webrtc/base/task_unittest.cc - src - Git at Google

 /*
  *  Copyright 2004 The WebRTC Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #if defined(WEBRTC_POSIX)
 #include <sys/time.h>
 #endif  // WEBRTC_POSIX

 // TODO: Remove this once the cause of sporadic failures in these
 // tests is tracked down.
 #include <iostream>

 #if defined(WEBRTC_WIN)
 #include "webrtc/base/win32.h"
 #endif  // WEBRTC_WIN

 #include "webrtc/base/arraysize.h"
 #include "webrtc/base/common.h"
 #include "webrtc/base/constructormagic.h"
 #include "webrtc/base/gunit.h"
 #include "webrtc/base/logging.h"
 #include "webrtc/base/task.h"
 #include "webrtc/base/taskrunner.h"
 #include "webrtc/base/thread.h"
 #include "webrtc/base/timeutils.h"

 namespace rtc {

 static int64_t GetCurrentTime() {
   return TimeMillis() * 10000;
 }

 // feel free to change these numbers.  Note that '0' won't work, though
 #define STUCK_TASK_COUNT 5
 #define HAPPY_TASK_COUNT 20

 // this is a generic timeout task which, when it signals timeout, will
 // include the unique ID of the task in the signal (we don't use this
 // in production code because we haven't yet had occasion to generate
 // an array of the same types of task)

 class IdTimeoutTask : public Task, public sigslot::has_slots<> {
  public:
   explicit IdTimeoutTask(TaskParent *parent) : Task(parent) {
     SignalTimeout.connect(this, &IdTimeoutTask::OnLocalTimeout);
   }

   sigslot::signal1<const int> SignalTimeoutId;
   sigslot::signal1<const int> SignalDoneId;

   virtual int ProcessStart() {
     return STATE_RESPONSE;
   }

   void OnLocalTimeout() {
     SignalTimeoutId(unique_id());
   }

  protected:
   virtual void Stop() {
     SignalDoneId(unique_id());
     Task::Stop();
   }
 };

 class StuckTask : public IdTimeoutTask {
  public:
   explicit StuckTask(TaskParent *parent) : IdTimeoutTask(parent) {}
   virtual int ProcessStart() {
     return STATE_BLOCKED;
   }
 };

 class HappyTask : public IdTimeoutTask {
  public:
   explicit HappyTask(TaskParent *parent) : IdTimeoutTask(parent) {
     time_to_perform_ = rand() % (STUCK_TASK_COUNT / 2);
   }
   virtual int ProcessStart() {
     if (ElapsedTime() > (time_to_perform_ * 1000 * 10000))
       return STATE_RESPONSE;
     else
       return STATE_BLOCKED;
   }

  private:
   int time_to_perform_;
 };

 // simple implementation of a task runner which uses Windows'
 // GetSystemTimeAsFileTime() to get the current clock ticks

 class MyTaskRunner : public TaskRunner {
  public:
   virtual void WakeTasks() { RunTasks(); }
   virtual int64_t CurrentTime() { return GetCurrentTime(); }

   bool timeout_change() const {
     return timeout_change_;
   }

   void clear_timeout_change() {
     timeout_change_ = false;
   }
  protected:
   virtual void OnTimeoutChange() {
     timeout_change_ = true;
   }
   bool timeout_change_;
 };

 //
 // this unit test is primarily concerned (for now) with the timeout
 // functionality in tasks.  It works as follows:
 //
 //   * Create a bunch of tasks, some "stuck" (ie., guaranteed to timeout)
 //     and some "happy" (will immediately finish).
 //   * Set the timeout on the "stuck" tasks to some number of seconds between
 //     1 and the number of stuck tasks
 //   * Start all the stuck & happy tasks in random order
 //   * Wait "number of stuck tasks" seconds and make sure everything timed out

 class TaskTest : public sigslot::has_slots<> {
  public:
   TaskTest() {}

   // no need to delete any tasks; the task runner owns them
   ~TaskTest() {}

   void Start() {
     // create and configure tasks
     for (int i = 0; i < STUCK_TASK_COUNT; ++i) {
       stuck_[i].task_ = new StuckTask(&task_runner_);
       stuck_[i].task_->SignalTimeoutId.connect(this,
                                                &TaskTest::OnTimeoutStuck);
       stuck_[i].timed_out_ = false;
       stuck_[i].xlat_ = stuck_[i].task_->unique_id();
       stuck_[i].task_->set_timeout_seconds(i + 1);
       LOG(LS_INFO) << "Task " << stuck_[i].xlat_ << " created with timeout "
                    << stuck_[i].task_->timeout_seconds();
     }

     for (int i = 0; i < HAPPY_TASK_COUNT; ++i) {
       happy_[i].task_ = new HappyTask(&task_runner_);
       happy_[i].task_->SignalTimeoutId.connect(this,
                                                &TaskTest::OnTimeoutHappy);
       happy_[i].task_->SignalDoneId.connect(this,
                                             &TaskTest::OnDoneHappy);
       happy_[i].timed_out_ = false;
       happy_[i].xlat_ = happy_[i].task_->unique_id();
     }

     // start all the tasks in random order
     int stuck_index = 0;
     int happy_index = 0;
     for (int i = 0; i < STUCK_TASK_COUNT + HAPPY_TASK_COUNT; ++i) {
       if ((stuck_index < STUCK_TASK_COUNT) &&
           (happy_index < HAPPY_TASK_COUNT)) {
         if (rand() % 2 == 1) {
           stuck_[stuck_index++].task_->Start();
         } else {
           happy_[happy_index++].task_->Start();
         }
       } else if (stuck_index < STUCK_TASK_COUNT) {
         stuck_[stuck_index++].task_->Start();
       } else {
         happy_[happy_index++].task_->Start();
       }
     }

     for (int i = 0; i < STUCK_TASK_COUNT; ++i) {
       std::cout << "Stuck task #" << i << " timeout is " <<
           stuck_[i].task_->timeout_seconds() << " at " <<
           stuck_[i].task_->timeout_time() << std::endl;
     }

     // just a little self-check to make sure we started all the tasks
     ASSERT_EQ(STUCK_TASK_COUNT, stuck_index);
     ASSERT_EQ(HAPPY_TASK_COUNT, happy_index);

     // run the unblocked tasks
     LOG(LS_INFO) << "Running tasks";
     task_runner_.RunTasks();

     std::cout << "Start time is " << GetCurrentTime() << std::endl;

     // give all the stuck tasks time to timeout
     for (int i = 0; !task_runner_.AllChildrenDone() && i < STUCK_TASK_COUNT;
          ++i) {
       Thread::Current()->ProcessMessages(1000);
       for (int j = 0; j < HAPPY_TASK_COUNT; ++j) {
         if (happy_[j].task_) {
           happy_[j].task_->Wake();
         }
       }
       LOG(LS_INFO) << "Polling tasks";
       task_runner_.PollTasks();
     }

     // We see occasional test failures here due to the stuck tasks not having
     // timed-out yet, which seems like it should be impossible. To help track
     // this down we have added logging of the timing information, which we send
     // directly to stdout so that we get it in opt builds too.
     std::cout << "End time is " << GetCurrentTime() << std::endl;
   }

   void OnTimeoutStuck(const int id) {
     LOG(LS_INFO) << "Timed out task " << id;

     int i;
     for (i = 0; i < STUCK_TASK_COUNT; ++i) {
       if (stuck_[i].xlat_ == id) {
         stuck_[i].timed_out_ = true;
         stuck_[i].task_ = NULL;
         break;
       }
     }

     // getting a bad ID here is a failure, but let's continue
     // running to see what else might go wrong
     EXPECT_LT(i, STUCK_TASK_COUNT);
   }

   void OnTimeoutHappy(const int id) {
     int i;
     for (i = 0; i < HAPPY_TASK_COUNT; ++i) {
       if (happy_[i].xlat_ == id) {
         happy_[i].timed_out_ = true;
         happy_[i].task_ = NULL;
         break;
       }
     }

     // getting a bad ID here is a failure, but let's continue
     // running to see what else might go wrong
     EXPECT_LT(i, HAPPY_TASK_COUNT);
   }

   void OnDoneHappy(const int id) {
     int i;
     for (i = 0; i < HAPPY_TASK_COUNT; ++i) {
       if (happy_[i].xlat_ == id) {
         happy_[i].task_ = NULL;
         break;
       }
     }

     // getting a bad ID here is a failure, but let's continue
     // running to see what else might go wrong
     EXPECT_LT(i, HAPPY_TASK_COUNT);
   }

   void check_passed() {
     EXPECT_TRUE(task_runner_.AllChildrenDone());

     // make sure none of our happy tasks timed out
     for (int i = 0; i < HAPPY_TASK_COUNT; ++i) {
       EXPECT_FALSE(happy_[i].timed_out_);
     }

     // make sure all of our stuck tasks timed out
     for (int i = 0; i < STUCK_TASK_COUNT; ++i) {
       EXPECT_TRUE(stuck_[i].timed_out_);
       if (!stuck_[i].timed_out_) {
         std::cout << "Stuck task #" << i << " timeout is at "
                   << stuck_[i].task_->timeout_time() << std::endl;
       }
     }

     std::cout.flush();
   }

  private:
   struct TaskInfo {
     IdTimeoutTask *task_;
     bool timed_out_;
     int xlat_;
   };

   MyTaskRunner task_runner_;
   TaskInfo stuck_[STUCK_TASK_COUNT];
   TaskInfo happy_[HAPPY_TASK_COUNT];
 };

 TEST(start_task_test, Timeout) {
   TaskTest task_test;
   task_test.Start();
   task_test.check_passed();
 }

 // Test for aborting the task while it is running

 class AbortTask : public Task {
  public:
   explicit AbortTask(TaskParent *parent) : Task(parent) {
     set_timeout_seconds(1);
   }

   virtual int ProcessStart() {
     Abort();
     return STATE_NEXT;
   }
  private:
   RTC_DISALLOW_COPY_AND_ASSIGN(AbortTask);
 };

 class TaskAbortTest : public sigslot::has_slots<> {
  public:
   TaskAbortTest() {}

   // no need to delete any tasks; the task runner owns them
   ~TaskAbortTest() {}

   void Start() {
     Task *abort_task = new AbortTask(&task_runner_);
     abort_task->SignalTimeout.connect(this, &TaskAbortTest::OnTimeout);
     abort_task->Start();

     // run the task
     task_runner_.RunTasks();
   }

  private:
   void OnTimeout() {
     FAIL() << "Task timed out instead of aborting.";
   }

   MyTaskRunner task_runner_;
   RTC_DISALLOW_COPY_AND_ASSIGN(TaskAbortTest);
 };

 TEST(start_task_test, Abort) {
   TaskAbortTest abort_test;
   abort_test.Start();
 }

 // Test for aborting a task to verify that it does the Wake operation
 // which gets it deleted.

 class SetBoolOnDeleteTask : public Task {
  public:
   SetBoolOnDeleteTask(TaskParent *parent, bool *set_when_deleted)
     : Task(parent),
       set_when_deleted_(set_when_deleted) {
     EXPECT_TRUE(NULL != set_when_deleted);
     EXPECT_FALSE(*set_when_deleted);
   }

   virtual ~SetBoolOnDeleteTask() {
     *set_when_deleted_ = true;
   }

   virtual int ProcessStart() {
     return STATE_BLOCKED;
   }

  private:
   bool* set_when_deleted_;
   RTC_DISALLOW_COPY_AND_ASSIGN(SetBoolOnDeleteTask);
 };

 class AbortShouldWakeTest : public sigslot::has_slots<> {
  public:
   AbortShouldWakeTest() {}

   // no need to delete any tasks; the task runner owns them
   ~AbortShouldWakeTest() {}

   void Start() {
     bool task_deleted = false;
     Task *task_to_abort = new SetBoolOnDeleteTask(&task_runner_, &task_deleted);
     task_to_abort->Start();

     // Task::Abort() should call TaskRunner::WakeTasks(). WakeTasks calls
     // TaskRunner::RunTasks() immediately which should delete the task.
     task_to_abort->Abort();
     EXPECT_TRUE(task_deleted);

     if (!task_deleted) {
       // avoid a crash (due to referencing a local variable)
       // if the test fails.
       task_runner_.RunTasks();
     }
   }

  private:
   void OnTimeout() {
     FAIL() << "Task timed out instead of aborting.";
   }

   MyTaskRunner task_runner_;
   RTC_DISALLOW_COPY_AND_ASSIGN(AbortShouldWakeTest);
 };

 TEST(start_task_test, AbortShouldWake) {
   AbortShouldWakeTest abort_should_wake_test;
   abort_should_wake_test.Start();
 }

 // Validate that TaskRunner's OnTimeoutChange gets called appropriately
 //  * When a task calls UpdateTaskTimeout
 //  * When the next timeout task time, times out
 class TimeoutChangeTest : public sigslot::has_slots<> {
  public:
   TimeoutChangeTest()
     : task_count_(arraysize(stuck_tasks_)) {}

   // no need to delete any tasks; the task runner owns them
   ~TimeoutChangeTest() {}

   void Start() {
     for (int i = 0; i < task_count_; ++i) {
       stuck_tasks_[i] = new StuckTask(&task_runner_);
       stuck_tasks_[i]->set_timeout_seconds(i + 2);
       stuck_tasks_[i]->SignalTimeoutId.connect(this,
                                                &TimeoutChangeTest::OnTimeoutId);
     }

     for (int i = task_count_ - 1; i >= 0; --i) {
       stuck_tasks_[i]->Start();
     }
     task_runner_.clear_timeout_change();

     // At this point, our timeouts are set as follows
     // task[0] is 2 seconds, task[1] at 3 seconds, etc.

     stuck_tasks_[0]->set_timeout_seconds(2);
     // Now, task[0] is 2 seconds, task[1] at 3 seconds...
     // so timeout change shouldn't be called.
     EXPECT_FALSE(task_runner_.timeout_change());
     task_runner_.clear_timeout_change();

     stuck_tasks_[0]->set_timeout_seconds(1);
     // task[0] is 1 seconds, task[1] at 3 seconds...
     // The smallest timeout got smaller so timeout change be called.
     EXPECT_TRUE(task_runner_.timeout_change());
     task_runner_.clear_timeout_change();

     stuck_tasks_[1]->set_timeout_seconds(2);
     // task[0] is 1 seconds, task[1] at 2 seconds...
     // The smallest timeout is still 1 second so no timeout change.
     EXPECT_FALSE(task_runner_.timeout_change());
     task_runner_.clear_timeout_change();

     while (task_count_ > 0) {
       int previous_count = task_count_;
       task_runner_.PollTasks();
       if (previous_count != task_count_) {
         // We only get here when a task times out.  When that
         // happens, the timeout change should get called because
         // the smallest timeout is now in the past.
         EXPECT_TRUE(task_runner_.timeout_change());
         task_runner_.clear_timeout_change();
       }
       Thread::Current()->socketserver()->Wait(500, false);
     }
   }

  private:
   void OnTimeoutId(const int id) {
     for (size_t i = 0; i < arraysize(stuck_tasks_); ++i) {
       if (stuck_tasks_[i] && stuck_tasks_[i]->unique_id() == id) {
         task_count_--;
         stuck_tasks_[i] = NULL;
         break;
       }
     }
   }

   MyTaskRunner task_runner_;
   StuckTask* (stuck_tasks_[3]);
   int task_count_;
   RTC_DISALLOW_COPY_AND_ASSIGN(TimeoutChangeTest);
 };

 TEST(start_task_test, TimeoutChange) {
   TimeoutChangeTest timeout_change_test;
   timeout_change_test.Start();
 }

 class DeleteTestTaskRunner : public TaskRunner {
  public:
   DeleteTestTaskRunner() {
   }
   virtual void WakeTasks() { }
   virtual int64_t CurrentTime() { return GetCurrentTime(); }
  private:
   RTC_DISALLOW_COPY_AND_ASSIGN(DeleteTestTaskRunner);
 };

 TEST(unstarted_task_test, DeleteTask) {
   // This test ensures that we don't
   // crash if a task is deleted without running it.
   DeleteTestTaskRunner task_runner;
   HappyTask* happy_task = new HappyTask(&task_runner);
   happy_task->Start();

   // try deleting the task directly
   HappyTask* child_happy_task = new HappyTask(happy_task);
   delete child_happy_task;

   // run the unblocked tasks
   task_runner.RunTasks();
 }

 TEST(unstarted_task_test, DoNotDeleteTask1) {
   // This test ensures that we don't
   // crash if a task runner is deleted without
   // running a certain task.
   DeleteTestTaskRunner task_runner;
   HappyTask* happy_task = new HappyTask(&task_runner);
   happy_task->Start();

   HappyTask* child_happy_task = new HappyTask(happy_task);
   child_happy_task->Start();

   // Never run the tasks
 }

 TEST(unstarted_task_test, DoNotDeleteTask2) {
   // This test ensures that we don't
   // crash if a taskrunner is delete with a
   // task that has never been started.
   DeleteTestTaskRunner task_runner;
   HappyTask* happy_task = new HappyTask(&task_runner);
   happy_task->Start();

   // Do not start the task.
   // Note: this leaks memory, so don't do this.
   // Instead, always run your tasks or delete them.
   new HappyTask(happy_task);

   // run the unblocked tasks
   task_runner.RunTasks();
 }

 }  // namespace rtc
	/*
	* Copyright 2004 The WebRTC Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#if defined(WEBRTC_POSIX)
	#include <sys/time.h>
	#endif // WEBRTC_POSIX

	// TODO: Remove this once the cause of sporadic failures in these
	// tests is tracked down.
	#include <iostream>

	#if defined(WEBRTC_WIN)
	#include "webrtc/base/win32.h"
	#endif // WEBRTC_WIN

	#include "webrtc/base/arraysize.h"
	#include "webrtc/base/common.h"
	#include "webrtc/base/constructormagic.h"
	#include "webrtc/base/gunit.h"
	#include "webrtc/base/logging.h"
	#include "webrtc/base/task.h"
	#include "webrtc/base/taskrunner.h"
	#include "webrtc/base/thread.h"
	#include "webrtc/base/timeutils.h"

	namespace rtc {

	static int64_t GetCurrentTime() {
	return TimeMillis() * 10000;
	}

	// feel free to change these numbers. Note that '0' won't work, though
	#define STUCK_TASK_COUNT 5
	#define HAPPY_TASK_COUNT 20

	// this is a generic timeout task which, when it signals timeout, will
	// include the unique ID of the task in the signal (we don't use this
	// in production code because we haven't yet had occasion to generate
	// an array of the same types of task)

	class IdTimeoutTask : public Task, public sigslot::has_slots<> {
	public:
	explicit IdTimeoutTask(TaskParent *parent) : Task(parent) {
	SignalTimeout.connect(this, &IdTimeoutTask::OnLocalTimeout);
	}

	sigslot::signal1<const int> SignalTimeoutId;
	sigslot::signal1<const int> SignalDoneId;

	virtual int ProcessStart() {
	return STATE_RESPONSE;
	}

	void OnLocalTimeout() {
	SignalTimeoutId(unique_id());
	}

	protected:
	virtual void Stop() {
	SignalDoneId(unique_id());
	Task::Stop();
	}
	};

	class StuckTask : public IdTimeoutTask {
	public:
	explicit StuckTask(TaskParent *parent) : IdTimeoutTask(parent) {}
	virtual int ProcessStart() {
	return STATE_BLOCKED;
	}
	};

	class HappyTask : public IdTimeoutTask {
	public:
	explicit HappyTask(TaskParent *parent) : IdTimeoutTask(parent) {
	time_to_perform_ = rand() % (STUCK_TASK_COUNT / 2);
	}
	virtual int ProcessStart() {
	if (ElapsedTime() > (time_to_perform_ * 1000 * 10000))
	return STATE_RESPONSE;
	else
	return STATE_BLOCKED;
	}

	private:
	int time_to_perform_;
	};

	// simple implementation of a task runner which uses Windows'
	// GetSystemTimeAsFileTime() to get the current clock ticks

	class MyTaskRunner : public TaskRunner {
	public:
	virtual void WakeTasks() { RunTasks(); }
	virtual int64_t CurrentTime() { return GetCurrentTime(); }

	bool timeout_change() const {
	return timeout_change_;
	}

	void clear_timeout_change() {
	timeout_change_ = false;
	}
	protected:
	virtual void OnTimeoutChange() {
	timeout_change_ = true;
	}
	bool timeout_change_;
	};

	//
	// this unit test is primarily concerned (for now) with the timeout
	// functionality in tasks. It works as follows:
	//
	// * Create a bunch of tasks, some "stuck" (ie., guaranteed to timeout)
	// and some "happy" (will immediately finish).
	// * Set the timeout on the "stuck" tasks to some number of seconds between
	// 1 and the number of stuck tasks
	// * Start all the stuck & happy tasks in random order
	// * Wait "number of stuck tasks" seconds and make sure everything timed out

	class TaskTest : public sigslot::has_slots<> {
	public:
	TaskTest() {}

	// no need to delete any tasks; the task runner owns them
	~TaskTest() {}

	void Start() {
	// create and configure tasks
	for (int i = 0; i < STUCK_TASK_COUNT; ++i) {
	stuck_[i].task_ = new StuckTask(&task_runner_);
	stuck_[i].task_->SignalTimeoutId.connect(this,
	&TaskTest::OnTimeoutStuck);
	stuck_[i].timed_out_ = false;
	stuck_[i].xlat_ = stuck_[i].task_->unique_id();
	stuck_[i].task_->set_timeout_seconds(i + 1);
	LOG(LS_INFO) << "Task " << stuck_[i].xlat_ << " created with timeout "
	<< stuck_[i].task_->timeout_seconds();
	}

	for (int i = 0; i < HAPPY_TASK_COUNT; ++i) {
	happy_[i].task_ = new HappyTask(&task_runner_);
	happy_[i].task_->SignalTimeoutId.connect(this,
	&TaskTest::OnTimeoutHappy);
	happy_[i].task_->SignalDoneId.connect(this,
	&TaskTest::OnDoneHappy);
	happy_[i].timed_out_ = false;
	happy_[i].xlat_ = happy_[i].task_->unique_id();
	}

	// start all the tasks in random order
	int stuck_index = 0;
	int happy_index = 0;
	for (int i = 0; i < STUCK_TASK_COUNT + HAPPY_TASK_COUNT; ++i) {
	if ((stuck_index < STUCK_TASK_COUNT) &&
	(happy_index < HAPPY_TASK_COUNT)) {
	if (rand() % 2 == 1) {
	stuck_[stuck_index++].task_->Start();
	} else {
	happy_[happy_index++].task_->Start();
	}
	} else if (stuck_index < STUCK_TASK_COUNT) {
	stuck_[stuck_index++].task_->Start();
	} else {
	happy_[happy_index++].task_->Start();
	}
	}

	for (int i = 0; i < STUCK_TASK_COUNT; ++i) {
	std::cout << "Stuck task #" << i << " timeout is " <<
	stuck_[i].task_->timeout_seconds() << " at " <<
	stuck_[i].task_->timeout_time() << std::endl;
	}

	// just a little self-check to make sure we started all the tasks
	ASSERT_EQ(STUCK_TASK_COUNT, stuck_index);
	ASSERT_EQ(HAPPY_TASK_COUNT, happy_index);

	// run the unblocked tasks
	LOG(LS_INFO) << "Running tasks";
	task_runner_.RunTasks();

	std::cout << "Start time is " << GetCurrentTime() << std::endl;

	// give all the stuck tasks time to timeout
	for (int i = 0; !task_runner_.AllChildrenDone() && i < STUCK_TASK_COUNT;
	++i) {
	Thread::Current()->ProcessMessages(1000);
	for (int j = 0; j < HAPPY_TASK_COUNT; ++j) {
	if (happy_[j].task_) {
	happy_[j].task_->Wake();
	}
	}
	LOG(LS_INFO) << "Polling tasks";
	task_runner_.PollTasks();
	}

	// We see occasional test failures here due to the stuck tasks not having
	// timed-out yet, which seems like it should be impossible. To help track
	// this down we have added logging of the timing information, which we send
	// directly to stdout so that we get it in opt builds too.
	std::cout << "End time is " << GetCurrentTime() << std::endl;
	}

	void OnTimeoutStuck(const int id) {
	LOG(LS_INFO) << "Timed out task " << id;

	int i;
	for (i = 0; i < STUCK_TASK_COUNT; ++i) {
	if (stuck_[i].xlat_ == id) {
	stuck_[i].timed_out_ = true;
	stuck_[i].task_ = NULL;
	break;
	}
	}

	// getting a bad ID here is a failure, but let's continue
	// running to see what else might go wrong
	EXPECT_LT(i, STUCK_TASK_COUNT);
	}

	void OnTimeoutHappy(const int id) {
	int i;
	for (i = 0; i < HAPPY_TASK_COUNT; ++i) {
	if (happy_[i].xlat_ == id) {
	happy_[i].timed_out_ = true;
	happy_[i].task_ = NULL;
	break;
	}
	}

	// getting a bad ID here is a failure, but let's continue
	// running to see what else might go wrong
	EXPECT_LT(i, HAPPY_TASK_COUNT);
	}

	void OnDoneHappy(const int id) {
	int i;
	for (i = 0; i < HAPPY_TASK_COUNT; ++i) {
	if (happy_[i].xlat_ == id) {
	happy_[i].task_ = NULL;
	break;
	}
	}

	// getting a bad ID here is a failure, but let's continue
	// running to see what else might go wrong
	EXPECT_LT(i, HAPPY_TASK_COUNT);
	}

	void check_passed() {
	EXPECT_TRUE(task_runner_.AllChildrenDone());

	// make sure none of our happy tasks timed out
	for (int i = 0; i < HAPPY_TASK_COUNT; ++i) {
	EXPECT_FALSE(happy_[i].timed_out_);
	}

	// make sure all of our stuck tasks timed out
	for (int i = 0; i < STUCK_TASK_COUNT; ++i) {
	EXPECT_TRUE(stuck_[i].timed_out_);
	if (!stuck_[i].timed_out_) {
	std::cout << "Stuck task #" << i << " timeout is at "
	<< stuck_[i].task_->timeout_time() << std::endl;
	}
	}

	std::cout.flush();
	}

	private:
	struct TaskInfo {
	IdTimeoutTask *task_;
	bool timed_out_;
	int xlat_;
	};

	MyTaskRunner task_runner_;
	TaskInfo stuck_[STUCK_TASK_COUNT];
	TaskInfo happy_[HAPPY_TASK_COUNT];
	};

	TEST(start_task_test, Timeout) {
	TaskTest task_test;
	task_test.Start();
	task_test.check_passed();
	}

	// Test for aborting the task while it is running

	class AbortTask : public Task {
	public:
	explicit AbortTask(TaskParent *parent) : Task(parent) {
	set_timeout_seconds(1);
	}

	virtual int ProcessStart() {
	Abort();
	return STATE_NEXT;
	}
	private:
	RTC_DISALLOW_COPY_AND_ASSIGN(AbortTask);
	};

	class TaskAbortTest : public sigslot::has_slots<> {
	public:
	TaskAbortTest() {}

	// no need to delete any tasks; the task runner owns them
	~TaskAbortTest() {}

	void Start() {
	Task *abort_task = new AbortTask(&task_runner_);
	abort_task->SignalTimeout.connect(this, &TaskAbortTest::OnTimeout);
	abort_task->Start();

	// run the task
	task_runner_.RunTasks();
	}

	private:
	void OnTimeout() {
	FAIL() << "Task timed out instead of aborting.";
	}

	MyTaskRunner task_runner_;
	RTC_DISALLOW_COPY_AND_ASSIGN(TaskAbortTest);
	};

	TEST(start_task_test, Abort) {
	TaskAbortTest abort_test;
	abort_test.Start();
	}

	// Test for aborting a task to verify that it does the Wake operation
	// which gets it deleted.

	class SetBoolOnDeleteTask : public Task {
	public:
	SetBoolOnDeleteTask(TaskParent parent, bool set_when_deleted)
	: Task(parent),
	set_when_deleted_(set_when_deleted) {
	EXPECT_TRUE(NULL != set_when_deleted);
	EXPECT_FALSE(*set_when_deleted);
	}

	virtual ~SetBoolOnDeleteTask() {
	*set_when_deleted_ = true;
	}

	virtual int ProcessStart() {
	return STATE_BLOCKED;
	}

	private:
	bool* set_when_deleted_;
	RTC_DISALLOW_COPY_AND_ASSIGN(SetBoolOnDeleteTask);
	};

	class AbortShouldWakeTest : public sigslot::has_slots<> {
	public:
	AbortShouldWakeTest() {}

	// no need to delete any tasks; the task runner owns them
	~AbortShouldWakeTest() {}

	void Start() {
	bool task_deleted = false;
	Task *task_to_abort = new SetBoolOnDeleteTask(&task_runner_, &task_deleted);
	task_to_abort->Start();

	// Task::Abort() should call TaskRunner::WakeTasks(). WakeTasks calls
	// TaskRunner::RunTasks() immediately which should delete the task.
	task_to_abort->Abort();
	EXPECT_TRUE(task_deleted);

	if (!task_deleted) {
	// avoid a crash (due to referencing a local variable)
	// if the test fails.
	task_runner_.RunTasks();
	}
	}

	private:
	void OnTimeout() {
	FAIL() << "Task timed out instead of aborting.";
	}

	MyTaskRunner task_runner_;
	RTC_DISALLOW_COPY_AND_ASSIGN(AbortShouldWakeTest);
	};

	TEST(start_task_test, AbortShouldWake) {
	AbortShouldWakeTest abort_should_wake_test;
	abort_should_wake_test.Start();
	}

	// Validate that TaskRunner's OnTimeoutChange gets called appropriately
	// * When a task calls UpdateTaskTimeout
	// * When the next timeout task time, times out
	class TimeoutChangeTest : public sigslot::has_slots<> {
	public:
	TimeoutChangeTest()
	: task_count_(arraysize(stuck_tasks_)) {}

	// no need to delete any tasks; the task runner owns them
	~TimeoutChangeTest() {}

	void Start() {
	for (int i = 0; i < task_count_; ++i) {
	stuck_tasks_[i] = new StuckTask(&task_runner_);
	stuck_tasks_[i]->set_timeout_seconds(i + 2);
	stuck_tasks_[i]->SignalTimeoutId.connect(this,
	&TimeoutChangeTest::OnTimeoutId);
	}

	for (int i = task_count_ - 1; i >= 0; --i) {
	stuck_tasks_[i]->Start();
	}
	task_runner_.clear_timeout_change();

	// At this point, our timeouts are set as follows
	// task[0] is 2 seconds, task[1] at 3 seconds, etc.

	stuck_tasks_[0]->set_timeout_seconds(2);
	// Now, task[0] is 2 seconds, task[1] at 3 seconds...
	// so timeout change shouldn't be called.
	EXPECT_FALSE(task_runner_.timeout_change());
	task_runner_.clear_timeout_change();

	stuck_tasks_[0]->set_timeout_seconds(1);
	// task[0] is 1 seconds, task[1] at 3 seconds...
	// The smallest timeout got smaller so timeout change be called.
	EXPECT_TRUE(task_runner_.timeout_change());
	task_runner_.clear_timeout_change();

	stuck_tasks_[1]->set_timeout_seconds(2);
	// task[0] is 1 seconds, task[1] at 2 seconds...
	// The smallest timeout is still 1 second so no timeout change.
	EXPECT_FALSE(task_runner_.timeout_change());
	task_runner_.clear_timeout_change();

	while (task_count_ > 0) {
	int previous_count = task_count_;
	task_runner_.PollTasks();
	if (previous_count != task_count_) {
	// We only get here when a task times out. When that
	// happens, the timeout change should get called because
	// the smallest timeout is now in the past.
	EXPECT_TRUE(task_runner_.timeout_change());
	task_runner_.clear_timeout_change();
	}
	Thread::Current()->socketserver()->Wait(500, false);
	}
	}

	private:
	void OnTimeoutId(const int id) {
	for (size_t i = 0; i < arraysize(stuck_tasks_); ++i) {
	if (stuck_tasks_[i] && stuck_tasks_[i]->unique_id() == id) {
	task_count_--;
	stuck_tasks_[i] = NULL;
	break;
	}
	}
	}

	MyTaskRunner task_runner_;
	StuckTask* (stuck_tasks_[3]);
	int task_count_;
	RTC_DISALLOW_COPY_AND_ASSIGN(TimeoutChangeTest);
	};

	TEST(start_task_test, TimeoutChange) {
	TimeoutChangeTest timeout_change_test;
	timeout_change_test.Start();
	}

	class DeleteTestTaskRunner : public TaskRunner {
	public:
	DeleteTestTaskRunner() {
	}
	virtual void WakeTasks() { }
	virtual int64_t CurrentTime() { return GetCurrentTime(); }
	private:
	RTC_DISALLOW_COPY_AND_ASSIGN(DeleteTestTaskRunner);
	};

	TEST(unstarted_task_test, DeleteTask) {
	// This test ensures that we don't
	// crash if a task is deleted without running it.
	DeleteTestTaskRunner task_runner;
	HappyTask* happy_task = new HappyTask(&task_runner);
	happy_task->Start();

	// try deleting the task directly
	HappyTask* child_happy_task = new HappyTask(happy_task);
	delete child_happy_task;

	// run the unblocked tasks
	task_runner.RunTasks();
	}

	TEST(unstarted_task_test, DoNotDeleteTask1) {
	// This test ensures that we don't
	// crash if a task runner is deleted without
	// running a certain task.
	DeleteTestTaskRunner task_runner;
	HappyTask* happy_task = new HappyTask(&task_runner);
	happy_task->Start();

	HappyTask* child_happy_task = new HappyTask(happy_task);
	child_happy_task->Start();

	// Never run the tasks
	}

	TEST(unstarted_task_test, DoNotDeleteTask2) {
	// This test ensures that we don't
	// crash if a taskrunner is delete with a
	// task that has never been started.
	DeleteTestTaskRunner task_runner;
	HappyTask* happy_task = new HappyTask(&task_runner);
	happy_task->Start();

	// Do not start the task.
	// Note: this leaks memory, so don't do this.
	// Instead, always run your tasks or delete them.
	new HappyTask(happy_task);

	// run the unblocked tasks
	task_runner.RunTasks();
	}

	} // namespace rtc