base/message_loop/message_pump_glib_unittest.cc - cobalt - Git at Google

 // Copyright (c) 2012 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/message_loop/message_pump_glib.h"

 #include <glib.h>
 #include <math.h>

 #include <algorithm>
 #include <vector>

 #include "base/bind.h"
 #include "base/bind_helpers.h"
 #include "base/callback.h"
 #include "base/macros.h"
 #include "base/memory/ref_counted.h"
 #include "base/message_loop/message_loop.h"
 #include "base/message_loop/message_loop_current.h"
 #include "base/run_loop.h"
 #include "base/single_thread_task_runner.h"
 #include "base/threading/thread.h"
 #include "base/threading/thread_task_runner_handle.h"
 #include "starboard/types.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace base {
 namespace {

 // This class injects dummy "events" into the GLib loop. When "handled" these
 // events can run tasks. This is intended to mock gtk events (the corresponding
 // GLib source runs at the same priority).
 class EventInjector {
  public:
   EventInjector() : processed_events_(0) {
     source_ = static_cast<Source*>(g_source_new(&SourceFuncs, sizeof(Source)));
     source_->injector = this;
     g_source_attach(source_, nullptr);
     g_source_set_can_recurse(source_, TRUE);
   }

   ~EventInjector() {
     g_source_destroy(source_);
     g_source_unref(source_);
   }

   int HandlePrepare() {
     // If the queue is empty, block.
     if (events_.empty())
       return -1;
     TimeDelta delta = events_[0].time - Time::NowFromSystemTime();
     return std::max(0, static_cast<int>(ceil(delta.InMillisecondsF())));
   }

   bool HandleCheck() {
     if (events_.empty())
       return false;
     return events_[0].time <= Time::NowFromSystemTime();
   }

   void HandleDispatch() {
     if (events_.empty())
       return;
     Event event = std::move(events_[0]);
     events_.erase(events_.begin());
     ++processed_events_;
     if (!event.callback.is_null())
       std::move(event.callback).Run();
     else if (!event.task.is_null())
       std::move(event.task).Run();
   }

   // Adds an event to the queue. When "handled", executes |callback|.
   // delay_ms is relative to the last event if any, or to Now() otherwise.
   void AddEvent(int delay_ms, OnceClosure callback) {
     AddEventHelper(delay_ms, std::move(callback), OnceClosure());
   }

   void AddDummyEvent(int delay_ms) {
     AddEventHelper(delay_ms, OnceClosure(), OnceClosure());
   }

   void AddEventAsTask(int delay_ms, OnceClosure task) {
     AddEventHelper(delay_ms, OnceClosure(), std::move(task));
   }

   void Reset() {
     processed_events_ = 0;
     events_.clear();
   }

   int processed_events() const { return processed_events_; }

  private:
   struct Event {
     Time time;
     OnceClosure callback;
     OnceClosure task;
   };

   struct Source : public GSource {
     EventInjector* injector;
   };

   void AddEventHelper(int delay_ms, OnceClosure callback, OnceClosure task) {
     Time last_time;
     if (!events_.empty())
       last_time = (events_.end()-1)->time;
     else
       last_time = Time::NowFromSystemTime();

     Time future = last_time + TimeDelta::FromMilliseconds(delay_ms);
     EventInjector::Event event = {future, std::move(callback), std::move(task)};
     events_.push_back(std::move(event));
   }

   static gboolean Prepare(GSource* source, gint* timeout_ms) {
     *timeout_ms = static_cast<Source*>(source)->injector->HandlePrepare();
     return FALSE;
   }

   static gboolean Check(GSource* source) {
     return static_cast<Source*>(source)->injector->HandleCheck();
   }

   static gboolean Dispatch(GSource* source,
                            GSourceFunc unused_func,
                            gpointer unused_data) {
     static_cast<Source*>(source)->injector->HandleDispatch();
     return TRUE;
   }

   Source* source_;
   std::vector<Event> events_;
   int processed_events_;
   static GSourceFuncs SourceFuncs;
   DISALLOW_COPY_AND_ASSIGN(EventInjector);
 };

 GSourceFuncs EventInjector::SourceFuncs = {EventInjector::Prepare,
                                            EventInjector::Check,
                                            EventInjector::Dispatch, nullptr};

 void IncrementInt(int *value) {
   ++*value;
 }

 // Checks how many events have been processed by the injector.
 void ExpectProcessedEvents(EventInjector* injector, int count) {
   EXPECT_EQ(injector->processed_events(), count);
 }

 // Posts a task on the current message loop.
 void PostMessageLoopTask(const Location& from_here, OnceClosure task) {
   ThreadTaskRunnerHandle::Get()->PostTask(from_here, std::move(task));
 }

 // Test fixture.
 class MessagePumpGLibTest : public testing::Test {
  public:
   MessagePumpGLibTest() : loop_(nullptr), injector_(nullptr) {}

   // Overridden from testing::Test:
   void SetUp() override {
     loop_ = new MessageLoop(MessageLoop::TYPE_UI);
     injector_ = new EventInjector();
   }
   void TearDown() override {
     delete injector_;
     injector_ = nullptr;
     delete loop_;
     loop_ = nullptr;
   }

   MessageLoop* loop() const { return loop_; }
   EventInjector* injector() const { return injector_; }

  private:
   MessageLoop* loop_;
   EventInjector* injector_;
   DISALLOW_COPY_AND_ASSIGN(MessagePumpGLibTest);
 };

 }  // namespace

 TEST_F(MessagePumpGLibTest, TestQuit) {
   // Checks that Quit works and that the basic infrastructure is working.

   // Quit from a task
   RunLoop().RunUntilIdle();
   EXPECT_EQ(0, injector()->processed_events());

   injector()->Reset();
   // Quit from an event
   RunLoop run_loop;
   injector()->AddEvent(0, run_loop.QuitClosure());
   run_loop.Run();
   EXPECT_EQ(1, injector()->processed_events());
 }

 TEST_F(MessagePumpGLibTest, TestEventTaskInterleave) {
   // Checks that tasks posted by events are executed before the next event if
   // the posted task queue is empty.
   // MessageLoop doesn't make strong guarantees that it is the case, but the
   // current implementation ensures it and the tests below rely on it.
   // If changes cause this test to fail, it is reasonable to change it, but
   // TestWorkWhileWaitingForEvents and TestEventsWhileWaitingForWork have to be
   // changed accordingly, otherwise they can become flaky.
   injector()->AddEventAsTask(0, DoNothing());
   OnceClosure check_task =
       BindOnce(&ExpectProcessedEvents, Unretained(injector()), 2);
   OnceClosure posted_task =
       BindOnce(&PostMessageLoopTask, FROM_HERE, std::move(check_task));
   injector()->AddEventAsTask(0, std::move(posted_task));
   injector()->AddEventAsTask(0, DoNothing());
   {
     RunLoop run_loop;
     injector()->AddEvent(0, run_loop.QuitClosure());
     run_loop.Run();
   }
   EXPECT_EQ(4, injector()->processed_events());

   injector()->Reset();
   injector()->AddEventAsTask(0, DoNothing());
   check_task = BindOnce(&ExpectProcessedEvents, Unretained(injector()), 2);
   posted_task =
       BindOnce(&PostMessageLoopTask, FROM_HERE, std::move(check_task));
   injector()->AddEventAsTask(0, std::move(posted_task));
   injector()->AddEventAsTask(10, DoNothing());
   {
     RunLoop run_loop;
     injector()->AddEvent(0, run_loop.QuitClosure());
     run_loop.Run();
   }
   EXPECT_EQ(4, injector()->processed_events());
 }

 TEST_F(MessagePumpGLibTest, TestWorkWhileWaitingForEvents) {
   int task_count = 0;
   // Tests that we process tasks while waiting for new events.
   // The event queue is empty at first.
   for (int i = 0; i < 10; ++i) {
     loop()->task_runner()->PostTask(FROM_HERE,
                                     BindOnce(&IncrementInt, &task_count));
   }
   // After all the previous tasks have executed, enqueue an event that will
   // quit.
   {
     RunLoop run_loop;
     loop()->task_runner()->PostTask(
         FROM_HERE, BindOnce(&EventInjector::AddEvent, Unretained(injector()), 0,
                             run_loop.QuitClosure()));
     run_loop.Run();
   }
   ASSERT_EQ(10, task_count);
   EXPECT_EQ(1, injector()->processed_events());

   // Tests that we process delayed tasks while waiting for new events.
   injector()->Reset();
   task_count = 0;
   for (int i = 0; i < 10; ++i) {
     loop()->task_runner()->PostDelayedTask(FROM_HERE,
                                            BindOnce(&IncrementInt, &task_count),
                                            TimeDelta::FromMilliseconds(10 * i));
   }
   // After all the previous tasks have executed, enqueue an event that will
   // quit.
   // This relies on the fact that delayed tasks are executed in delay order.
   // That is verified in message_loop_unittest.cc.
   {
     RunLoop run_loop;
     loop()->task_runner()->PostDelayedTask(
         FROM_HERE,
         BindOnce(&EventInjector::AddEvent, Unretained(injector()), 0,
                  run_loop.QuitClosure()),
         TimeDelta::FromMilliseconds(150));
     run_loop.Run();
   }
   ASSERT_EQ(10, task_count);
   EXPECT_EQ(1, injector()->processed_events());
 }

 TEST_F(MessagePumpGLibTest, TestEventsWhileWaitingForWork) {
   // Tests that we process events while waiting for work.
   // The event queue is empty at first.
   for (int i = 0; i < 10; ++i) {
     injector()->AddDummyEvent(0);
   }
   // After all the events have been processed, post a task that will check that
   // the events have been processed (note: the task executes after the event
   // that posted it has been handled, so we expect 11 at that point).
   OnceClosure check_task =
       BindOnce(&ExpectProcessedEvents, Unretained(injector()), 11);
   OnceClosure posted_task =
       BindOnce(&PostMessageLoopTask, FROM_HERE, std::move(check_task));
   injector()->AddEventAsTask(10, std::move(posted_task));

   // And then quit (relies on the condition tested by TestEventTaskInterleave).
   RunLoop run_loop;
   injector()->AddEvent(10, run_loop.QuitClosure());
   run_loop.Run();

   EXPECT_EQ(12, injector()->processed_events());
 }

 namespace {

 // This class is a helper for the concurrent events / posted tasks test below.
 // It will quit the main loop once enough tasks and events have been processed,
 // while making sure there is always work to do and events in the queue.
 class ConcurrentHelper : public RefCounted<ConcurrentHelper>  {
  public:
   ConcurrentHelper(EventInjector* injector, OnceClosure done_closure)
       : injector_(injector),
         done_closure_(std::move(done_closure)),
         event_count_(kStartingEventCount),
         task_count_(kStartingTaskCount) {}

   void FromTask() {
     if (task_count_ > 0) {
       --task_count_;
     }
     if (task_count_ == 0 && event_count_ == 0) {
       std::move(done_closure_).Run();
     } else {
       ThreadTaskRunnerHandle::Get()->PostTask(
           FROM_HERE, BindOnce(&ConcurrentHelper::FromTask, this));
     }
   }

   void FromEvent() {
     if (event_count_ > 0) {
       --event_count_;
     }
     if (task_count_ == 0 && event_count_ == 0) {
       std::move(done_closure_).Run();
     } else {
       injector_->AddEventAsTask(0,
                                 BindOnce(&ConcurrentHelper::FromEvent, this));
     }
   }

   int event_count() const { return event_count_; }
   int task_count() const { return task_count_; }

  private:
   friend class RefCounted<ConcurrentHelper>;

   ~ConcurrentHelper() {}

   static const int kStartingEventCount = 20;
   static const int kStartingTaskCount = 20;

   EventInjector* injector_;
   OnceClosure done_closure_;
   int event_count_;
   int task_count_;
 };

 }  // namespace

 TEST_F(MessagePumpGLibTest, TestConcurrentEventPostedTask) {
   // Tests that posted tasks don't starve events, nor the opposite.
   // We use the helper class above. We keep both event and posted task queues
   // full, the helper verifies that both tasks and events get processed.
   // If that is not the case, either event_count_ or task_count_ will not get
   // to 0, and MessageLoop::QuitWhenIdle() will never be called.
   RunLoop run_loop;
   scoped_refptr<ConcurrentHelper> helper =
       new ConcurrentHelper(injector(), run_loop.QuitClosure());

   // Add 2 events to the queue to make sure it is always full (when we remove
   // the event before processing it).
   injector()->AddEventAsTask(0, BindOnce(&ConcurrentHelper::FromEvent, helper));
   injector()->AddEventAsTask(0, BindOnce(&ConcurrentHelper::FromEvent, helper));

   // Similarly post 2 tasks.
   loop()->task_runner()->PostTask(
       FROM_HERE, BindOnce(&ConcurrentHelper::FromTask, helper));
   loop()->task_runner()->PostTask(
       FROM_HERE, BindOnce(&ConcurrentHelper::FromTask, helper));

   run_loop.Run();
   EXPECT_EQ(0, helper->event_count());
   EXPECT_EQ(0, helper->task_count());
 }

 namespace {

 void AddEventsAndDrainGLib(EventInjector* injector, OnceClosure on_drained) {
   // Add a couple of dummy events
   injector->AddDummyEvent(0);
   injector->AddDummyEvent(0);
   // Then add an event that will quit the main loop.
   injector->AddEvent(0, std::move(on_drained));

   // Post a couple of dummy tasks
   ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE, DoNothing());
   ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE, DoNothing());

   // Drain the events
   while (g_main_context_pending(nullptr)) {
     g_main_context_iteration(nullptr, FALSE);
   }
 }

 }  // namespace

 TEST_F(MessagePumpGLibTest, TestDrainingGLib) {
   // Tests that draining events using GLib works.
   RunLoop run_loop;
   loop()->task_runner()->PostTask(
       FROM_HERE, BindOnce(&AddEventsAndDrainGLib, Unretained(injector()),
                           run_loop.QuitClosure()));
   run_loop.Run();

   EXPECT_EQ(3, injector()->processed_events());
 }

 namespace {

 // Helper class that lets us run the GLib message loop.
 class GLibLoopRunner : public RefCounted<GLibLoopRunner> {
  public:
   GLibLoopRunner() : quit_(false) { }

   void RunGLib() {
     while (!quit_) {
       g_main_context_iteration(nullptr, TRUE);
     }
   }

   void RunLoop() {
     while (!quit_) {
       g_main_context_iteration(nullptr, TRUE);
     }
   }

   void Quit() {
     quit_ = true;
   }

   void Reset() {
     quit_ = false;
   }

  private:
   friend class RefCounted<GLibLoopRunner>;

   ~GLibLoopRunner() {}

   bool quit_;
 };

 void TestGLibLoopInternal(EventInjector* injector, OnceClosure done) {
   // Allow tasks to be processed from 'native' event loops.
   MessageLoopCurrent::Get()->SetNestableTasksAllowed(true);
   scoped_refptr<GLibLoopRunner> runner = new GLibLoopRunner();

   int task_count = 0;
   // Add a couple of dummy events
   injector->AddDummyEvent(0);
   injector->AddDummyEvent(0);
   // Post a couple of dummy tasks
   ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
                                           BindOnce(&IncrementInt, &task_count));
   ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
                                           BindOnce(&IncrementInt, &task_count));
   // Delayed events
   injector->AddDummyEvent(10);
   injector->AddDummyEvent(10);
   // Delayed work
   ThreadTaskRunnerHandle::Get()->PostDelayedTask(
       FROM_HERE, BindOnce(&IncrementInt, &task_count),
       TimeDelta::FromMilliseconds(30));
   ThreadTaskRunnerHandle::Get()->PostDelayedTask(
       FROM_HERE, BindOnce(&GLibLoopRunner::Quit, runner),
       TimeDelta::FromMilliseconds(40));

   // Run a nested, straight GLib message loop.
   runner->RunGLib();

   ASSERT_EQ(3, task_count);
   EXPECT_EQ(4, injector->processed_events());
   std::move(done).Run();
 }

 void TestGtkLoopInternal(EventInjector* injector, OnceClosure done) {
   // Allow tasks to be processed from 'native' event loops.
   MessageLoopCurrent::Get()->SetNestableTasksAllowed(true);
   scoped_refptr<GLibLoopRunner> runner = new GLibLoopRunner();

   int task_count = 0;
   // Add a couple of dummy events
   injector->AddDummyEvent(0);
   injector->AddDummyEvent(0);
   // Post a couple of dummy tasks
   ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
                                           BindOnce(&IncrementInt, &task_count));
   ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
                                           BindOnce(&IncrementInt, &task_count));
   // Delayed events
   injector->AddDummyEvent(10);
   injector->AddDummyEvent(10);
   // Delayed work
   ThreadTaskRunnerHandle::Get()->PostDelayedTask(
       FROM_HERE, BindOnce(&IncrementInt, &task_count),
       TimeDelta::FromMilliseconds(30));
   ThreadTaskRunnerHandle::Get()->PostDelayedTask(
       FROM_HERE, BindOnce(&GLibLoopRunner::Quit, runner),
       TimeDelta::FromMilliseconds(40));

   // Run a nested, straight Gtk message loop.
   runner->RunLoop();

   ASSERT_EQ(3, task_count);
   EXPECT_EQ(4, injector->processed_events());
   std::move(done).Run();
 }

 }  // namespace

 TEST_F(MessagePumpGLibTest, TestGLibLoop) {
   // Tests that events and posted tasks are correctly executed if the message
   // loop is not run by MessageLoop::Run() but by a straight GLib loop.
   // Note that in this case we don't make strong guarantees about niceness
   // between events and posted tasks.
   RunLoop run_loop;
   loop()->task_runner()->PostTask(
       FROM_HERE, BindOnce(&TestGLibLoopInternal, Unretained(injector()),
                           run_loop.QuitClosure()));
   run_loop.Run();
 }

 TEST_F(MessagePumpGLibTest, TestGtkLoop) {
   // Tests that events and posted tasks are correctly executed if the message
   // loop is not run by MessageLoop::Run() but by a straight Gtk loop.
   // Note that in this case we don't make strong guarantees about niceness
   // between events and posted tasks.
   RunLoop run_loop;
   loop()->task_runner()->PostTask(
       FROM_HERE, BindOnce(&TestGtkLoopInternal, Unretained(injector()),
                           run_loop.QuitClosure()));
   run_loop.Run();
 }

 }  // namespace base
	// Copyright (c) 2012 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/message_loop/message_pump_glib.h"

	#include <glib.h>
	#include <math.h>

	#include <algorithm>
	#include <vector>

	#include "base/bind.h"
	#include "base/bind_helpers.h"
	#include "base/callback.h"
	#include "base/macros.h"
	#include "base/memory/ref_counted.h"
	#include "base/message_loop/message_loop.h"
	#include "base/message_loop/message_loop_current.h"
	#include "base/run_loop.h"
	#include "base/single_thread_task_runner.h"
	#include "base/threading/thread.h"
	#include "base/threading/thread_task_runner_handle.h"
	#include "starboard/types.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace base {
	namespace {

	// This class injects dummy "events" into the GLib loop. When "handled" these
	// events can run tasks. This is intended to mock gtk events (the corresponding
	// GLib source runs at the same priority).
	class EventInjector {
	public:
	EventInjector() : processed_events_(0) {
	source_ = static_cast<Source*>(g_source_new(&SourceFuncs, sizeof(Source)));
	source_->injector = this;
	g_source_attach(source_, nullptr);
	g_source_set_can_recurse(source_, TRUE);
	}

	~EventInjector() {
	g_source_destroy(source_);
	g_source_unref(source_);
	}

	int HandlePrepare() {
	// If the queue is empty, block.
	if (events_.empty())
	return -1;
	TimeDelta delta = events_[0].time - Time::NowFromSystemTime();
	return std::max(0, static_cast<int>(ceil(delta.InMillisecondsF())));
	}

	bool HandleCheck() {
	if (events_.empty())
	return false;
	return events_[0].time <= Time::NowFromSystemTime();
	}

	void HandleDispatch() {
	if (events_.empty())
	return;
	Event event = std::move(events_[0]);
	events_.erase(events_.begin());
	++processed_events_;
	if (!event.callback.is_null())
	std::move(event.callback).Run();
	else if (!event.task.is_null())
	std::move(event.task).Run();
	}

	// Adds an event to the queue. When "handled", executes \|callback\|.
	// delay_ms is relative to the last event if any, or to Now() otherwise.
	void AddEvent(int delay_ms, OnceClosure callback) {
	AddEventHelper(delay_ms, std::move(callback), OnceClosure());
	}

	void AddDummyEvent(int delay_ms) {
	AddEventHelper(delay_ms, OnceClosure(), OnceClosure());
	}

	void AddEventAsTask(int delay_ms, OnceClosure task) {
	AddEventHelper(delay_ms, OnceClosure(), std::move(task));
	}

	void Reset() {
	processed_events_ = 0;
	events_.clear();
	}

	int processed_events() const { return processed_events_; }

	private:
	struct Event {
	Time time;
	OnceClosure callback;
	OnceClosure task;
	};

	struct Source : public GSource {
	EventInjector* injector;
	};

	void AddEventHelper(int delay_ms, OnceClosure callback, OnceClosure task) {
	Time last_time;
	if (!events_.empty())
	last_time = (events_.end()-1)->time;
	else
	last_time = Time::NowFromSystemTime();

	Time future = last_time + TimeDelta::FromMilliseconds(delay_ms);
	EventInjector::Event event = {future, std::move(callback), std::move(task)};
	events_.push_back(std::move(event));
	}

	static gboolean Prepare(GSource* source, gint* timeout_ms) {
	timeout_ms = static_cast<Source>(source)->injector->HandlePrepare();
	return FALSE;
	}

	static gboolean Check(GSource* source) {
	return static_cast<Source*>(source)->injector->HandleCheck();
	}

	static gboolean Dispatch(GSource* source,
	GSourceFunc unused_func,
	gpointer unused_data) {
	static_cast<Source*>(source)->injector->HandleDispatch();
	return TRUE;
	}

	Source* source_;
	std::vector<Event> events_;
	int processed_events_;
	static GSourceFuncs SourceFuncs;
	DISALLOW_COPY_AND_ASSIGN(EventInjector);
	};

	GSourceFuncs EventInjector::SourceFuncs = {EventInjector::Prepare,
	EventInjector::Check,
	EventInjector::Dispatch, nullptr};

	void IncrementInt(int *value) {
	++*value;
	}

	// Checks how many events have been processed by the injector.
	void ExpectProcessedEvents(EventInjector* injector, int count) {
	EXPECT_EQ(injector->processed_events(), count);
	}

	// Posts a task on the current message loop.
	void PostMessageLoopTask(const Location& from_here, OnceClosure task) {
	ThreadTaskRunnerHandle::Get()->PostTask(from_here, std::move(task));
	}

	// Test fixture.
	class MessagePumpGLibTest : public testing::Test {
	public:
	MessagePumpGLibTest() : loop_(nullptr), injector_(nullptr) {}

	// Overridden from testing::Test:
	void SetUp() override {
	loop_ = new MessageLoop(MessageLoop::TYPE_UI);
	injector_ = new EventInjector();
	}
	void TearDown() override {
	delete injector_;
	injector_ = nullptr;
	delete loop_;
	loop_ = nullptr;
	}

	MessageLoop* loop() const { return loop_; }
	EventInjector* injector() const { return injector_; }

	private:
	MessageLoop* loop_;
	EventInjector* injector_;
	DISALLOW_COPY_AND_ASSIGN(MessagePumpGLibTest);
	};

	} // namespace

	TEST_F(MessagePumpGLibTest, TestQuit) {
	// Checks that Quit works and that the basic infrastructure is working.

	// Quit from a task
	RunLoop().RunUntilIdle();
	EXPECT_EQ(0, injector()->processed_events());

	injector()->Reset();
	// Quit from an event
	RunLoop run_loop;
	injector()->AddEvent(0, run_loop.QuitClosure());
	run_loop.Run();
	EXPECT_EQ(1, injector()->processed_events());
	}

	TEST_F(MessagePumpGLibTest, TestEventTaskInterleave) {
	// Checks that tasks posted by events are executed before the next event if
	// the posted task queue is empty.
	// MessageLoop doesn't make strong guarantees that it is the case, but the
	// current implementation ensures it and the tests below rely on it.
	// If changes cause this test to fail, it is reasonable to change it, but
	// TestWorkWhileWaitingForEvents and TestEventsWhileWaitingForWork have to be
	// changed accordingly, otherwise they can become flaky.
	injector()->AddEventAsTask(0, DoNothing());
	OnceClosure check_task =
	BindOnce(&ExpectProcessedEvents, Unretained(injector()), 2);
	OnceClosure posted_task =
	BindOnce(&PostMessageLoopTask, FROM_HERE, std::move(check_task));
	injector()->AddEventAsTask(0, std::move(posted_task));
	injector()->AddEventAsTask(0, DoNothing());
	{
	RunLoop run_loop;
	injector()->AddEvent(0, run_loop.QuitClosure());
	run_loop.Run();
	}
	EXPECT_EQ(4, injector()->processed_events());

	injector()->Reset();
	injector()->AddEventAsTask(0, DoNothing());
	check_task = BindOnce(&ExpectProcessedEvents, Unretained(injector()), 2);
	posted_task =
	BindOnce(&PostMessageLoopTask, FROM_HERE, std::move(check_task));
	injector()->AddEventAsTask(0, std::move(posted_task));
	injector()->AddEventAsTask(10, DoNothing());
	{
	RunLoop run_loop;
	injector()->AddEvent(0, run_loop.QuitClosure());
	run_loop.Run();
	}
	EXPECT_EQ(4, injector()->processed_events());
	}

	TEST_F(MessagePumpGLibTest, TestWorkWhileWaitingForEvents) {
	int task_count = 0;
	// Tests that we process tasks while waiting for new events.
	// The event queue is empty at first.
	for (int i = 0; i < 10; ++i) {
	loop()->task_runner()->PostTask(FROM_HERE,
	BindOnce(&IncrementInt, &task_count));
	}
	// After all the previous tasks have executed, enqueue an event that will
	// quit.
	{
	RunLoop run_loop;
	loop()->task_runner()->PostTask(
	FROM_HERE, BindOnce(&EventInjector::AddEvent, Unretained(injector()), 0,
	run_loop.QuitClosure()));
	run_loop.Run();
	}
	ASSERT_EQ(10, task_count);
	EXPECT_EQ(1, injector()->processed_events());

	// Tests that we process delayed tasks while waiting for new events.
	injector()->Reset();
	task_count = 0;
	for (int i = 0; i < 10; ++i) {
	loop()->task_runner()->PostDelayedTask(FROM_HERE,
	BindOnce(&IncrementInt, &task_count),
	TimeDelta::FromMilliseconds(10 * i));
	}
	// After all the previous tasks have executed, enqueue an event that will
	// quit.
	// This relies on the fact that delayed tasks are executed in delay order.
	// That is verified in message_loop_unittest.cc.
	{
	RunLoop run_loop;
	loop()->task_runner()->PostDelayedTask(
	FROM_HERE,
	BindOnce(&EventInjector::AddEvent, Unretained(injector()), 0,
	run_loop.QuitClosure()),
	TimeDelta::FromMilliseconds(150));
	run_loop.Run();
	}
	ASSERT_EQ(10, task_count);
	EXPECT_EQ(1, injector()->processed_events());
	}

	TEST_F(MessagePumpGLibTest, TestEventsWhileWaitingForWork) {
	// Tests that we process events while waiting for work.
	// The event queue is empty at first.
	for (int i = 0; i < 10; ++i) {
	injector()->AddDummyEvent(0);
	}
	// After all the events have been processed, post a task that will check that
	// the events have been processed (note: the task executes after the event
	// that posted it has been handled, so we expect 11 at that point).
	OnceClosure check_task =
	BindOnce(&ExpectProcessedEvents, Unretained(injector()), 11);
	OnceClosure posted_task =
	BindOnce(&PostMessageLoopTask, FROM_HERE, std::move(check_task));
	injector()->AddEventAsTask(10, std::move(posted_task));

	// And then quit (relies on the condition tested by TestEventTaskInterleave).
	RunLoop run_loop;
	injector()->AddEvent(10, run_loop.QuitClosure());
	run_loop.Run();

	EXPECT_EQ(12, injector()->processed_events());
	}

	namespace {

	// This class is a helper for the concurrent events / posted tasks test below.
	// It will quit the main loop once enough tasks and events have been processed,
	// while making sure there is always work to do and events in the queue.
	class ConcurrentHelper : public RefCounted<ConcurrentHelper> {
	public:
	ConcurrentHelper(EventInjector* injector, OnceClosure done_closure)
	: injector_(injector),
	done_closure_(std::move(done_closure)),
	event_count_(kStartingEventCount),
	task_count_(kStartingTaskCount) {}

	void FromTask() {
	if (task_count_ > 0) {
	--task_count_;
	}
	if (task_count_ == 0 && event_count_ == 0) {
	std::move(done_closure_).Run();
	} else {
	ThreadTaskRunnerHandle::Get()->PostTask(
	FROM_HERE, BindOnce(&ConcurrentHelper::FromTask, this));
	}
	}

	void FromEvent() {
	if (event_count_ > 0) {
	--event_count_;
	}
	if (task_count_ == 0 && event_count_ == 0) {
	std::move(done_closure_).Run();
	} else {
	injector_->AddEventAsTask(0,
	BindOnce(&ConcurrentHelper::FromEvent, this));
	}
	}

	int event_count() const { return event_count_; }
	int task_count() const { return task_count_; }

	private:
	friend class RefCounted<ConcurrentHelper>;

	~ConcurrentHelper() {}

	static const int kStartingEventCount = 20;
	static const int kStartingTaskCount = 20;

	EventInjector* injector_;
	OnceClosure done_closure_;
	int event_count_;
	int task_count_;
	};

	} // namespace

	TEST_F(MessagePumpGLibTest, TestConcurrentEventPostedTask) {
	// Tests that posted tasks don't starve events, nor the opposite.
	// We use the helper class above. We keep both event and posted task queues
	// full, the helper verifies that both tasks and events get processed.
	// If that is not the case, either event_count_ or task_count_ will not get
	// to 0, and MessageLoop::QuitWhenIdle() will never be called.
	RunLoop run_loop;
	scoped_refptr<ConcurrentHelper> helper =
	new ConcurrentHelper(injector(), run_loop.QuitClosure());

	// Add 2 events to the queue to make sure it is always full (when we remove
	// the event before processing it).
	injector()->AddEventAsTask(0, BindOnce(&ConcurrentHelper::FromEvent, helper));
	injector()->AddEventAsTask(0, BindOnce(&ConcurrentHelper::FromEvent, helper));

	// Similarly post 2 tasks.
	loop()->task_runner()->PostTask(
	FROM_HERE, BindOnce(&ConcurrentHelper::FromTask, helper));
	loop()->task_runner()->PostTask(
	FROM_HERE, BindOnce(&ConcurrentHelper::FromTask, helper));

	run_loop.Run();
	EXPECT_EQ(0, helper->event_count());
	EXPECT_EQ(0, helper->task_count());
	}

	namespace {

	void AddEventsAndDrainGLib(EventInjector* injector, OnceClosure on_drained) {
	// Add a couple of dummy events
	injector->AddDummyEvent(0);
	injector->AddDummyEvent(0);
	// Then add an event that will quit the main loop.
	injector->AddEvent(0, std::move(on_drained));

	// Post a couple of dummy tasks
	ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE, DoNothing());
	ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE, DoNothing());

	// Drain the events
	while (g_main_context_pending(nullptr)) {
	g_main_context_iteration(nullptr, FALSE);
	}
	}

	} // namespace

	TEST_F(MessagePumpGLibTest, TestDrainingGLib) {
	// Tests that draining events using GLib works.
	RunLoop run_loop;
	loop()->task_runner()->PostTask(
	FROM_HERE, BindOnce(&AddEventsAndDrainGLib, Unretained(injector()),
	run_loop.QuitClosure()));
	run_loop.Run();

	EXPECT_EQ(3, injector()->processed_events());
	}

	namespace {

	// Helper class that lets us run the GLib message loop.
	class GLibLoopRunner : public RefCounted<GLibLoopRunner> {
	public:
	GLibLoopRunner() : quit_(false) { }

	void RunGLib() {
	while (!quit_) {
	g_main_context_iteration(nullptr, TRUE);
	}
	}

	void RunLoop() {
	while (!quit_) {
	g_main_context_iteration(nullptr, TRUE);
	}
	}

	void Quit() {
	quit_ = true;
	}

	void Reset() {
	quit_ = false;
	}

	private:
	friend class RefCounted<GLibLoopRunner>;

	~GLibLoopRunner() {}

	bool quit_;
	};

	void TestGLibLoopInternal(EventInjector* injector, OnceClosure done) {
	// Allow tasks to be processed from 'native' event loops.
	MessageLoopCurrent::Get()->SetNestableTasksAllowed(true);
	scoped_refptr<GLibLoopRunner> runner = new GLibLoopRunner();

	int task_count = 0;
	// Add a couple of dummy events
	injector->AddDummyEvent(0);
	injector->AddDummyEvent(0);
	// Post a couple of dummy tasks
	ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
	BindOnce(&IncrementInt, &task_count));
	ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
	BindOnce(&IncrementInt, &task_count));
	// Delayed events
	injector->AddDummyEvent(10);
	injector->AddDummyEvent(10);
	// Delayed work
	ThreadTaskRunnerHandle::Get()->PostDelayedTask(
	FROM_HERE, BindOnce(&IncrementInt, &task_count),
	TimeDelta::FromMilliseconds(30));
	ThreadTaskRunnerHandle::Get()->PostDelayedTask(
	FROM_HERE, BindOnce(&GLibLoopRunner::Quit, runner),
	TimeDelta::FromMilliseconds(40));

	// Run a nested, straight GLib message loop.
	runner->RunGLib();

	ASSERT_EQ(3, task_count);
	EXPECT_EQ(4, injector->processed_events());
	std::move(done).Run();
	}

	void TestGtkLoopInternal(EventInjector* injector, OnceClosure done) {
	// Allow tasks to be processed from 'native' event loops.
	MessageLoopCurrent::Get()->SetNestableTasksAllowed(true);
	scoped_refptr<GLibLoopRunner> runner = new GLibLoopRunner();

	int task_count = 0;
	// Add a couple of dummy events
	injector->AddDummyEvent(0);
	injector->AddDummyEvent(0);
	// Post a couple of dummy tasks
	ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
	BindOnce(&IncrementInt, &task_count));
	ThreadTaskRunnerHandle::Get()->PostTask(FROM_HERE,
	BindOnce(&IncrementInt, &task_count));
	// Delayed events
	injector->AddDummyEvent(10);
	injector->AddDummyEvent(10);
	// Delayed work
	ThreadTaskRunnerHandle::Get()->PostDelayedTask(
	FROM_HERE, BindOnce(&IncrementInt, &task_count),
	TimeDelta::FromMilliseconds(30));
	ThreadTaskRunnerHandle::Get()->PostDelayedTask(
	FROM_HERE, BindOnce(&GLibLoopRunner::Quit, runner),
	TimeDelta::FromMilliseconds(40));

	// Run a nested, straight Gtk message loop.
	runner->RunLoop();

	ASSERT_EQ(3, task_count);
	EXPECT_EQ(4, injector->processed_events());
	std::move(done).Run();
	}

	} // namespace

	TEST_F(MessagePumpGLibTest, TestGLibLoop) {
	// Tests that events and posted tasks are correctly executed if the message
	// loop is not run by MessageLoop::Run() but by a straight GLib loop.
	// Note that in this case we don't make strong guarantees about niceness
	// between events and posted tasks.
	RunLoop run_loop;
	loop()->task_runner()->PostTask(
	FROM_HERE, BindOnce(&TestGLibLoopInternal, Unretained(injector()),
	run_loop.QuitClosure()));
	run_loop.Run();
	}

	TEST_F(MessagePumpGLibTest, TestGtkLoop) {
	// Tests that events and posted tasks are correctly executed if the message
	// loop is not run by MessageLoop::Run() but by a straight Gtk loop.
	// Note that in this case we don't make strong guarantees about niceness
	// between events and posted tasks.
	RunLoop run_loop;
	loop()->task_runner()->PostTask(
	FROM_HERE, BindOnce(&TestGtkLoopInternal, Unretained(injector()),
	run_loop.QuitClosure()));
	run_loop.Run();
	}

	} // namespace base