerTilePriorityQueueTest, SetIsLikelyToRequireADraw) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
// Verify that the queue has a required for draw tile at Top.
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
EXPECT_TRUE(queue->Top().tile()->required_for_draw());
EXPECT_FALSE(host_impl()->is_likely_to_require_a_draw());
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
EXPECT_TRUE(host_impl()->is_likely_to_require_a_draw());
}
TEST_F(TileManagerTilePriorityQueueTest,
SetIsLikelyToRequireADrawOnZeroMemoryBudget) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
// Verify that the queue has a required for draw tile at Top.
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
EXPECT_TRUE(queue->Top().tile()->required_for_draw());
ManagedMemoryPolicy policy = host_impl()->ActualManagedMemoryPolicy();
policy.bytes_limit_when_visible = 0;
host_impl()->SetMemoryPolicy(policy);
EXPECT_FALSE(host_impl()->is_likely_to_require_a_draw());
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
EXPECT_FALSE(host_impl()->is_likely_to_require_a_draw());
}
TEST_F(TileManagerTilePriorityQueueTest,
SetIsLikelyToRequireADrawOnLimitedMemoryBudget) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
// Verify that the queue has a required for draw tile at Top.
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
EXPECT_TRUE(queue->Top().tile()->required_for_draw());
EXPECT_EQ(gfx::Size(256, 256), queue->Top().tile()->desired_texture_size());
EXPECT_EQ(RGBA_8888, host_impl()->resource_provider()->best_texture_format());
ManagedMemoryPolicy policy = host_impl()->ActualManagedMemoryPolicy();
policy.bytes_limit_when_visible = ResourceUtil::UncheckedSizeInBytes<size_t>(
gfx::Size(256, 256), RGBA_8888);
host_impl()->SetMemoryPolicy(policy);
EXPECT_FALSE(host_impl()->is_likely_to_require_a_draw());
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
EXPECT_TRUE(host_impl()->is_likely_to_require_a_draw());
Resource* resource = host_impl()->resource_pool()->AcquireResource(
gfx::Size(256, 256), RGBA_8888, gfx::ColorSpace());
host_impl()->tile_manager()->CheckIfMoreTilesNeedToBePreparedForTesting();
EXPECT_FALSE(host_impl()->is_likely_to_require_a_draw());
host_impl()->resource_pool()->ReleaseResource(resource);
}
TEST_F(TileManagerTilePriorityQueueTest, DefaultMemoryPolicy) {
const gfx::Size layer_bounds(1000, 1000);
host_impl()->SetViewportSize(layer_bounds);
SetupDefaultTrees(layer_bounds);
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
// 64MB is the default mem limit.
EXPECT_EQ(67108864u,
host_impl()->global_tile_state().hard_memory_limit_in_bytes);
EXPECT_EQ(TileMemoryLimitPolicy::ALLOW_ANYTHING,
host_impl()->global_tile_state().memory_limit_policy);
EXPECT_EQ(ManagedMemoryPolicy::kDefaultNumResourcesLimit,
host_impl()->global_tile_state().num_resources_limit);
}
TEST_F(TileManagerTilePriorityQueueTest, RasterQueueAllUsesCorrectTileBounds) {
// Verify that we use the real tile bounds when advancing phases during the
// tile iteration.
gfx::Size layer_bounds(1, 1);
scoped_refptr<FakeRasterSource> raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
FakePictureLayerTilingClient pending_client;
pending_client.SetTileSize(gfx::Size(64, 64));
std::unique_ptr<PictureLayerTilingSet> tiling_set =
PictureLayerTilingSet::Create(WhichTree::ACTIVE_TREE, &pending_client,
1.0f, 1.0f, 1000);
pending_client.set_twin_tiling_set(tiling_set.get());
auto* tiling = tiling_set->AddTiling(1.0f, raster_source);
tiling->set_resolution(HIGH_RESOLUTION);
tiling->CreateAllTilesForTesting();
// The tile is (0, 0, 1, 1), create an intersecting and non-intersecting
// rectangle to test the advance phase with. The tile size is (64, 64), so
// both rectangles intersect the tile content size, but only one should
// intersect the actual size.
gfx::Rect non_intersecting_rect(2, 2, 10, 10);
gfx::Rect intersecting_rect(0, 0, 10, 10);
{
tiling->SetTilePriorityRectsForTesting(
non_intersecting_rect, // Visible rect.
intersecting_rect, // Skewport rect.
intersecting_rect, // Soon rect.
intersecting_rect); // Eventually rect.
std::unique_ptr<TilingSetRasterQueueAll> queue(
new TilingSetRasterQueueAll(tiling_set.get(), false));
EXPECT_FALSE(queue->IsEmpty());
}
{
tiling->SetTilePriorityRectsForTesting(
non_intersecting_rect, // Visible rect.
non_intersecting_rect, // Skewport rect.
intersecting_rect, // Soon rect.
intersecting_rect); // Eventually rect.
std::unique_ptr<TilingSetRasterQueueAll> queue(
new TilingSetRasterQueueAll(tiling_set.get(), false));
EXPECT_FALSE(queue->IsEmpty());
}
{
tiling->SetTilePriorityRectsForTesting(
non_intersecting_rect, // Visible rect.
non_intersecting_rect, // Skewport rect.
non_intersecting_rect, // Soon rect.
intersecting_rect); // Eventually rect.
std::unique_ptr<TilingSetRasterQueueAll> queue(
new TilingSetRasterQueueAll(tiling_set.get(), false));
EXPECT_FALSE(queue->IsEmpty());
}
}
TEST_F(TileManagerTilePriorityQueueTest, NoRasterTasksforSolidColorTiles) {
gfx::Size size(10, 10);
const gfx::Size layer_bounds(1000, 1000);
std::unique_ptr<FakeRecordingSource> recording_source =
FakeRecordingSource::CreateFilledRecordingSource(layer_bounds);
SkPaint solid_paint;
SkColor solid_color = SkColorSetARGB(255, 12, 23, 34);
solid_paint.setColor(solid_color);
recording_source->add_draw_rect_with_paint(gfx::Rect(layer_bounds),
solid_paint);
// Create non solid tile as well, otherwise tilings wouldnt be created.
SkColor non_solid_color = SkColorSetARGB(128, 45, 56, 67);
SkPaint non_solid_paint;
non_solid_paint.setColor(non_solid_color);
recording_source->add_draw_rect_with_paint(gfx::Rect(0, 0, 10, 10),
non_solid_paint);
recording_source->Rerecord();
scoped_refptr<RasterSource> raster_source =
RasterSource::CreateFromRecordingSource(recording_source.get(), false);
FakePictureLayerTilingClient tiling_client;
tiling_client.SetTileSize(size);
std::unique_ptr<PictureLayerImpl> layer_impl =
PictureLayerImpl::Create(host_impl()->active_tree(), 1, false);
layer_impl->set_is_drawn_render_surface_layer_list_member(true);
PictureLayerTilingSet* tiling_set = layer_impl->picture_layer_tiling_set();
PictureLayerTiling* tiling = tiling_set->AddTiling(1.0f, raster_source);
tiling->set_resolution(HIGH_RESOLUTION);
tiling->CreateAllTilesForTesting();
tiling->SetTilePriorityRectsForTesting(
gfx::Rect(layer_bounds), // Visible rect.
gfx::Rect(layer_bounds), // Skewport rect.
gfx::Rect(layer_bounds), // Soon rect.
gfx::Rect(layer_bounds)); // Eventually rect.
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
std::vector<Tile*> tiles = tiling->AllTilesForTesting();
for (size_t tile_idx = 0; tile_idx < tiles.size(); ++tile_idx) {
Tile* tile = tiles[tile_idx];
if (tile->id() == 1) {
// Non-solid tile.
EXPECT_TRUE(tile->HasRasterTask());
EXPECT_EQ(TileDrawInfo::RESOURCE_MODE, tile->draw_info().mode());
} else {
EXPECT_FALSE(tile->HasRasterTask());
EXPECT_EQ(TileDrawInfo::SOLID_COLOR_MODE, tile->draw_info().mode());
EXPECT_EQ(solid_color, tile->draw_info().solid_color());
}
}
}
class TileManagerTest : public TestLayerTreeHostBase {
public:
// MockLayerTreeHostImpl allows us to intercept tile manager callbacks.
class MockLayerTreeHostImpl : public FakeLayerTreeHostImpl {
public:
MockLayerTreeHostImpl(
const LayerTreeSettings& settings,
TaskRunnerProvider* task_runner_provider,
SharedBitmapManager* manager,
TaskGraphRunner* task_graph_runner,
gpu::GpuMemoryBufferManager* gpu_memory_buffer_manager)
: FakeLayerTreeHostImpl(settings,
task_runner_provider,
manager,
task_graph_runner,
gpu_memory_buffer_manager) {}
MOCK_METHOD0(NotifyAllTileTasksCompleted, void());
MOCK_METHOD0(NotifyReadyToDraw, void());
};
std::unique_ptr<FakeLayerTreeHostImpl> CreateHostImpl(
const LayerTreeSettings& settings,
TaskRunnerProvider* task_runner_provider,
SharedBitmapManager* shared_bitmap_manager,
TaskGraphRunner* task_graph_runner,
gpu::GpuMemoryBufferManager* gpu_memory_buffer_manager) override {
return base::MakeUnique<MockLayerTreeHostImpl>(
settings, task_runner_provider, shared_bitmap_manager,
task_graph_runner, gpu_memory_buffer_manager);
}
// By default use software compositing (no context provider).
std::unique_ptr<OutputSurface> CreateOutputSurface() override {
return FakeOutputSurface::CreateDelegatingSoftware();
}
MockLayerTreeHostImpl& MockHostImpl() {
return *static_cast<MockLayerTreeHostImpl*>(host_impl());
}
};
// Test to ensure that we call NotifyAllTileTasksCompleted when PrepareTiles is
// called.
TEST_F(TileManagerTest, AllWorkFinishedTest) {
// Check with no tile work enqueued.
{
base::RunLoop run_loop;
EXPECT_FALSE(
host_impl()->tile_manager()->HasScheduledTileTasksForTesting());
EXPECT_CALL(MockHostImpl(), NotifyAllTileTasksCompleted())
.WillOnce(testing::Invoke([&run_loop]() { run_loop.Quit(); }));
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
EXPECT_TRUE(host_impl()->tile_manager()->HasScheduledTileTasksForTesting());
run_loop.Run();
}
// Check that the "schedule more work" path also triggers the expected
// callback.
{
base::RunLoop run_loop;
EXPECT_FALSE(
host_impl()->tile_manager()->HasScheduledTileTasksForTesting());
EXPECT_CALL(MockHostImpl(), NotifyAllTileTasksCompleted())
.WillOnce(testing::Invoke([&run_loop]() { run_loop.Quit(); }));
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
host_impl()->tile_manager()->SetMoreTilesNeedToBeRasterizedForTesting();
EXPECT_TRUE(host_impl()->tile_manager()->HasScheduledTileTasksForTesting());
run_loop.Run();
}
}
TEST_F(TileManagerTest, ActivateAndDrawWhenOOM) {
SetupDefaultTrees(gfx::Size(1000, 1000));
auto global_state = host_impl()->global_tile_state();
global_state.hard_memory_limit_in_bytes = 1u;
global_state.soft_memory_limit_in_bytes = 1u;
{
base::RunLoop run_loop;
EXPECT_FALSE(
host_impl()->tile_manager()->HasScheduledTileTasksForTesting());
EXPECT_CALL(MockHostImpl(), NotifyAllTileTasksCompleted())
.WillOnce(testing::Invoke([&run_loop]() { run_loop.Quit(); }));
host_impl()->tile_manager()->PrepareTiles(global_state);
EXPECT_TRUE(host_impl()->tile_manager()->HasScheduledTileTasksForTesting());
run_loop.Run();
}
EXPECT_TRUE(host_impl()->tile_manager()->IsReadyToDraw());
EXPECT_TRUE(host_impl()->tile_manager()->IsReadyToActivate());
EXPECT_TRUE(host_impl()->notify_tile_state_changed_called());
// Next PrepareTiles should skip NotifyTileStateChanged since all tiles
// are marked oom already.
{
base::RunLoop run_loop;
host_impl()->set_notify_tile_state_changed_called(false);
EXPECT_CALL(MockHostImpl(), NotifyAllTileTasksCompleted())
.WillOnce(testing::Invoke([&run_loop]() { run_loop.Quit(); }));
host_impl()->tile_manager()->PrepareTiles(global_state);
run_loop.Run();
EXPECT_FALSE(host_impl()->notify_tile_state_changed_called());
}
}
TEST_F(TileManagerTest, LowResHasNoImage) {
gfx::Size size(10, 12);
TileResolution resolutions[] = {HIGH_RESOLUTION, LOW_RESOLUTION};
for (size_t i = 0; i < arraysize(resolutions); ++i) {
SCOPED_TRACE(resolutions[i]);
// Make a RasterSource that will draw a blue bitmap image.
sk_sp<SkSurface> surface =
SkSurface::MakeRasterN32Premul(size.width(), size.height());
ASSERT_NE(surface, nullptr);
surface->getCanvas()->clear(SK_ColorBLUE);
sk_sp<SkImage> blue_image = surface->makeImageSnapshot();
std::unique_ptr<FakeRecordingSource> recording_source =
FakeRecordingSource::CreateFilledRecordingSource(size);
recording_source->SetBackgroundColor(SK_ColorTRANSPARENT);
recording_source->SetRequiresClear(true);
recording_source->SetClearCanvasWithDebugColor(false);
SkPaint paint;
paint.setColor(SK_ColorGREEN);
recording_source->add_draw_rect_with_paint(gfx::Rect(size), paint);
recording_source->add_draw_image(std::move(blue_image), gfx::Point());
recording_source->Rerecord();
scoped_refptr<RasterSource> raster =
RasterSource::CreateFromRecordingSource(recording_source.get(), false);
FakePictureLayerTilingClient tiling_client;
tiling_client.SetTileSize(size);
std::unique_ptr<PictureLayerImpl> layer =
PictureLayerImpl::Create(host_impl()->active_tree(), 1, false);
PictureLayerTilingSet* tiling_set = layer->picture_layer_tiling_set();
layer->set_is_drawn_render_surface_layer_list_member(true);
auto* tiling = tiling_set->AddTiling(1.0f, raster);
tiling->set_resolution(resolutions[i]);
tiling->CreateAllTilesForTesting();
tiling->SetTilePriorityRectsForTesting(
gfx::Rect(size), // Visible rect.
gfx::Rect(size), // Skewport rect.
gfx::Rect(size), // Soon rect.
gfx::Rect(size)); // Eventually rect.
// SMOOTHNESS_TAKES_PRIORITY ensures that we will actually raster
// LOW_RESOLUTION tiles, otherwise they are skipped.
host_impl()->SetTreePriority(SMOOTHNESS_TAKES_PRIORITY);
// Call PrepareTiles and wait for it to complete.
auto* tile_manager = host_impl()->tile_manager();
base::RunLoop run_loop;
EXPECT_CALL(MockHostImpl(), NotifyAllTileTasksCompleted())
.WillOnce(testing::Invoke([&run_loop]() { run_loop.Quit(); }));
tile_manager->PrepareTiles(host_impl()->global_tile_state());
run_loop.Run();
tile_manager->Flush();
Tile* tile = tiling->TileAt(0, 0);
// The tile in the tiling was rastered.
EXPECT_EQ(TileDrawInfo::RESOURCE_MODE, tile->draw_info().mode());
EXPECT_TRUE(tile->draw_info().IsReadyToDraw());
ResourceProvider::ScopedReadLockSoftware lock(
host_impl()->resource_provider(), tile->draw_info().resource_id());
const SkBitmap* bitmap = lock.sk_bitmap();
for (int x = 0; x < size.width(); ++x) {
for (int y = 0; y < size.height(); ++y) {
SCOPED_TRACE(y);
SCOPED_TRACE(x);
if (resolutions[i] == LOW_RESOLUTION) {
// Since it's low res, the bitmap was not drawn, and the background
// (green) is visible instead.
ASSERT_EQ(SK_ColorGREEN, bitmap->getColor(x, y));
} else {
EXPECT_EQ(HIGH_RESOLUTION, resolutions[i]);
// Since it's high res, the bitmap (blue) was drawn, and the
// background is not visible.
ASSERT_EQ(SK_ColorBLUE, bitmap->getColor(x, y));
}
}
}
}
}
class ActivationTasksDoNotBlockReadyToDrawTest : public TileManagerTest {
protected:
std::unique_ptr<TaskGraphRunner> CreateTaskGraphRunner() override {
return base::MakeUnique<SynchronousTaskGraphRunner>();
}
std::unique_ptr<OutputSurface> CreateOutputSurface() override {
return FakeOutputSurface::CreateDelegating3d();
}
LayerTreeSettings CreateSettings() override {
LayerTreeSettings settings = TileManagerTest::CreateSettings();
settings.gpu_rasterization_forced = true;
return settings;
}
};
TEST_F(ActivationTasksDoNotBlockReadyToDrawTest,
ActivationTasksDoNotBlockReadyToDraw) {
const gfx::Size layer_bounds(1000, 1000);
EXPECT_TRUE(host_impl()->use_gpu_rasterization());
// Active tree has no non-solid tiles, so it will generate no tile tasks.
std::unique_ptr<FakeRecordingSource> active_tree_recording_source =
FakeRecordingSource::CreateFilledRecordingSource(layer_bounds);
SkPaint solid_paint;
SkColor solid_color = SkColorSetARGB(255, 12, 23, 34);
solid_paint.setColor(solid_color);
active_tree_recording_source->add_draw_rect_with_paint(
gfx::Rect(layer_bounds), solid_paint);
active_tree_recording_source->Rerecord();
// Pending tree has non-solid tiles, so it will generate tile tasks.
std::unique_ptr<FakeRecordingSource> pending_tree_recording_source =
FakeRecordingSource::CreateFilledRecordingSource(layer_bounds);
SkColor non_solid_color = SkColorSetARGB(128, 45, 56, 67);
SkPaint non_solid_paint;
non_solid_paint.setColor(non_solid_color);
pending_tree_recording_source->add_draw_rect_with_paint(
gfx::Rect(5, 5, 10, 10), non_solid_paint);
pending_tree_recording_source->Rerecord();
scoped_refptr<RasterSource> active_tree_raster_source =
RasterSource::CreateFromRecordingSource(
active_tree_recording_source.get(), false);
scoped_refptr<RasterSource> pending_tree_raster_source =
RasterSource::CreateFromRecordingSource(
pending_tree_recording_source.get(), false);
SetupTrees(pending_tree_raster_source, active_tree_raster_source);
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
// The first task to run should be ReadyToDraw (this should not be blocked by
// the tasks required for activation).
base::RunLoop run_loop;
EXPECT_CALL(MockHostImpl(), NotifyReadyToDraw())
.WillOnce(testing::Invoke([&run_loop]() { run_loop.Quit(); }));
static_cast<SynchronousTaskGraphRunner*>(task_graph_runner())
->RunSingleTaskForTesting();
run_loop.Run();
}
class PartialRasterTileManagerTest : public TileManagerTest {
public:
LayerTreeSettings CreateSettings() override {
LayerTreeSettings settings = TileManagerTest::CreateSettings();
settings.use_partial_raster = true;
return settings;
}
};
// Ensures that if a raster task is cancelled, it gets returned to the resource
// pool with an invalid content ID, not with its invalidated content ID.
TEST_F(PartialRasterTileManagerTest, CancelledTasksHaveNoContentId) {
// Create a FakeTileTaskManagerImpl and set it on the tile manager so that all
// scheduled work is immediately cancelled.
FakeTileTaskManagerImpl tile_task_manager;
host_impl()->tile_manager()->SetTileTaskManagerForTesting(&tile_task_manager);
// Pick arbitrary IDs - they don't really matter as long as they're constant.
const int kLayerId = 7;
const uint64_t kInvalidatedId = 43;
const gfx::Size kTileSize(128, 128);
scoped_refptr<FakeRasterSource> pending_raster_source =
FakeRasterSource::CreateFilled(kTileSize);
host_impl()->CreatePendingTree();
LayerTreeImpl* pending_tree = host_impl()->pending_tree();
// Steal from the recycled tree.
std::unique_ptr<FakePictureLayerImpl> pending_layer =
FakePictureLayerImpl::CreateWithRasterSource(pending_tree, kLayerId,
pending_raster_source);
pending_layer->SetDrawsContent(true);
pending_layer->SetHasRenderSurface(true);
// The bounds() just mirror the raster source size.
pending_layer->SetBounds(pending_layer->raster_source()->GetSize());
pending_tree->SetRootLayerForTesting(std::move(pending_layer));
// Add tilings/tiles for the layer.
host_impl()->pending_tree()->BuildLayerListAndPropertyTreesForTesting();
host_impl()->pending_tree()->UpdateDrawProperties(
false /* update_lcd_text */);
// Build the raster queue and invalidate the top tile.
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl()->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
queue->Top().tile()->SetInvalidated(gfx::Rect(), kInvalidatedId);
// PrepareTiles to schedule tasks. Due to the FakeTileTaskManagerImpl,
// these tasks will immediately be canceled.
host_impl()->tile_manager()->PrepareTiles(host_impl()->global_tile_state());
// Make sure that the tile we invalidated above was not returned to the pool
// with its invalidated resource ID.
host_impl()->resource_pool()->CheckBusyResources();
gfx::Rect total_invalidated_rect;
EXPECT_FALSE(host_impl()->resource_pool()->TryAcquireResourceForPartialRaster(
kInvalidatedId + 1, gfx::Rect(), kInvalidatedId,
&total_invalidated_rect));
EXPECT_EQ(gfx::Rect(), total_invalidated_rect);
// Free our host_impl_ before the tile_task_manager we passed it, as it
// will use that class in clean up.
TakeHostImpl();
}
// FakeRasterBufferProviderImpl that verifies the resource content ID of raster
// tasks.
class VerifyResourceContentIdRasterBufferProvider
: public FakeRasterBufferProviderImpl {
public:
explicit VerifyResourceContentIdRasterBufferProvider(
uint64_t expected_resource_id)
: expected_resource_id_(expected_resource_id) {}
~VerifyResourceContentIdRasterBufferProvider() override {}
// RasterBufferProvider methods.
std::unique_ptr<RasterBuffer> AcquireBufferForRaster(
const Resource* resource,
uint64_t resource_content_id,
uint64_t previous_content_id) override {
EXPECT_EQ(expected_resource_id_, resource_content_id);
return nullptr;
}
private:
uint64_t expected_resource_id_;
};
// Runs a test to ensure that partial raster is either enabled or disabled,
// depending on |partial_raster_enabled|'s value. Takes ownership of host_impl
// so that cleanup order can be controlled.
void RunPartialRasterCheck(std::unique_ptr<LayerTreeHostImpl> host_impl,
bool partial_raster_enabled) {
// Pick arbitrary IDs - they don't really matter as long as they're constant.
const int kLayerId = 7;
const uint64_t kInvalidatedId = 43;
const uint64_t kExpectedId = partial_raster_enabled ? kInvalidatedId : 0u;
const gfx::Size kTileSize(128, 128);
// Create a VerifyResourceContentIdTileTaskManager to ensure that the
// raster task we see is created with |kExpectedId|.
FakeTileTaskManagerImpl tile_task_manager;
host_impl->tile_manager()->SetTileTaskManagerForTesting(&tile_task_manager);
VerifyResourceContentIdRasterBufferProvider raster_buffer_provider(
kExpectedId);
host_impl->tile_manager()->SetRasterBufferProviderForTesting(
&raster_buffer_provider);
// Ensure there's a resource with our |kInvalidatedId| in the resource pool.
auto* resource = host_impl->resource_pool()->AcquireResource(
kTileSize, RGBA_8888, gfx::ColorSpace());
host_impl->resource_pool()->OnContentReplaced(resource->id(), kInvalidatedId);
host_impl->resource_pool()->ReleaseResource(resource);
host_impl->resource_pool()->CheckBusyResources();
scoped_refptr<FakeRasterSource> pending_raster_source =
FakeRasterSource::CreateFilled(kTileSize);
host_impl->CreatePendingTree();
LayerTreeImpl* pending_tree = host_impl->pending_tree();
// Steal from the recycled tree.
std::unique_ptr<FakePictureLayerImpl> pending_layer =
FakePictureLayerImpl::CreateWithRasterSource(pending_tree, kLayerId,
pending_raster_source);
pending_layer->SetDrawsContent(true);
pending_layer->SetHasRenderSurface(true);
// The bounds() just mirror the raster source size.
pending_layer->SetBounds(pending_layer->raster_source()->GetSize());
pending_tree->SetRootLayerForTesting(std::move(pending_layer));
// Add tilings/tiles for the layer.
host_impl->pending_tree()->BuildLayerListAndPropertyTreesForTesting();
host_impl->pending_tree()->UpdateDrawProperties(false /* update_lcd_text */);
// Build the raster queue and invalidate the top tile.
std::unique_ptr<RasterTilePriorityQueue> queue(host_impl->BuildRasterQueue(
SAME_PRIORITY_FOR_BOTH_TREES, RasterTilePriorityQueue::Type::ALL));
EXPECT_FALSE(queue->IsEmpty());
queue->Top().tile()->SetInvalidated(gfx::Rect(), kInvalidatedId);
// PrepareTiles to schedule tasks. Due to the
// VerifyPreviousContentRasterBufferProvider, these tasks will verified and
// cancelled.
host_impl->tile_manager()->PrepareTiles(host_impl->global_tile_state());
// Free our host_impl before the verifying_task_manager we passed it, as it
// will use that class in clean up.
host_impl = nullptr;
}
// Ensures that the tile manager successfully reuses tiles when partial
// raster is enabled.
TEST_F(PartialRasterTileManagerTest, PartialRasterSuccessfullyEnabled) {
RunPartialRasterCheck(TakeHostImpl(), true /* partial_raster_enabled */);
}
// Ensures that the tile manager does not attempt to reuse tiles when partial
// raster is disabled.
TEST_F(TileManagerTest, PartialRasterSuccessfullyDisabled) {
RunPartialRasterCheck(TakeHostImpl(), false /* partial_raster_enabled */);
}
} // namespace
} // namespace cc