blob: 11eb86ae0fbaa6f92313bde21a441fbce0c894cb [file] [log] [blame]
// Copyright 2015 Google Inc. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "base/string_util.h"
#include "base/synchronization/waitable_event.h"
#include "cobalt/base/event_dispatcher.h"
#include "cobalt/dom/benchmark_stat_names.h"
#include "cobalt/layout/benchmark_stat_names.h"
#include "cobalt/layout_tests/layout_snapshot.h"
#include "cobalt/layout_tests/test_parser.h"
#include "cobalt/math/size.h"
#include "cobalt/renderer/pipeline.h"
#include "cobalt/renderer/renderer_module.h"
#include "cobalt/renderer/submission.h"
#include "cobalt/system_window/system_window.h"
#include "cobalt/trace_event/benchmark.h"
#include "googleurl/src/gurl.h"
namespace cobalt {
namespace layout_tests {
namespace {
const int kViewportWidth = 1920;
const int kViewportHeight = 1080;
// The RendererBenchmarkRunner sets up an environment where we can control
// the number of benchmark samples we acquire from the renderer by counting
// each time the renderer submit complete callback is made. It also manages
// the skipping of the first frame to avoid the first frame outlier.
class RendererBenchmarkRunner {
public:
RendererBenchmarkRunner()
: done_gathering_samples_(true, false),
system_window_(new system_window::SystemWindow(
&event_dispatcher_, math::Size(kViewportWidth, kViewportHeight))) {
// Since we'd like to measure the renderer, we force it to rasterize each
// frame despite the fact that the render tree may not be changing.
renderer::RendererModule::Options renderer_options;
renderer_options.submit_even_if_render_tree_is_unchanged = true;
renderer_module_.emplace(system_window_.get(), renderer_options);
}
// Return the resource provider from the internal renderer so that it can
// be used during layout.
render_tree::ResourceProvider* GetResourceProvider() {
return renderer_module_->pipeline()->GetResourceProvider();
}
// Run the renderer benchmarks and perform the measurements.
void RunBenchmarks(const browser::WebModule::LayoutResults& layout_results,
int samples_to_gather) {
// Initialize our per-RunBenchmarks() state.
samples_to_gather_ = samples_to_gather;
done_gathering_samples_.Reset();
renderer::Submission submission_with_callback(layout_results.render_tree,
layout_results.layout_time);
submission_with_callback.on_rasterized_callback = base::Bind(
&RendererBenchmarkRunner::OnSubmitComplete, base::Unretained(this));
renderer_module_->pipeline()->Submit(submission_with_callback);
done_gathering_samples_.Wait();
renderer_module_->pipeline()->Clear();
}
private:
// Called whenever the renderer completes a frame submission. This allows us
// to count how many frames have been submitted so we know when to stop (via
// the signaling of the done_gathering_samples_ event).
void OnSubmitComplete() {
--samples_to_gather_;
// We wait for samples_to_gather + 1 submits to complete because we actually
// want samples_to_gather, but we skipped the first submit.
if (samples_to_gather_ <= 0) {
done_gathering_samples_.Signal();
}
}
int samples_to_gather_;
base::WaitableEvent done_gathering_samples_;
base::EventDispatcher event_dispatcher_;
scoped_ptr<system_window::SystemWindow> system_window_;
base::optional<renderer::RendererModule> renderer_module_;
};
} // namespace
class LayoutBenchmark : public trace_event::Benchmark {
public:
explicit LayoutBenchmark(const TestInfo& test_info);
~LayoutBenchmark() OVERRIDE {}
void Experiment() OVERRIDE;
void AnalyzeTraceEvent(
const scoped_refptr<trace_event::EventParser::ScopedEvent>& event)
OVERRIDE;
std::vector<trace_event::Benchmark::Result> CompileResults() OVERRIDE;
private:
typedef base::hash_map<std::string, double> IntermediateResultsMap;
typedef base::hash_map<std::string, std::vector<double> >
FinalResultsSampleMap;
void OnIterationComplete();
static std::string FilePathToBenchmarkName(const FilePath& filepath);
TestInfo test_info_;
// During each iteration, we accumulate intermediate results by *adding*
// task times together. Only when the iteration is complete do we consider
// our result a sample.
IntermediateResultsMap intermediate_results_;
// A list of accumulated intermediate results. The vectors in this map are
// pushed to at the end of each iteration.
FinalResultsSampleMap layout_samples_;
FinalResultsSampleMap renderer_samples_;
// Is this our first iteration?
bool first_iteration_;
// We setup the renderer benchmark runner first so that we can gain access
// to the resource provider and so that we can also benchmark the rendering
// of the layed out web pages.
RendererBenchmarkRunner renderer_benchmark_runner_;
};
LayoutBenchmark::LayoutBenchmark(const TestInfo& test_info)
: test_info_(test_info), first_iteration_(true) {
// Setup the name's benchmark based on the test entry file path.
set_name(FilePathToBenchmarkName(test_info_.base_file_path));
set_num_iterations(10, base::Bind(&LayoutBenchmark::OnIterationComplete,
base::Unretained(this)));
// Define the set of event names that we would like to watch for by
// initializing their map entries to the default constructed values (e.g.
// std::vector<double>()).
layout_samples_[layout::kBenchmarkStatLayout];
layout_samples_[dom::kBenchmarkStatUpdateSelectorTree];
layout_samples_[dom::kBenchmarkStatUpdateComputedStyles];
layout_samples_[layout::kBenchmarkStatBoxGeneration];
layout_samples_[layout::kBenchmarkStatUpdateCrossReferences];
layout_samples_[layout::kBenchmarkStatUpdateUsedSizes];
layout_samples_[layout::kBenchmarkStatRenderAndAnimate];
renderer_samples_["AnimateNode::Apply()"];
renderer_samples_["VisitRenderTree"];
renderer_samples_["Skia Flush"];
}
std::string LayoutBenchmark::FilePathToBenchmarkName(const FilePath& filepath) {
std::vector<FilePath::StringType> components;
filepath.GetComponents(&components);
// Don't include the "benchmarks" directory as part of the benchmark name.
components.erase(components.begin());
return JoinString(components, '/');
}
void LayoutBenchmark::Experiment() {
MessageLoop message_loop(MessageLoop::TYPE_DEFAULT);
// We prepare a layout_results variable where we place the results from each
// layout. We will then use the final layout_results as input to the renderer
// benchmark.
base::optional<browser::WebModule::LayoutResults> layout_results;
const math::Size kDefaultViewportSize(1920, 1080);
math::Size viewport_size = test_info_.viewport_size
? *test_info_.viewport_size
: kDefaultViewportSize;
// Set up a WebModule, load the URL and trigger layout to get layout benchmark
// results.
layout_results =
SnapshotURL(test_info_.url, viewport_size,
renderer_benchmark_runner_.GetResourceProvider());
// Finally run the renderer benchmarks to acquire performance data on
// rendering.
renderer_benchmark_runner_.RunBenchmarks(*layout_results, 60);
}
namespace {
// Return true if the event has an ancestor with the specified named event.
bool HasAncestorEvent(
const scoped_refptr<trace_event::EventParser::ScopedEvent>& event,
const std::string& ancestor_event_string) {
scoped_refptr<trace_event::EventParser::ScopedEvent> ancestor_event =
event->parent();
while (ancestor_event) {
if (ancestor_event->name() == ancestor_event_string) {
break;
}
ancestor_event = ancestor_event->parent();
}
return ancestor_event.get() != NULL;
}
} // namespace
void LayoutBenchmark::AnalyzeTraceEvent(
const scoped_refptr<trace_event::EventParser::ScopedEvent>& event) {
// Check if this is a layout sample.
if (event->name() == layout::kBenchmarkStatNonMeasuredLayout) {
// If this is a layout that should not be measured, use that as a signal
// that we are measuring partial layout, and clear out all measured data
// so far and start fresh for the eventual measured layout.
intermediate_results_.clear();
return;
}
FinalResultsSampleMap::iterator found_layout =
layout_samples_.find(event->name());
if (found_layout != layout_samples_.end() &&
!HasAncestorEvent(event, layout::kBenchmarkStatNonMeasuredLayout)) {
if (!ContainsKey(intermediate_results_, found_layout->first)) {
intermediate_results_[found_layout->first] = 0;
}
double event_duration = event->in_scope_duration()->InSecondsF();
intermediate_results_[found_layout->first] += event_duration;
if (event->name() != layout::kBenchmarkStatLayout &&
!HasAncestorEvent(event, layout::kBenchmarkStatLayout)) {
// If the event (which we have specifically requested to include in
// the benchmark results) does not fall under the scope of the official
// layout event, artificially increase the tracked layout time to include
// it. This way events can occur at any time, and the scoped layout
// event still gives us a way to measure unaccounted for time that we
// know is devoted to layout.
intermediate_results_[layout::kBenchmarkStatLayout] += event_duration;
}
}
FinalResultsSampleMap::iterator found_renderer =
renderer_samples_.find(event->name());
if (found_renderer != renderer_samples_.end()) {
found_renderer->second.push_back(event->in_scope_duration()->InSecondsF());
}
}
void LayoutBenchmark::OnIterationComplete() {
// Skip recording the results of the first iteration, since a few things
// may have been lazily initialized and we'd like to avoid recording that.
if (first_iteration_) {
for (FinalResultsSampleMap::iterator iter = renderer_samples_.begin();
iter != renderer_samples_.end(); ++iter) {
iter->second.clear();
}
} else {
// Save our finalized intermediate results into our finalized results, and
// then clear out our intermediate results for the next iteration.
for (FinalResultsSampleMap::iterator iter = layout_samples_.begin();
iter != layout_samples_.end(); ++iter) {
if (ContainsKey(intermediate_results_, iter->first)) {
iter->second.push_back(intermediate_results_[iter->first]);
}
}
}
first_iteration_ = false;
intermediate_results_.clear();
}
std::vector<trace_event::Benchmark::Result> LayoutBenchmark::CompileResults() {
std::vector<trace_event::Benchmark::Result> results;
for (FinalResultsSampleMap::iterator iter = layout_samples_.begin();
iter != layout_samples_.end(); ++iter) {
results.push_back(trace_event::Benchmark::Result(
iter->first + " in-scope duration in seconds", iter->second));
}
for (FinalResultsSampleMap::iterator iter = renderer_samples_.begin();
iter != renderer_samples_.end(); ++iter) {
results.push_back(trace_event::Benchmark::Result(
iter->first + " in-scope duration in seconds", iter->second));
}
return results;
}
class LayoutBenchmarkCreator : public trace_event::BenchmarkCreator {
public:
std::vector<CreateBenchmarkFunction> GetBenchmarkCreators() OVERRIDE {
std::vector<CreateBenchmarkFunction> benchmarks;
std::vector<TestInfo> benchmark_infos = EnumerateLayoutTests("benchmarks");
for (std::vector<TestInfo>::const_iterator iter = benchmark_infos.begin();
iter != benchmark_infos.end(); ++iter) {
benchmarks.push_back(
base::Bind(&LayoutBenchmarkCreator::CreateLayoutBenchmark, *iter));
}
return benchmarks;
}
private:
static scoped_ptr<trace_event::Benchmark> CreateLayoutBenchmark(
const TestInfo& test_info) {
return scoped_ptr<trace_event::Benchmark>(new LayoutBenchmark(test_info));
}
};
LayoutBenchmarkCreator g_benchmark_creator;
} // namespace layout_tests
} // namespace cobalt