// 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 "base/bind.h" #include "base/format_macros.h" #include "base/memory/scoped_vector.h" #include "base/strings/stringprintf.h" #include "base/synchronization/condition_variable.h" #include "base/synchronization/lock.h" #include "base/synchronization/waitable_event.h" #include "base/threading/thread.h" #include "base/time/time.h" #include "build/build_config.h" #include "testing/gtest/include/gtest/gtest.h" #include "testing/perf/perf_test.h" #if defined(OS_ANDROID) #include "base/android/java_handler_thread.h" #endif namespace base { namespace { class ScheduleWorkTest : public testing::Test { public: ScheduleWorkTest() : counter_(0) {} void Increment(uint64_t amount) { counter_ += amount; } void Schedule(int index) { base::TimeTicks start = base::TimeTicks::HighResNow(); base::TimeTicks thread_start; if (TimeTicks::IsThreadNowSupported()) thread_start = base::TimeTicks::ThreadNow(); base::TimeDelta minimum = base::TimeDelta::Max(); base::TimeDelta maximum = base::TimeDelta(); base::TimeTicks now, lastnow = start; uint64_t schedule_calls = 0u; do { for (size_t i = 0; i < kBatchSize; ++i) { target_message_loop()->ScheduleWork(); schedule_calls++; } now = base::TimeTicks::HighResNow(); base::TimeDelta laptime = now - lastnow; lastnow = now; minimum = std::min(minimum, laptime); maximum = std::max(maximum, laptime); } while (now - start < base::TimeDelta::FromSeconds(kTargetTimeSec)); scheduling_times_[index] = now - start; if (TimeTicks::IsThreadNowSupported()) scheduling_thread_times_[index] = base::TimeTicks::ThreadNow() - thread_start; min_batch_times_[index] = minimum; max_batch_times_[index] = maximum; target_message_loop()->PostTask(FROM_HERE, base::Bind(&ScheduleWorkTest::Increment, base::Unretained(this), schedule_calls)); } void ScheduleWork(MessageLoop::Type target_type, int num_scheduling_threads) { #if defined(OS_ANDROID) if (target_type == MessageLoop::TYPE_JAVA) { java_thread_.reset(new android::JavaHandlerThread("target")); java_thread_->Start(); } else #endif { target_.reset(new Thread("target")); target_->StartWithOptions(Thread::Options(target_type, 0u)); } ScopedVector scheduling_threads; scheduling_times_.reset(new base::TimeDelta[num_scheduling_threads]); scheduling_thread_times_.reset(new base::TimeDelta[num_scheduling_threads]); min_batch_times_.reset(new base::TimeDelta[num_scheduling_threads]); max_batch_times_.reset(new base::TimeDelta[num_scheduling_threads]); for (int i = 0; i < num_scheduling_threads; ++i) { scheduling_threads.push_back(new Thread("posting thread")); scheduling_threads[i]->Start(); } for (int i = 0; i < num_scheduling_threads; ++i) { scheduling_threads[i]->message_loop()->PostTask( FROM_HERE, base::Bind(&ScheduleWorkTest::Schedule, base::Unretained(this), i)); } for (int i = 0; i < num_scheduling_threads; ++i) { scheduling_threads[i]->Stop(); } #if defined(OS_ANDROID) if (target_type == MessageLoop::TYPE_JAVA) { java_thread_->Stop(); java_thread_.reset(); } else #endif { target_->Stop(); target_.reset(); } base::TimeDelta total_time; base::TimeDelta total_thread_time; base::TimeDelta min_batch_time = base::TimeDelta::Max(); base::TimeDelta max_batch_time = base::TimeDelta(); for (int i = 0; i < num_scheduling_threads; ++i) { total_time += scheduling_times_[i]; total_thread_time += scheduling_thread_times_[i]; min_batch_time = std::min(min_batch_time, min_batch_times_[i]); max_batch_time = std::max(max_batch_time, max_batch_times_[i]); } std::string trace = StringPrintf( "%d_threads_scheduling_to_%s_pump", num_scheduling_threads, target_type == MessageLoop::TYPE_IO ? "io" : (target_type == MessageLoop::TYPE_UI ? "ui" : "default")); perf_test::PrintResult( "task", "", trace, total_time.InMicroseconds() / static_cast(counter_), "us/task", true); perf_test::PrintResult( "task", "_min_batch_time", trace, min_batch_time.InMicroseconds() / static_cast(kBatchSize), "us/task", false); perf_test::PrintResult( "task", "_max_batch_time", trace, max_batch_time.InMicroseconds() / static_cast(kBatchSize), "us/task", false); if (TimeTicks::IsThreadNowSupported()) { perf_test::PrintResult( "task", "_thread_time", trace, total_thread_time.InMicroseconds() / static_cast(counter_), "us/task", true); } } MessageLoop* target_message_loop() { #if defined(OS_ANDROID) if (java_thread_) return java_thread_->message_loop(); #endif return target_->message_loop(); } private: scoped_ptr target_; #if defined(OS_ANDROID) scoped_ptr java_thread_; #endif scoped_ptr scheduling_times_; scoped_ptr scheduling_thread_times_; scoped_ptr min_batch_times_; scoped_ptr max_batch_times_; uint64_t counter_; static const size_t kTargetTimeSec = 5; static const size_t kBatchSize = 1000; }; TEST_F(ScheduleWorkTest, ThreadTimeToIOFromOneThread) { ScheduleWork(MessageLoop::TYPE_IO, 1); } TEST_F(ScheduleWorkTest, ThreadTimeToIOFromTwoThreads) { ScheduleWork(MessageLoop::TYPE_IO, 2); } TEST_F(ScheduleWorkTest, ThreadTimeToIOFromFourThreads) { ScheduleWork(MessageLoop::TYPE_IO, 4); } TEST_F(ScheduleWorkTest, ThreadTimeToUIFromOneThread) { ScheduleWork(MessageLoop::TYPE_UI, 1); } TEST_F(ScheduleWorkTest, ThreadTimeToUIFromTwoThreads) { ScheduleWork(MessageLoop::TYPE_UI, 2); } TEST_F(ScheduleWorkTest, ThreadTimeToUIFromFourThreads) { ScheduleWork(MessageLoop::TYPE_UI, 4); } TEST_F(ScheduleWorkTest, ThreadTimeToDefaultFromOneThread) { ScheduleWork(MessageLoop::TYPE_DEFAULT, 1); } TEST_F(ScheduleWorkTest, ThreadTimeToDefaultFromTwoThreads) { ScheduleWork(MessageLoop::TYPE_DEFAULT, 2); } TEST_F(ScheduleWorkTest, ThreadTimeToDefaultFromFourThreads) { ScheduleWork(MessageLoop::TYPE_DEFAULT, 4); } #if defined(OS_ANDROID) TEST_F(ScheduleWorkTest, ThreadTimeToJavaFromOneThread) { ScheduleWork(MessageLoop::TYPE_JAVA, 1); } TEST_F(ScheduleWorkTest, ThreadTimeToJavaFromTwoThreads) { ScheduleWork(MessageLoop::TYPE_JAVA, 2); } TEST_F(ScheduleWorkTest, ThreadTimeToJavaFromFourThreads) { ScheduleWork(MessageLoop::TYPE_JAVA, 4); } #endif static void DoNothing() { } class FakeMessagePump : public MessagePump { public: FakeMessagePump() {} ~FakeMessagePump() override {} void Run(Delegate* delegate) override {} void Quit() override {} void ScheduleWork() override {} void ScheduleDelayedWork(const TimeTicks& delayed_work_time) override {} }; class PostTaskTest : public testing::Test { public: void Run(int batch_size, int tasks_per_reload) { base::TimeTicks start = base::TimeTicks::HighResNow(); base::TimeTicks now; MessageLoop loop(scoped_ptr(new FakeMessagePump)); scoped_refptr queue( new internal::IncomingTaskQueue(&loop)); uint32_t num_posted = 0; do { for (int i = 0; i < batch_size; ++i) { for (int j = 0; j < tasks_per_reload; ++j) { queue->AddToIncomingQueue( FROM_HERE, base::Bind(&DoNothing), base::TimeDelta(), false); num_posted++; } TaskQueue loop_local_queue; queue->ReloadWorkQueue(&loop_local_queue); while (!loop_local_queue.empty()) { PendingTask t = loop_local_queue.front(); loop_local_queue.pop(); loop.RunTask(t); } } now = base::TimeTicks::HighResNow(); } while (now - start < base::TimeDelta::FromSeconds(5)); std::string trace = StringPrintf("%d_tasks_per_reload", tasks_per_reload); perf_test::PrintResult( "task", "", trace, (now - start).InMicroseconds() / static_cast(num_posted), "us/task", true); } }; TEST_F(PostTaskTest, OneTaskPerReload) { Run(10000, 1); } TEST_F(PostTaskTest, TenTasksPerReload) { Run(10000, 10); } TEST_F(PostTaskTest, OneHundredTasksPerReload) { Run(1000, 100); } } // namespace } // namespace base