runtime/vm/thread_pool_test.cc - sdk - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #include "vm/thread_pool.h"
 #include "vm/lockers.h"
 #include "vm/os.h"
 #include "vm/unit_test.h"

 namespace dart {

 DECLARE_FLAG(int, worker_timeout_millis);

 VM_UNIT_TEST_CASE(ThreadPool_Create) {
   ThreadPool thread_pool;
 }

 class TestTask : public ThreadPool::Task {
  public:
   TestTask(Monitor* sync, bool* done) : sync_(sync), done_(done) {}

   // Before running the task, *done_ should be true. This lets the caller
   // ASSERT things knowing that the thread is still around. To unblock the
   // thread, the caller should take the lock, set *done_ to false, and Notify()
   // the monitor.
   virtual void Run() {
     {
       MonitorLocker ml(sync_);
       while (*done_) {
         ml.Wait();
       }
     }
     MonitorLocker ml(sync_);
     *done_ = true;
     ml.Notify();
   }

  private:
   Monitor* sync_;
   bool* done_;
 };

 VM_UNIT_TEST_CASE(ThreadPool_RunOne) {
   ThreadPool thread_pool;
   Monitor sync;
   bool done = true;
   thread_pool.Run(new TestTask(&sync, &done));
   {
     MonitorLocker ml(&sync);
     done = false;
     ml.Notify();
     while (!done) {
       ml.Wait();
     }
   }
   EXPECT(done);

   // Do a sanity test on the worker stats.
   EXPECT_EQ(1U, thread_pool.workers_started());
   EXPECT_EQ(0U, thread_pool.workers_stopped());
 }

 VM_UNIT_TEST_CASE(ThreadPool_RunMany) {
   const int kTaskCount = 100;
   ThreadPool thread_pool;
   Monitor sync[kTaskCount];
   bool done[kTaskCount];

   for (int i = 0; i < kTaskCount; i++) {
     done[i] = true;
     thread_pool.Run(new TestTask(&sync[i], &done[i]));
   }
   for (int i = 0; i < kTaskCount; i++) {
     MonitorLocker ml(&sync[i]);
     done[i] = false;
     ml.Notify();
     while (!done[i]) {
       ml.Wait();
     }
     EXPECT(done[i]);
   }
 }

 class SleepTask : public ThreadPool::Task {
  public:
   SleepTask(Monitor* sync, int* started_count, int* slept_count, int millis)
       : sync_(sync),
         started_count_(started_count),
         slept_count_(slept_count),
         millis_(millis) {}

   virtual void Run() {
     {
       MonitorLocker ml(sync_);
       *started_count_ = *started_count_ + 1;
       ml.Notify();
     }
     // Sleep so we can be sure the ThreadPool destructor blocks until we're
     // done.
     OS::Sleep(millis_);
     {
       MonitorLocker ml(sync_);
       *slept_count_ = *slept_count_ + 1;
       // No notification here. The main thread is blocked in ThreadPool
       // shutdown waiting for this thread to finish.
     }
   }

  private:
   Monitor* sync_;
   int* started_count_;
   int* slept_count_;
   int millis_;
 };

 VM_UNIT_TEST_CASE(ThreadPool_WorkerShutdown) {
   const int kTaskCount = 10;
   Monitor sync;
   int slept_count = 0;
   int started_count = 0;

   // Set up the ThreadPool so that workers notify before they exit.
   ThreadPool* thread_pool = new ThreadPool();

   // Run a single task.
   for (int i = 0; i < kTaskCount; i++) {
     thread_pool->Run(new SleepTask(&sync, &started_count, &slept_count, 2));
   }

   {
     // Wait for everybody to start.
     MonitorLocker ml(&sync);
     while (started_count < kTaskCount) {
       ml.Wait();
     }
   }

   // Kill the thread pool while the workers are sleeping.
   delete thread_pool;
   thread_pool = NULL;

   int final_count = 0;
   {
     MonitorLocker ml(&sync);
     final_count = slept_count;
   }

   // We should have waited for all the workers to finish, so they all should
   // have had a chance to increment slept_count.
   EXPECT_EQ(kTaskCount, final_count);
 }

 VM_UNIT_TEST_CASE(ThreadPool_WorkerTimeout) {
   // Adjust the worker timeout so that we timeout quickly.
   int saved_timeout = FLAG_worker_timeout_millis;
   FLAG_worker_timeout_millis = 1;

   ThreadPool thread_pool;
   EXPECT_EQ(0U, thread_pool.workers_started());
   EXPECT_EQ(0U, thread_pool.workers_stopped());

   // Run a worker.
   Monitor sync;
   bool done = true;
   thread_pool.Run(new TestTask(&sync, &done));
   EXPECT_EQ(1U, thread_pool.workers_started());
   EXPECT_EQ(0U, thread_pool.workers_stopped());
   {
     MonitorLocker ml(&sync);
     done = false;
     ml.Notify();
     while (!done) {
       ml.Wait();
     }
   }
   EXPECT(done);

   // Wait up to 5 seconds to see if a worker times out.
   const int kMaxWait = 5000;
   int waited = 0;
   while (thread_pool.workers_stopped() == 0 && waited < kMaxWait) {
     OS::Sleep(1);
     waited += 1;
   }
   EXPECT_EQ(1U, thread_pool.workers_stopped());
   FLAG_worker_timeout_millis = saved_timeout;
 }

 class SpawnTask : public ThreadPool::Task {
  public:
   SpawnTask(ThreadPool* pool, Monitor* sync, int todo, int total, int* done)
       : pool_(pool), sync_(sync), todo_(todo), total_(total), done_(done) {}

   virtual void Run() {
     todo_--;  // Subtract one for current task.
     int child_todo = todo_ / 2;

     // Spawn 0-2 children.
     if (todo_ > 0) {
       pool_->Run(
           new SpawnTask(pool_, sync_, todo_ - child_todo, total_, done_));
     }
     if (todo_ > 1) {
       pool_->Run(new SpawnTask(pool_, sync_, child_todo, total_, done_));
     }

     {
       MonitorLocker ml(sync_);
       (*done_)++;
       if (*done_ >= total_) {
         ml.Notify();
       }
     }
   }

  private:
   ThreadPool* pool_;
   Monitor* sync_;
   int todo_;
   int total_;
   int* done_;
 };

 VM_UNIT_TEST_CASE(ThreadPool_RecursiveSpawn) {
   ThreadPool thread_pool;
   Monitor sync;
   const int kTotalTasks = 500;
   int done = 0;
   thread_pool.Run(
       new SpawnTask(&thread_pool, &sync, kTotalTasks, kTotalTasks, &done));
   {
     MonitorLocker ml(&sync);
     while (done < kTotalTasks) {
       ml.Wait();
     }
   }
   EXPECT_EQ(kTotalTasks, done);
 }

 }  // namespace dart
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#include "vm/thread_pool.h"
	#include "vm/lockers.h"
	#include "vm/os.h"
	#include "vm/unit_test.h"

	namespace dart {

	DECLARE_FLAG(int, worker_timeout_millis);

	VM_UNIT_TEST_CASE(ThreadPool_Create) {
	ThreadPool thread_pool;
	}

	class TestTask : public ThreadPool::Task {
	public:
	TestTask(Monitor* sync, bool* done) : sync_(sync), done_(done) {}

	// Before running the task, *done_ should be true. This lets the caller
	// ASSERT things knowing that the thread is still around. To unblock the
	// thread, the caller should take the lock, set *done_ to false, and Notify()
	// the monitor.
	virtual void Run() {
	{
	MonitorLocker ml(sync_);
	while (*done_) {
	ml.Wait();
	}
	}
	MonitorLocker ml(sync_);
	*done_ = true;
	ml.Notify();
	}

	private:
	Monitor* sync_;
	bool* done_;
	};

	VM_UNIT_TEST_CASE(ThreadPool_RunOne) {
	ThreadPool thread_pool;
	Monitor sync;
	bool done = true;
	thread_pool.Run(new TestTask(&sync, &done));
	{
	MonitorLocker ml(&sync);
	done = false;
	ml.Notify();
	while (!done) {
	ml.Wait();
	}
	}
	EXPECT(done);

	// Do a sanity test on the worker stats.
	EXPECT_EQ(1U, thread_pool.workers_started());
	EXPECT_EQ(0U, thread_pool.workers_stopped());
	}

	VM_UNIT_TEST_CASE(ThreadPool_RunMany) {
	const int kTaskCount = 100;
	ThreadPool thread_pool;
	Monitor sync[kTaskCount];
	bool done[kTaskCount];

	for (int i = 0; i < kTaskCount; i++) {
	done[i] = true;
	thread_pool.Run(new TestTask(&sync[i], &done[i]));
	}
	for (int i = 0; i < kTaskCount; i++) {
	MonitorLocker ml(&sync[i]);
	done[i] = false;
	ml.Notify();
	while (!done[i]) {
	ml.Wait();
	}
	EXPECT(done[i]);
	}
	}

	class SleepTask : public ThreadPool::Task {
	public:
	SleepTask(Monitor* sync, int* started_count, int* slept_count, int millis)
	: sync_(sync),
	started_count_(started_count),
	slept_count_(slept_count),
	millis_(millis) {}

	virtual void Run() {
	{
	MonitorLocker ml(sync_);
	started_count_ = started_count_ + 1;
	ml.Notify();
	}
	// Sleep so we can be sure the ThreadPool destructor blocks until we're
	// done.
	OS::Sleep(millis_);
	{
	MonitorLocker ml(sync_);
	slept_count_ = slept_count_ + 1;
	// No notification here. The main thread is blocked in ThreadPool
	// shutdown waiting for this thread to finish.
	}
	}

	private:
	Monitor* sync_;
	int* started_count_;
	int* slept_count_;
	int millis_;
	};

	VM_UNIT_TEST_CASE(ThreadPool_WorkerShutdown) {
	const int kTaskCount = 10;
	Monitor sync;
	int slept_count = 0;
	int started_count = 0;

	// Set up the ThreadPool so that workers notify before they exit.
	ThreadPool* thread_pool = new ThreadPool();

	// Run a single task.
	for (int i = 0; i < kTaskCount; i++) {
	thread_pool->Run(new SleepTask(&sync, &started_count, &slept_count, 2));
	}

	{
	// Wait for everybody to start.
	MonitorLocker ml(&sync);
	while (started_count < kTaskCount) {
	ml.Wait();
	}
	}

	// Kill the thread pool while the workers are sleeping.
	delete thread_pool;
	thread_pool = NULL;

	int final_count = 0;
	{
	MonitorLocker ml(&sync);
	final_count = slept_count;
	}

	// We should have waited for all the workers to finish, so they all should
	// have had a chance to increment slept_count.
	EXPECT_EQ(kTaskCount, final_count);
	}

	VM_UNIT_TEST_CASE(ThreadPool_WorkerTimeout) {
	// Adjust the worker timeout so that we timeout quickly.
	int saved_timeout = FLAG_worker_timeout_millis;
	FLAG_worker_timeout_millis = 1;

	ThreadPool thread_pool;
	EXPECT_EQ(0U, thread_pool.workers_started());
	EXPECT_EQ(0U, thread_pool.workers_stopped());

	// Run a worker.
	Monitor sync;
	bool done = true;
	thread_pool.Run(new TestTask(&sync, &done));
	EXPECT_EQ(1U, thread_pool.workers_started());
	EXPECT_EQ(0U, thread_pool.workers_stopped());
	{
	MonitorLocker ml(&sync);
	done = false;
	ml.Notify();
	while (!done) {
	ml.Wait();
	}
	}
	EXPECT(done);

	// Wait up to 5 seconds to see if a worker times out.
	const int kMaxWait = 5000;
	int waited = 0;
	while (thread_pool.workers_stopped() == 0 && waited < kMaxWait) {
	OS::Sleep(1);
	waited += 1;
	}
	EXPECT_EQ(1U, thread_pool.workers_stopped());
	FLAG_worker_timeout_millis = saved_timeout;
	}

	class SpawnTask : public ThreadPool::Task {
	public:
	SpawnTask(ThreadPool* pool, Monitor* sync, int todo, int total, int* done)
	: pool_(pool), sync_(sync), todo_(todo), total_(total), done_(done) {}

	virtual void Run() {
	todo_--; // Subtract one for current task.
	int child_todo = todo_ / 2;

	// Spawn 0-2 children.
	if (todo_ > 0) {
	pool_->Run(
	new SpawnTask(pool_, sync_, todo_ - child_todo, total_, done_));
	}
	if (todo_ > 1) {
	pool_->Run(new SpawnTask(pool_, sync_, child_todo, total_, done_));
	}

	{
	MonitorLocker ml(sync_);
	(*done_)++;
	if (*done_ >= total_) {
	ml.Notify();
	}
	}
	}

	private:
	ThreadPool* pool_;
	Monitor* sync_;
	int todo_;
	int total_;
	int* done_;
	};

	VM_UNIT_TEST_CASE(ThreadPool_RecursiveSpawn) {
	ThreadPool thread_pool;
	Monitor sync;
	const int kTotalTasks = 500;
	int done = 0;
	thread_pool.Run(
	new SpawnTask(&thread_pool, &sync, kTotalTasks, kTotalTasks, &done));
	{
	MonitorLocker ml(&sync);
	while (done < kTotalTasks) {
	ml.Wait();
	}
	}
	EXPECT_EQ(kTotalTasks, done);
	}

	} // namespace dart