mojo/message_pump/handle_watcher_unittest.cc - chromium/src - Git at Google

 // 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 "mojo/message_pump/handle_watcher.h"

 #include <string>

 #include "base/at_exit.h"
 #include "base/auto_reset.h"
 #include "base/bind.h"
 #include "base/memory/scoped_vector.h"
 #include "base/run_loop.h"
 #include "base/test/simple_test_tick_clock.h"
 #include "base/threading/thread.h"
 #include "mojo/message_pump/message_pump_mojo.h"
 #include "mojo/message_pump/time_helper.h"
 #include "mojo/public/cpp/system/core.h"
 #include "mojo/public/cpp/test_support/test_utils.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace mojo {
 namespace common {
 namespace test {

 enum MessageLoopConfig {
   MESSAGE_LOOP_CONFIG_DEFAULT = 0,
   MESSAGE_LOOP_CONFIG_MOJO = 1
 };

 void ObserveCallback(bool* was_signaled,
                      MojoResult* result_observed,
                      MojoResult result) {
   *was_signaled = true;
   *result_observed = result;
 }

 void RunUntilIdle() {
   base::RunLoop run_loop;
   run_loop.RunUntilIdle();
 }

 void DeleteWatcherAndForwardResult(
     HandleWatcher* watcher,
     base::Callback<void(MojoResult)> next_callback,
     MojoResult result) {
   delete watcher;
   next_callback.Run(result);
 }

 scoped_ptr<base::MessageLoop> CreateMessageLoop(MessageLoopConfig config) {
   scoped_ptr<base::MessageLoop> loop;
   if (config == MESSAGE_LOOP_CONFIG_DEFAULT)
     loop.reset(new base::MessageLoop());
   else
     loop.reset(new base::MessageLoop(MessagePumpMojo::Create()));
   return loop.Pass();
 }

 // Helper class to manage the callback and running the message loop waiting for
 // message to be received. Typical usage is something like:
 //   Schedule callback returned from GetCallback().
 //   RunUntilGotCallback();
 //   EXPECT_TRUE(got_callback());
 //   clear_callback();
 class CallbackHelper {
  public:
   CallbackHelper()
       : got_callback_(false),
         run_loop_(NULL),
         weak_factory_(this) {}
   ~CallbackHelper() {}

   // See description above |got_callback_|.
   bool got_callback() const { return got_callback_; }
   void clear_callback() { got_callback_ = false; }

   // Runs the current MessageLoop until the callback returned from GetCallback()
   // is notified.
   void RunUntilGotCallback() {
     ASSERT_TRUE(run_loop_ == NULL);
     base::RunLoop run_loop;
     base::AutoReset<base::RunLoop*> reseter(&run_loop_, &run_loop);
     run_loop.Run();
   }

   base::Callback<void(MojoResult)> GetCallback() {
     return base::Bind(&CallbackHelper::OnCallback, weak_factory_.GetWeakPtr());
   }

   void Start(HandleWatcher* watcher, const MessagePipeHandle& handle) {
     StartWithCallback(watcher, handle, GetCallback());
   }

   void StartWithCallback(HandleWatcher* watcher,
                          const MessagePipeHandle& handle,
                          const base::Callback<void(MojoResult)>& callback) {
     watcher->Start(handle, MOJO_HANDLE_SIGNAL_READABLE,
                    MOJO_DEADLINE_INDEFINITE, callback);
   }

  private:
   void OnCallback(MojoResult result) {
     got_callback_ = true;
     if (run_loop_)
       run_loop_->Quit();
   }

   // Set to true when the callback is called.
   bool got_callback_;

   // If non-NULL we're in RunUntilGotCallback().
   base::RunLoop* run_loop_;

   base::WeakPtrFactory<CallbackHelper> weak_factory_;

  private:
   DISALLOW_COPY_AND_ASSIGN(CallbackHelper);
 };

 class HandleWatcherTest : public testing::TestWithParam<MessageLoopConfig> {
  public:
   HandleWatcherTest() : message_loop_(CreateMessageLoop(GetParam())) {}
   virtual ~HandleWatcherTest() {
     test::SetTickClockForTest(NULL);
   }

  protected:
   void TearDownMessageLoop() {
     message_loop_.reset();
   }

   void InstallTickClock() {
     test::SetTickClockForTest(&tick_clock_);
   }

   base::SimpleTestTickClock tick_clock_;

  private:
   base::ShadowingAtExitManager at_exit_;
   scoped_ptr<base::MessageLoop> message_loop_;

   DISALLOW_COPY_AND_ASSIGN(HandleWatcherTest);
 };

 INSTANTIATE_TEST_CASE_P(
     MultipleMessageLoopConfigs, HandleWatcherTest,
     testing::Values(MESSAGE_LOOP_CONFIG_DEFAULT, MESSAGE_LOOP_CONFIG_MOJO));

 // Trivial test case with a single handle to watch.
 TEST_P(HandleWatcherTest, SingleHandler) {
   MessagePipe test_pipe;
   ASSERT_TRUE(test_pipe.handle0.is_valid());
   CallbackHelper callback_helper;
   HandleWatcher watcher;
   callback_helper.Start(&watcher, test_pipe.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper.got_callback());
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe.handle1.get(),
                                            std::string()));
   callback_helper.RunUntilGotCallback();
   EXPECT_TRUE(callback_helper.got_callback());
 }

 // Creates three handles and notfies them in reverse order ensuring each one is
 // notified appropriately.
 TEST_P(HandleWatcherTest, ThreeHandles) {
   MessagePipe test_pipe1;
   MessagePipe test_pipe2;
   MessagePipe test_pipe3;
   CallbackHelper callback_helper1;
   CallbackHelper callback_helper2;
   CallbackHelper callback_helper3;
   ASSERT_TRUE(test_pipe1.handle0.is_valid());
   ASSERT_TRUE(test_pipe2.handle0.is_valid());
   ASSERT_TRUE(test_pipe3.handle0.is_valid());

   HandleWatcher watcher1;
   callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());

   HandleWatcher watcher2;
   callback_helper2.Start(&watcher2, test_pipe2.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());

   HandleWatcher watcher3;
   callback_helper3.Start(&watcher3, test_pipe3.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());

   // Write to 3 and make sure it's notified.
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe3.handle1.get(),
                                            std::string()));
   callback_helper3.RunUntilGotCallback();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   EXPECT_TRUE(callback_helper3.got_callback());
   callback_helper3.clear_callback();

   // Write to 1 and 3. Only 1 should be notified since 3 was is no longer
   // running.
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
                                            std::string()));
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe3.handle1.get(),
                                            std::string()));
   callback_helper1.RunUntilGotCallback();
   EXPECT_TRUE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());
   callback_helper1.clear_callback();

   // Write to 1 and 2. Only 2 should be notified (since 1 was already notified).
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
                                            std::string()));
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe2.handle1.get(),
                                            std::string()));
   callback_helper2.RunUntilGotCallback();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_TRUE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());
 }

 // Verifies Start() invoked a second time works.
 TEST_P(HandleWatcherTest, Restart) {
   MessagePipe test_pipe1;
   MessagePipe test_pipe2;
   CallbackHelper callback_helper1;
   CallbackHelper callback_helper2;
   ASSERT_TRUE(test_pipe1.handle0.is_valid());
   ASSERT_TRUE(test_pipe2.handle0.is_valid());

   HandleWatcher watcher1;
   callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());

   HandleWatcher watcher2;
   callback_helper2.Start(&watcher2, test_pipe2.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());

   // Write to 1 and make sure it's notified.
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
                                            std::string()));
   callback_helper1.RunUntilGotCallback();
   EXPECT_TRUE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   callback_helper1.clear_callback();
   EXPECT_TRUE(mojo::test::DiscardMessage(test_pipe1.handle0.get()));

   // Write to 2 and make sure it's notified.
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe2.handle1.get(),
                                            std::string()));
   callback_helper2.RunUntilGotCallback();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_TRUE(callback_helper2.got_callback());
   callback_helper2.clear_callback();

   // Listen on 1 again.
   callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());

   // Write to 1 and make sure it's notified.
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
                                            std::string()));
   callback_helper1.RunUntilGotCallback();
   EXPECT_TRUE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
 }

 // Verifies Start() invoked a second time on the same handle works.
 TEST_P(HandleWatcherTest, RestartOnSameHandle) {
   MessagePipe test_pipe;
   CallbackHelper callback_helper;
   ASSERT_TRUE(test_pipe.handle0.is_valid());

   HandleWatcher watcher;
   callback_helper.Start(&watcher, test_pipe.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper.got_callback());

   callback_helper.Start(&watcher, test_pipe.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper.got_callback());
 }

 // Verifies deadline is honored.
 TEST_P(HandleWatcherTest, Deadline) {
   InstallTickClock();

   MessagePipe test_pipe1;
   MessagePipe test_pipe2;
   MessagePipe test_pipe3;
   CallbackHelper callback_helper1;
   CallbackHelper callback_helper2;
   CallbackHelper callback_helper3;
   ASSERT_TRUE(test_pipe1.handle0.is_valid());
   ASSERT_TRUE(test_pipe2.handle0.is_valid());
   ASSERT_TRUE(test_pipe3.handle0.is_valid());

   // Add a watcher with an infinite timeout.
   HandleWatcher watcher1;
   callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());

   // Add another watcher wth a timeout of 500 microseconds.
   HandleWatcher watcher2;
   watcher2.Start(test_pipe2.handle0.get(), MOJO_HANDLE_SIGNAL_READABLE, 500,
                  callback_helper2.GetCallback());
   RunUntilIdle();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_FALSE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());

   // Advance the clock passed the deadline. We also have to start another
   // watcher to wake up the background thread.
   tick_clock_.Advance(base::TimeDelta::FromMicroseconds(501));

   HandleWatcher watcher3;
   callback_helper3.Start(&watcher3, test_pipe3.handle0.get());

   callback_helper2.RunUntilGotCallback();
   EXPECT_FALSE(callback_helper1.got_callback());
   EXPECT_TRUE(callback_helper2.got_callback());
   EXPECT_FALSE(callback_helper3.got_callback());
 }

 TEST_P(HandleWatcherTest, DeleteInCallback) {
   MessagePipe test_pipe;
   CallbackHelper callback_helper;

   HandleWatcher* watcher = new HandleWatcher();
   callback_helper.StartWithCallback(watcher, test_pipe.handle1.get(),
                                     base::Bind(&DeleteWatcherAndForwardResult,
                                                watcher,
                                                callback_helper.GetCallback()));
   EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe.handle0.get(),
                                            std::string()));
   callback_helper.RunUntilGotCallback();
   EXPECT_TRUE(callback_helper.got_callback());
 }

 TEST_P(HandleWatcherTest, AbortedOnMessageLoopDestruction) {
   bool was_signaled = false;
   MojoResult result = MOJO_RESULT_OK;

   MessagePipe pipe;
   HandleWatcher watcher;
   watcher.Start(pipe.handle0.get(),
                 MOJO_HANDLE_SIGNAL_READABLE,
                 MOJO_DEADLINE_INDEFINITE,
                 base::Bind(&ObserveCallback, &was_signaled, &result));

   // Now, let the MessageLoop get torn down. We expect our callback to run.
   TearDownMessageLoop();

   EXPECT_TRUE(was_signaled);
   EXPECT_EQ(MOJO_RESULT_ABORTED, result);
 }

 void NeverReached(MojoResult result) {
   FAIL() << "Callback should never be invoked " << result;
 }

 // Called on the main thread when a thread is done. Decrements |active_count|
 // and if |active_count| is zero quits |run_loop|.
 void StressThreadDone(base::RunLoop* run_loop, int* active_count) {
   (*active_count)--;
   EXPECT_GE(*active_count, 0);
   if (*active_count == 0)
     run_loop->Quit();
 }

 // See description of StressTest. This is called on the background thread.
 // |count| is the number of HandleWatchers to create. |active_count| is the
 // number of outstanding threads, |task_runner| the task runner for the main
 // thread and |run_loop| the run loop that should be quit when there are no more
 // threads running. When done StressThreadDone() is invoked on the main thread.
 // |active_count| and |run_loop| should only be used on the main thread.
 void RunStressTest(int count,
                    scoped_refptr<base::TaskRunner> task_runner,
                    base::RunLoop* run_loop,
                    int* active_count) {
   struct TestData {
     MessagePipe pipe;
     HandleWatcher watcher;
   };
   ScopedVector<TestData> data_vector;
   for (int i = 0; i < count; ++i) {
     if (i % 20 == 0) {
       // Every so often we wait. This results in some level of thread balancing
       // as well as making sure HandleWatcher has time to actually start some
       // watches.
       MessagePipe test_pipe;
       ASSERT_TRUE(test_pipe.handle0.is_valid());
       CallbackHelper callback_helper;
       HandleWatcher watcher;
       callback_helper.Start(&watcher, test_pipe.handle0.get());
       RunUntilIdle();
       EXPECT_FALSE(callback_helper.got_callback());
       EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe.handle1.get(),
                                                std::string()));
       base::MessageLoop::ScopedNestableTaskAllower scoper(
           base::MessageLoop::current());
       callback_helper.RunUntilGotCallback();
       EXPECT_TRUE(callback_helper.got_callback());
     } else {
       scoped_ptr<TestData> test_data(new TestData);
       ASSERT_TRUE(test_data->pipe.handle0.is_valid());
       test_data->watcher.Start(test_data->pipe.handle0.get(),
                     MOJO_HANDLE_SIGNAL_READABLE,
                     MOJO_DEADLINE_INDEFINITE,
                     base::Bind(&NeverReached));
       data_vector.push_back(test_data.release());
     }
     if (i % 15 == 0)
       data_vector.clear();
   }
   task_runner->PostTask(FROM_HERE,
                         base::Bind(&StressThreadDone, run_loop,
                                    active_count));
 }

 // This test is meant to stress HandleWatcher. It uses from various threads
 // repeatedly starting and stopping watches. It spins up kThreadCount
 // threads. Each thread creates kWatchCount watches. Every so often each thread
 // writes to a pipe and waits for the response.
 TEST(HandleWatcherCleanEnvironmentTest, StressTest) {
 #if defined(NDEBUG)
   const int kThreadCount = 15;
   const int kWatchCount = 400;
 #else
   const int kThreadCount = 10;
   const int kWatchCount = 250;
 #endif

   base::ShadowingAtExitManager at_exit;
   base::MessageLoop message_loop;
   base::RunLoop run_loop;
   ScopedVector<base::Thread> threads;
   int threads_active_counter = kThreadCount;
   // Starts the threads first and then post the task in hopes of having more
   // threads running at once.
   for (int i = 0; i < kThreadCount; ++i) {
     scoped_ptr<base::Thread> thread(new base::Thread("test thread"));
     if (i % 2) {
       base::Thread::Options thread_options;
       thread_options.message_pump_factory =
           base::Bind(&MessagePumpMojo::Create);
       thread->StartWithOptions(thread_options);
     } else {
       thread->Start();
     }
     threads.push_back(thread.release());
   }
   for (int i = 0; i < kThreadCount; ++i) {
     threads[i]->task_runner()->PostTask(
         FROM_HERE, base::Bind(&RunStressTest, kWatchCount,
                               message_loop.task_runner(),
                               &run_loop, &threads_active_counter));
   }
   run_loop.Run();
   ASSERT_EQ(0, threads_active_counter);
 }

 }  // namespace test
 }  // namespace common
 }  // namespace mojo
	// 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 "mojo/message_pump/handle_watcher.h"

	#include <string>

	#include "base/at_exit.h"
	#include "base/auto_reset.h"
	#include "base/bind.h"
	#include "base/memory/scoped_vector.h"
	#include "base/run_loop.h"
	#include "base/test/simple_test_tick_clock.h"
	#include "base/threading/thread.h"
	#include "mojo/message_pump/message_pump_mojo.h"
	#include "mojo/message_pump/time_helper.h"
	#include "mojo/public/cpp/system/core.h"
	#include "mojo/public/cpp/test_support/test_utils.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace mojo {
	namespace common {
	namespace test {

	enum MessageLoopConfig {
	MESSAGE_LOOP_CONFIG_DEFAULT = 0,
	MESSAGE_LOOP_CONFIG_MOJO = 1
	};

	void ObserveCallback(bool* was_signaled,
	MojoResult* result_observed,
	MojoResult result) {
	*was_signaled = true;
	*result_observed = result;
	}

	void RunUntilIdle() {
	base::RunLoop run_loop;
	run_loop.RunUntilIdle();
	}

	void DeleteWatcherAndForwardResult(
	HandleWatcher* watcher,
	base::Callback<void(MojoResult)> next_callback,
	MojoResult result) {
	delete watcher;
	next_callback.Run(result);
	}

	scoped_ptr<base::MessageLoop> CreateMessageLoop(MessageLoopConfig config) {
	scoped_ptr<base::MessageLoop> loop;
	if (config == MESSAGE_LOOP_CONFIG_DEFAULT)
	loop.reset(new base::MessageLoop());
	else
	loop.reset(new base::MessageLoop(MessagePumpMojo::Create()));
	return loop.Pass();
	}

	// Helper class to manage the callback and running the message loop waiting for
	// message to be received. Typical usage is something like:
	// Schedule callback returned from GetCallback().
	// RunUntilGotCallback();
	// EXPECT_TRUE(got_callback());
	// clear_callback();
	class CallbackHelper {
	public:
	CallbackHelper()
	: got_callback_(false),
	run_loop_(NULL),
	weak_factory_(this) {}
	~CallbackHelper() {}

	// See description above \|got_callback_\|.
	bool got_callback() const { return got_callback_; }
	void clear_callback() { got_callback_ = false; }

	// Runs the current MessageLoop until the callback returned from GetCallback()
	// is notified.
	void RunUntilGotCallback() {
	ASSERT_TRUE(run_loop_ == NULL);
	base::RunLoop run_loop;
	base::AutoReset<base::RunLoop*> reseter(&run_loop_, &run_loop);
	run_loop.Run();
	}

	base::Callback<void(MojoResult)> GetCallback() {
	return base::Bind(&CallbackHelper::OnCallback, weak_factory_.GetWeakPtr());
	}

	void Start(HandleWatcher* watcher, const MessagePipeHandle& handle) {
	StartWithCallback(watcher, handle, GetCallback());
	}

	void StartWithCallback(HandleWatcher* watcher,
	const MessagePipeHandle& handle,
	const base::Callback<void(MojoResult)>& callback) {
	watcher->Start(handle, MOJO_HANDLE_SIGNAL_READABLE,
	MOJO_DEADLINE_INDEFINITE, callback);
	}

	private:
	void OnCallback(MojoResult result) {
	got_callback_ = true;
	if (run_loop_)
	run_loop_->Quit();
	}

	// Set to true when the callback is called.
	bool got_callback_;

	// If non-NULL we're in RunUntilGotCallback().
	base::RunLoop* run_loop_;

	base::WeakPtrFactory<CallbackHelper> weak_factory_;

	private:
	DISALLOW_COPY_AND_ASSIGN(CallbackHelper);
	};

	class HandleWatcherTest : public testing::TestWithParam<MessageLoopConfig> {
	public:
	HandleWatcherTest() : message_loop_(CreateMessageLoop(GetParam())) {}
	virtual ~HandleWatcherTest() {
	test::SetTickClockForTest(NULL);
	}

	protected:
	void TearDownMessageLoop() {
	message_loop_.reset();
	}

	void InstallTickClock() {
	test::SetTickClockForTest(&tick_clock_);
	}

	base::SimpleTestTickClock tick_clock_;

	private:
	base::ShadowingAtExitManager at_exit_;
	scoped_ptr<base::MessageLoop> message_loop_;

	DISALLOW_COPY_AND_ASSIGN(HandleWatcherTest);
	};

	INSTANTIATE_TEST_CASE_P(
	MultipleMessageLoopConfigs, HandleWatcherTest,
	testing::Values(MESSAGE_LOOP_CONFIG_DEFAULT, MESSAGE_LOOP_CONFIG_MOJO));

	// Trivial test case with a single handle to watch.
	TEST_P(HandleWatcherTest, SingleHandler) {
	MessagePipe test_pipe;
	ASSERT_TRUE(test_pipe.handle0.is_valid());
	CallbackHelper callback_helper;
	HandleWatcher watcher;
	callback_helper.Start(&watcher, test_pipe.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper.got_callback());
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe.handle1.get(),
	std::string()));
	callback_helper.RunUntilGotCallback();
	EXPECT_TRUE(callback_helper.got_callback());
	}

	// Creates three handles and notfies them in reverse order ensuring each one is
	// notified appropriately.
	TEST_P(HandleWatcherTest, ThreeHandles) {
	MessagePipe test_pipe1;
	MessagePipe test_pipe2;
	MessagePipe test_pipe3;
	CallbackHelper callback_helper1;
	CallbackHelper callback_helper2;
	CallbackHelper callback_helper3;
	ASSERT_TRUE(test_pipe1.handle0.is_valid());
	ASSERT_TRUE(test_pipe2.handle0.is_valid());
	ASSERT_TRUE(test_pipe3.handle0.is_valid());

	HandleWatcher watcher1;
	callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());

	HandleWatcher watcher2;
	callback_helper2.Start(&watcher2, test_pipe2.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());

	HandleWatcher watcher3;
	callback_helper3.Start(&watcher3, test_pipe3.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());

	// Write to 3 and make sure it's notified.
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe3.handle1.get(),
	std::string()));
	callback_helper3.RunUntilGotCallback();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	EXPECT_TRUE(callback_helper3.got_callback());
	callback_helper3.clear_callback();

	// Write to 1 and 3. Only 1 should be notified since 3 was is no longer
	// running.
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
	std::string()));
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe3.handle1.get(),
	std::string()));
	callback_helper1.RunUntilGotCallback();
	EXPECT_TRUE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());
	callback_helper1.clear_callback();

	// Write to 1 and 2. Only 2 should be notified (since 1 was already notified).
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
	std::string()));
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe2.handle1.get(),
	std::string()));
	callback_helper2.RunUntilGotCallback();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_TRUE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());
	}

	// Verifies Start() invoked a second time works.
	TEST_P(HandleWatcherTest, Restart) {
	MessagePipe test_pipe1;
	MessagePipe test_pipe2;
	CallbackHelper callback_helper1;
	CallbackHelper callback_helper2;
	ASSERT_TRUE(test_pipe1.handle0.is_valid());
	ASSERT_TRUE(test_pipe2.handle0.is_valid());

	HandleWatcher watcher1;
	callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());

	HandleWatcher watcher2;
	callback_helper2.Start(&watcher2, test_pipe2.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());

	// Write to 1 and make sure it's notified.
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
	std::string()));
	callback_helper1.RunUntilGotCallback();
	EXPECT_TRUE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	callback_helper1.clear_callback();
	EXPECT_TRUE(mojo::test::DiscardMessage(test_pipe1.handle0.get()));

	// Write to 2 and make sure it's notified.
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe2.handle1.get(),
	std::string()));
	callback_helper2.RunUntilGotCallback();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_TRUE(callback_helper2.got_callback());
	callback_helper2.clear_callback();

	// Listen on 1 again.
	callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());

	// Write to 1 and make sure it's notified.
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe1.handle1.get(),
	std::string()));
	callback_helper1.RunUntilGotCallback();
	EXPECT_TRUE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	}

	// Verifies Start() invoked a second time on the same handle works.
	TEST_P(HandleWatcherTest, RestartOnSameHandle) {
	MessagePipe test_pipe;
	CallbackHelper callback_helper;
	ASSERT_TRUE(test_pipe.handle0.is_valid());

	HandleWatcher watcher;
	callback_helper.Start(&watcher, test_pipe.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper.got_callback());

	callback_helper.Start(&watcher, test_pipe.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper.got_callback());
	}

	// Verifies deadline is honored.
	TEST_P(HandleWatcherTest, Deadline) {
	InstallTickClock();

	MessagePipe test_pipe1;
	MessagePipe test_pipe2;
	MessagePipe test_pipe3;
	CallbackHelper callback_helper1;
	CallbackHelper callback_helper2;
	CallbackHelper callback_helper3;
	ASSERT_TRUE(test_pipe1.handle0.is_valid());
	ASSERT_TRUE(test_pipe2.handle0.is_valid());
	ASSERT_TRUE(test_pipe3.handle0.is_valid());

	// Add a watcher with an infinite timeout.
	HandleWatcher watcher1;
	callback_helper1.Start(&watcher1, test_pipe1.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());

	// Add another watcher wth a timeout of 500 microseconds.
	HandleWatcher watcher2;
	watcher2.Start(test_pipe2.handle0.get(), MOJO_HANDLE_SIGNAL_READABLE, 500,
	callback_helper2.GetCallback());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_FALSE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());

	// Advance the clock passed the deadline. We also have to start another
	// watcher to wake up the background thread.
	tick_clock_.Advance(base::TimeDelta::FromMicroseconds(501));

	HandleWatcher watcher3;
	callback_helper3.Start(&watcher3, test_pipe3.handle0.get());

	callback_helper2.RunUntilGotCallback();
	EXPECT_FALSE(callback_helper1.got_callback());
	EXPECT_TRUE(callback_helper2.got_callback());
	EXPECT_FALSE(callback_helper3.got_callback());
	}

	TEST_P(HandleWatcherTest, DeleteInCallback) {
	MessagePipe test_pipe;
	CallbackHelper callback_helper;

	HandleWatcher* watcher = new HandleWatcher();
	callback_helper.StartWithCallback(watcher, test_pipe.handle1.get(),
	base::Bind(&DeleteWatcherAndForwardResult,
	watcher,
	callback_helper.GetCallback()));
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe.handle0.get(),
	std::string()));
	callback_helper.RunUntilGotCallback();
	EXPECT_TRUE(callback_helper.got_callback());
	}

	TEST_P(HandleWatcherTest, AbortedOnMessageLoopDestruction) {
	bool was_signaled = false;
	MojoResult result = MOJO_RESULT_OK;

	MessagePipe pipe;
	HandleWatcher watcher;
	watcher.Start(pipe.handle0.get(),
	MOJO_HANDLE_SIGNAL_READABLE,
	MOJO_DEADLINE_INDEFINITE,
	base::Bind(&ObserveCallback, &was_signaled, &result));

	// Now, let the MessageLoop get torn down. We expect our callback to run.
	TearDownMessageLoop();

	EXPECT_TRUE(was_signaled);
	EXPECT_EQ(MOJO_RESULT_ABORTED, result);
	}

	void NeverReached(MojoResult result) {
	FAIL() << "Callback should never be invoked " << result;
	}

	// Called on the main thread when a thread is done. Decrements \|active_count\|
	// and if \|active_count\| is zero quits \|run_loop\|.
	void StressThreadDone(base::RunLoop* run_loop, int* active_count) {
	(*active_count)--;
	EXPECT_GE(*active_count, 0);
	if (*active_count == 0)
	run_loop->Quit();
	}

	// See description of StressTest. This is called on the background thread.
	// \|count\| is the number of HandleWatchers to create. \|active_count\| is the
	// number of outstanding threads, \|task_runner\| the task runner for the main
	// thread and \|run_loop\| the run loop that should be quit when there are no more
	// threads running. When done StressThreadDone() is invoked on the main thread.
	// \|active_count\| and \|run_loop\| should only be used on the main thread.
	void RunStressTest(int count,
	scoped_refptr<base::TaskRunner> task_runner,
	base::RunLoop* run_loop,
	int* active_count) {
	struct TestData {
	MessagePipe pipe;
	HandleWatcher watcher;
	};
	ScopedVector<TestData> data_vector;
	for (int i = 0; i < count; ++i) {
	if (i % 20 == 0) {
	// Every so often we wait. This results in some level of thread balancing
	// as well as making sure HandleWatcher has time to actually start some
	// watches.
	MessagePipe test_pipe;
	ASSERT_TRUE(test_pipe.handle0.is_valid());
	CallbackHelper callback_helper;
	HandleWatcher watcher;
	callback_helper.Start(&watcher, test_pipe.handle0.get());
	RunUntilIdle();
	EXPECT_FALSE(callback_helper.got_callback());
	EXPECT_TRUE(mojo::test::WriteTextMessage(test_pipe.handle1.get(),
	std::string()));
	base::MessageLoop::ScopedNestableTaskAllower scoper(
	base::MessageLoop::current());
	callback_helper.RunUntilGotCallback();
	EXPECT_TRUE(callback_helper.got_callback());
	} else {
	scoped_ptr<TestData> test_data(new TestData);
	ASSERT_TRUE(test_data->pipe.handle0.is_valid());
	test_data->watcher.Start(test_data->pipe.handle0.get(),
	MOJO_HANDLE_SIGNAL_READABLE,
	MOJO_DEADLINE_INDEFINITE,
	base::Bind(&NeverReached));
	data_vector.push_back(test_data.release());
	}
	if (i % 15 == 0)
	data_vector.clear();
	}
	task_runner->PostTask(FROM_HERE,
	base::Bind(&StressThreadDone, run_loop,
	active_count));
	}

	// This test is meant to stress HandleWatcher. It uses from various threads
	// repeatedly starting and stopping watches. It spins up kThreadCount
	// threads. Each thread creates kWatchCount watches. Every so often each thread
	// writes to a pipe and waits for the response.
	TEST(HandleWatcherCleanEnvironmentTest, StressTest) {
	#if defined(NDEBUG)
	const int kThreadCount = 15;
	const int kWatchCount = 400;
	#else
	const int kThreadCount = 10;
	const int kWatchCount = 250;
	#endif

	base::ShadowingAtExitManager at_exit;
	base::MessageLoop message_loop;
	base::RunLoop run_loop;
	ScopedVector<base::Thread> threads;
	int threads_active_counter = kThreadCount;
	// Starts the threads first and then post the task in hopes of having more
	// threads running at once.
	for (int i = 0; i < kThreadCount; ++i) {
	scoped_ptr<base::Thread> thread(new base::Thread("test thread"));
	if (i % 2) {
	base::Thread::Options thread_options;
	thread_options.message_pump_factory =
	base::Bind(&MessagePumpMojo::Create);
	thread->StartWithOptions(thread_options);
	} else {
	thread->Start();
	}
	threads.push_back(thread.release());
	}
	for (int i = 0; i < kThreadCount; ++i) {
	threads[i]->task_runner()->PostTask(
	FROM_HERE, base::Bind(&RunStressTest, kWatchCount,
	message_loop.task_runner(),
	&run_loop, &threads_active_counter));
	}
	run_loop.Run();
	ASSERT_EQ(0, threads_active_counter);
	}

	} // namespace test
	} // namespace common
	} // namespace mojo