cc/base/delayed_unique_notifier_unittest.cc - chromium/src - Git at Google

 // Copyright 2014 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include <deque>

 #include "base/bind.h"
 #include "base/bind_helpers.h"
 #include "base/test/test_pending_task.h"
 #include "base/test/test_simple_task_runner.h"
 #include "cc/base/delayed_unique_notifier.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace cc {
 namespace {

 class TestNotifier : public DelayedUniqueNotifier {
  public:
   TestNotifier(base::SequencedTaskRunner* task_runner,
                const base::Closure& closure,
                const base::TimeDelta& delay)
       : DelayedUniqueNotifier(task_runner, closure, delay) {}
   ~TestNotifier() override {}

   // Overridden from DelayedUniqueNotifier:
   base::TimeTicks Now() const override { return now_; }

   void SetNow(base::TimeTicks now) { now_ = now; }

  private:
   base::TimeTicks now_;
 };

 class DelayedUniqueNotifierTest : public testing::Test {
  public:
   DelayedUniqueNotifierTest() : notification_count_(0) {}

   void SetUp() override {
     notification_count_ = 0;
     task_runner_ = make_scoped_refptr(new base::TestSimpleTaskRunner);
   }

   void Notify() { ++notification_count_; }

   int NotificationCount() const { return notification_count_; }

   std::deque<base::TestPendingTask> TakePendingTasks() {
     std::deque<base::TestPendingTask> tasks = task_runner_->GetPendingTasks();
     task_runner_->ClearPendingTasks();
     return tasks;
   }

  protected:
   int notification_count_;
   scoped_refptr<base::TestSimpleTaskRunner> task_runner_;
 };

 TEST_F(DelayedUniqueNotifierTest, ZeroDelay) {
   base::TimeDelta delay = base::TimeDelta::FromInternalValue(0);
   TestNotifier notifier(
       task_runner_.get(),
       base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
       delay);

   EXPECT_EQ(0, NotificationCount());

   // Basic schedule for |delay| from now.
   base::TimeTicks schedule_time =
       base::TimeTicks() + base::TimeDelta::FromInternalValue(10);

   notifier.SetNow(schedule_time);
   notifier.Schedule();

   std::deque<base::TestPendingTask> tasks = TakePendingTasks();
   ASSERT_EQ(1u, tasks.size());
   EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

   tasks[0].task.Run();
   EXPECT_EQ(1, NotificationCount());

   // 5 schedules should result in only one run.
   for (int i = 0; i < 5; ++i)
     notifier.Schedule();

   tasks = TakePendingTasks();
   ASSERT_EQ(1u, tasks.size());
   EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

   tasks[0].task.Run();
   EXPECT_EQ(2, NotificationCount());
 }

 TEST_F(DelayedUniqueNotifierTest, SmallDelay) {
   base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
   TestNotifier notifier(
       task_runner_.get(),
       base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
       delay);

   EXPECT_EQ(0, NotificationCount());

   // Basic schedule for |delay| from now (now: 30, run time: 50).
   base::TimeTicks schedule_time =
       base::TimeTicks() + base::TimeDelta::FromInternalValue(30);

   notifier.SetNow(schedule_time);
   notifier.Schedule();

   std::deque<base::TestPendingTask> tasks = TakePendingTasks();

   ASSERT_EQ(1u, tasks.size());
   EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

   // It's not yet time to run, so we expect no notifications.
   tasks[0].task.Run();
   EXPECT_EQ(0, NotificationCount());

   tasks = TakePendingTasks();

   ASSERT_EQ(1u, tasks.size());
   // Now the time should be delay minus whatever the value of now happens to be
   // (now: 30, run time: 50).
   base::TimeTicks scheduled_run_time = notifier.Now() + delay;
   base::TimeTicks scheduled_delay =
       base::TimeTicks() + (scheduled_run_time - notifier.Now());
   EXPECT_EQ(scheduled_delay, tasks[0].GetTimeToRun());

   // Move closer to the run time (time: 49, run time: 50).
   notifier.SetNow(notifier.Now() + base::TimeDelta::FromInternalValue(19));

   // It's not yet time to run, so we expect no notifications.
   tasks[0].task.Run();
   EXPECT_EQ(0, NotificationCount());

   tasks = TakePendingTasks();
   ASSERT_EQ(1u, tasks.size());

   // Now the time should be delay minus whatever the value of now happens to be.
   scheduled_delay = base::TimeTicks() + (scheduled_run_time - notifier.Now());
   EXPECT_EQ(scheduled_delay, tasks[0].GetTimeToRun());

   // Move to exactly the run time (time: 50, run time: 50).
   notifier.SetNow(notifier.Now() + base::TimeDelta::FromInternalValue(1));

   // It's time to run!
   tasks[0].task.Run();
   EXPECT_EQ(1, NotificationCount());

   tasks = TakePendingTasks();
   EXPECT_EQ(0u, tasks.size());
 }

 TEST_F(DelayedUniqueNotifierTest, RescheduleDelay) {
   base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
   TestNotifier notifier(
       task_runner_.get(),
       base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
       delay);

   base::TimeTicks schedule_time;
   // Move time 19 units forward and reschedule, expecting that we still need to
   // run in |delay| time and we don't get a notification.
   for (int i = 0; i < 10; ++i) {
     EXPECT_EQ(0, NotificationCount());

     // Move time forward 19 units.
     schedule_time = notifier.Now() + base::TimeDelta::FromInternalValue(19);
     notifier.SetNow(schedule_time);
     notifier.Schedule();

     std::deque<base::TestPendingTask> tasks = TakePendingTasks();

     ASSERT_EQ(1u, tasks.size());
     EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

     // It's not yet time to run, so we expect no notifications.
     tasks[0].task.Run();
     EXPECT_EQ(0, NotificationCount());
   }

   // Move time forward 20 units, expecting a notification.
   schedule_time = notifier.Now() + base::TimeDelta::FromInternalValue(20);
   notifier.SetNow(schedule_time);

   std::deque<base::TestPendingTask> tasks = TakePendingTasks();

   ASSERT_EQ(1u, tasks.size());
   EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

   // Time to run!
   tasks[0].task.Run();
   EXPECT_EQ(1, NotificationCount());
 }

 TEST_F(DelayedUniqueNotifierTest, CancelAndHasPendingNotification) {
   base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
   TestNotifier notifier(
       task_runner_.get(),
       base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
       delay);

   EXPECT_EQ(0, NotificationCount());

   // Schedule for |delay| seconds from now.
   base::TimeTicks schedule_time =
       notifier.Now() + base::TimeDelta::FromInternalValue(10);
   notifier.SetNow(schedule_time);
   notifier.Schedule();
   EXPECT_TRUE(notifier.HasPendingNotification());

   // Cancel the run.
   notifier.Cancel();
   EXPECT_FALSE(notifier.HasPendingNotification());

   std::deque<base::TestPendingTask> tasks = TakePendingTasks();

   ASSERT_EQ(1u, tasks.size());
   EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

   // Time to run, but a canceled task!
   tasks[0].task.Run();
   EXPECT_EQ(0, NotificationCount());
   EXPECT_FALSE(notifier.HasPendingNotification());

   tasks = TakePendingTasks();
   EXPECT_EQ(0u, tasks.size());

   notifier.Schedule();
   EXPECT_TRUE(notifier.HasPendingNotification());
   tasks = TakePendingTasks();

   ASSERT_EQ(1u, tasks.size());
   EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

   // Advance the time.
   notifier.SetNow(notifier.Now() + delay);

   // This should run since it wasn't canceled.
   tasks[0].task.Run();
   EXPECT_EQ(1, NotificationCount());
   EXPECT_FALSE(notifier.HasPendingNotification());

   for (int i = 0; i < 10; ++i) {
     notifier.Schedule();
     EXPECT_TRUE(notifier.HasPendingNotification());
     notifier.Cancel();
     EXPECT_FALSE(notifier.HasPendingNotification());
   }

   tasks = TakePendingTasks();

   ASSERT_EQ(1u, tasks.size());
   EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

   // Time to run, but a canceled task!
   notifier.SetNow(notifier.Now() + delay);
   tasks[0].task.Run();
   EXPECT_EQ(1, NotificationCount());

   tasks = TakePendingTasks();
   EXPECT_EQ(0u, tasks.size());
   EXPECT_FALSE(notifier.HasPendingNotification());
 }

 TEST_F(DelayedUniqueNotifierTest, ShutdownWithScheduledTask) {
   base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
   TestNotifier notifier(
       task_runner_.get(),
       base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
       delay);

   EXPECT_EQ(0, NotificationCount());

   // Schedule for |delay| seconds from now.
   base::TimeTicks schedule_time =
       notifier.Now() + base::TimeDelta::FromInternalValue(10);
   notifier.SetNow(schedule_time);
   notifier.Schedule();
   EXPECT_TRUE(notifier.HasPendingNotification());

   // Shutdown the notifier.
   notifier.Shutdown();

   // The task is still there, but...
   std::deque<base::TestPendingTask> tasks = TakePendingTasks();
   ASSERT_EQ(1u, tasks.size());

   // Running the task after shutdown does nothing since it's cancelled.
   tasks[0].task.Run();
   EXPECT_EQ(0, NotificationCount());

   tasks = TakePendingTasks();
   EXPECT_EQ(0u, tasks.size());

   // We are no longer able to schedule tasks.
   notifier.Schedule();
   tasks = TakePendingTasks();
   ASSERT_EQ(0u, tasks.size());

   // Verify after the scheduled time happens there is still no task.
   notifier.SetNow(notifier.Now() + delay);
   tasks = TakePendingTasks();
   ASSERT_EQ(0u, tasks.size());
 }

 TEST_F(DelayedUniqueNotifierTest, ShutdownPreventsSchedule) {
   base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
   TestNotifier notifier(
       task_runner_.get(),
       base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
       delay);

   EXPECT_EQ(0, NotificationCount());

   // Schedule for |delay| seconds from now.
   base::TimeTicks schedule_time =
       notifier.Now() + base::TimeDelta::FromInternalValue(10);
   notifier.SetNow(schedule_time);

   // Shutdown the notifier.
   notifier.Shutdown();

   // Scheduling a task no longer does anything.
   notifier.Schedule();
   std::deque<base::TestPendingTask> tasks = TakePendingTasks();
   ASSERT_EQ(0u, tasks.size());

   // Verify after the scheduled time happens there is still no task.
   notifier.SetNow(notifier.Now() + delay);
   tasks = TakePendingTasks();
   ASSERT_EQ(0u, tasks.size());
 }

 }  // namespace
 }  // namespace cc
	// Copyright 2014 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include <deque>

	#include "base/bind.h"
	#include "base/bind_helpers.h"
	#include "base/test/test_pending_task.h"
	#include "base/test/test_simple_task_runner.h"
	#include "cc/base/delayed_unique_notifier.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace cc {
	namespace {

	class TestNotifier : public DelayedUniqueNotifier {
	public:
	TestNotifier(base::SequencedTaskRunner* task_runner,
	const base::Closure& closure,
	const base::TimeDelta& delay)
	: DelayedUniqueNotifier(task_runner, closure, delay) {}
	~TestNotifier() override {}

	// Overridden from DelayedUniqueNotifier:
	base::TimeTicks Now() const override { return now_; }

	void SetNow(base::TimeTicks now) { now_ = now; }

	private:
	base::TimeTicks now_;
	};

	class DelayedUniqueNotifierTest : public testing::Test {
	public:
	DelayedUniqueNotifierTest() : notification_count_(0) {}

	void SetUp() override {
	notification_count_ = 0;
	task_runner_ = make_scoped_refptr(new base::TestSimpleTaskRunner);
	}

	void Notify() { ++notification_count_; }

	int NotificationCount() const { return notification_count_; }

	std::deque<base::TestPendingTask> TakePendingTasks() {
	std::deque<base::TestPendingTask> tasks = task_runner_->GetPendingTasks();
	task_runner_->ClearPendingTasks();
	return tasks;
	}

	protected:
	int notification_count_;
	scoped_refptr<base::TestSimpleTaskRunner> task_runner_;
	};

	TEST_F(DelayedUniqueNotifierTest, ZeroDelay) {
	base::TimeDelta delay = base::TimeDelta::FromInternalValue(0);
	TestNotifier notifier(
	task_runner_.get(),
	base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
	delay);

	EXPECT_EQ(0, NotificationCount());

	// Basic schedule for \|delay\| from now.
	base::TimeTicks schedule_time =
	base::TimeTicks() + base::TimeDelta::FromInternalValue(10);

	notifier.SetNow(schedule_time);
	notifier.Schedule();

	std::deque<base::TestPendingTask> tasks = TakePendingTasks();
	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	tasks[0].task.Run();
	EXPECT_EQ(1, NotificationCount());

	// 5 schedules should result in only one run.
	for (int i = 0; i < 5; ++i)
	notifier.Schedule();

	tasks = TakePendingTasks();
	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	tasks[0].task.Run();
	EXPECT_EQ(2, NotificationCount());
	}

	TEST_F(DelayedUniqueNotifierTest, SmallDelay) {
	base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
	TestNotifier notifier(
	task_runner_.get(),
	base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
	delay);

	EXPECT_EQ(0, NotificationCount());

	// Basic schedule for \|delay\| from now (now: 30, run time: 50).
	base::TimeTicks schedule_time =
	base::TimeTicks() + base::TimeDelta::FromInternalValue(30);

	notifier.SetNow(schedule_time);
	notifier.Schedule();

	std::deque<base::TestPendingTask> tasks = TakePendingTasks();

	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	// It's not yet time to run, so we expect no notifications.
	tasks[0].task.Run();
	EXPECT_EQ(0, NotificationCount());

	tasks = TakePendingTasks();

	ASSERT_EQ(1u, tasks.size());
	// Now the time should be delay minus whatever the value of now happens to be
	// (now: 30, run time: 50).
	base::TimeTicks scheduled_run_time = notifier.Now() + delay;
	base::TimeTicks scheduled_delay =
	base::TimeTicks() + (scheduled_run_time - notifier.Now());
	EXPECT_EQ(scheduled_delay, tasks[0].GetTimeToRun());

	// Move closer to the run time (time: 49, run time: 50).
	notifier.SetNow(notifier.Now() + base::TimeDelta::FromInternalValue(19));

	// It's not yet time to run, so we expect no notifications.
	tasks[0].task.Run();
	EXPECT_EQ(0, NotificationCount());

	tasks = TakePendingTasks();
	ASSERT_EQ(1u, tasks.size());

	// Now the time should be delay minus whatever the value of now happens to be.
	scheduled_delay = base::TimeTicks() + (scheduled_run_time - notifier.Now());
	EXPECT_EQ(scheduled_delay, tasks[0].GetTimeToRun());

	// Move to exactly the run time (time: 50, run time: 50).
	notifier.SetNow(notifier.Now() + base::TimeDelta::FromInternalValue(1));

	// It's time to run!
	tasks[0].task.Run();
	EXPECT_EQ(1, NotificationCount());

	tasks = TakePendingTasks();
	EXPECT_EQ(0u, tasks.size());
	}

	TEST_F(DelayedUniqueNotifierTest, RescheduleDelay) {
	base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
	TestNotifier notifier(
	task_runner_.get(),
	base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
	delay);

	base::TimeTicks schedule_time;
	// Move time 19 units forward and reschedule, expecting that we still need to
	// run in \|delay\| time and we don't get a notification.
	for (int i = 0; i < 10; ++i) {
	EXPECT_EQ(0, NotificationCount());

	// Move time forward 19 units.
	schedule_time = notifier.Now() + base::TimeDelta::FromInternalValue(19);
	notifier.SetNow(schedule_time);
	notifier.Schedule();

	std::deque<base::TestPendingTask> tasks = TakePendingTasks();

	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	// It's not yet time to run, so we expect no notifications.
	tasks[0].task.Run();
	EXPECT_EQ(0, NotificationCount());
	}

	// Move time forward 20 units, expecting a notification.
	schedule_time = notifier.Now() + base::TimeDelta::FromInternalValue(20);
	notifier.SetNow(schedule_time);

	std::deque<base::TestPendingTask> tasks = TakePendingTasks();

	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	// Time to run!
	tasks[0].task.Run();
	EXPECT_EQ(1, NotificationCount());
	}

	TEST_F(DelayedUniqueNotifierTest, CancelAndHasPendingNotification) {
	base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
	TestNotifier notifier(
	task_runner_.get(),
	base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
	delay);

	EXPECT_EQ(0, NotificationCount());

	// Schedule for \|delay\| seconds from now.
	base::TimeTicks schedule_time =
	notifier.Now() + base::TimeDelta::FromInternalValue(10);
	notifier.SetNow(schedule_time);
	notifier.Schedule();
	EXPECT_TRUE(notifier.HasPendingNotification());

	// Cancel the run.
	notifier.Cancel();
	EXPECT_FALSE(notifier.HasPendingNotification());

	std::deque<base::TestPendingTask> tasks = TakePendingTasks();

	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	// Time to run, but a canceled task!
	tasks[0].task.Run();
	EXPECT_EQ(0, NotificationCount());
	EXPECT_FALSE(notifier.HasPendingNotification());

	tasks = TakePendingTasks();
	EXPECT_EQ(0u, tasks.size());

	notifier.Schedule();
	EXPECT_TRUE(notifier.HasPendingNotification());
	tasks = TakePendingTasks();

	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	// Advance the time.
	notifier.SetNow(notifier.Now() + delay);

	// This should run since it wasn't canceled.
	tasks[0].task.Run();
	EXPECT_EQ(1, NotificationCount());
	EXPECT_FALSE(notifier.HasPendingNotification());

	for (int i = 0; i < 10; ++i) {
	notifier.Schedule();
	EXPECT_TRUE(notifier.HasPendingNotification());
	notifier.Cancel();
	EXPECT_FALSE(notifier.HasPendingNotification());
	}

	tasks = TakePendingTasks();

	ASSERT_EQ(1u, tasks.size());
	EXPECT_EQ(base::TimeTicks() + delay, tasks[0].GetTimeToRun());

	// Time to run, but a canceled task!
	notifier.SetNow(notifier.Now() + delay);
	tasks[0].task.Run();
	EXPECT_EQ(1, NotificationCount());

	tasks = TakePendingTasks();
	EXPECT_EQ(0u, tasks.size());
	EXPECT_FALSE(notifier.HasPendingNotification());
	}

	TEST_F(DelayedUniqueNotifierTest, ShutdownWithScheduledTask) {
	base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
	TestNotifier notifier(
	task_runner_.get(),
	base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
	delay);

	EXPECT_EQ(0, NotificationCount());

	// Schedule for \|delay\| seconds from now.
	base::TimeTicks schedule_time =
	notifier.Now() + base::TimeDelta::FromInternalValue(10);
	notifier.SetNow(schedule_time);
	notifier.Schedule();
	EXPECT_TRUE(notifier.HasPendingNotification());

	// Shutdown the notifier.
	notifier.Shutdown();

	// The task is still there, but...
	std::deque<base::TestPendingTask> tasks = TakePendingTasks();
	ASSERT_EQ(1u, tasks.size());

	// Running the task after shutdown does nothing since it's cancelled.
	tasks[0].task.Run();
	EXPECT_EQ(0, NotificationCount());

	tasks = TakePendingTasks();
	EXPECT_EQ(0u, tasks.size());

	// We are no longer able to schedule tasks.
	notifier.Schedule();
	tasks = TakePendingTasks();
	ASSERT_EQ(0u, tasks.size());

	// Verify after the scheduled time happens there is still no task.
	notifier.SetNow(notifier.Now() + delay);
	tasks = TakePendingTasks();
	ASSERT_EQ(0u, tasks.size());
	}

	TEST_F(DelayedUniqueNotifierTest, ShutdownPreventsSchedule) {
	base::TimeDelta delay = base::TimeDelta::FromInternalValue(20);
	TestNotifier notifier(
	task_runner_.get(),
	base::Bind(&DelayedUniqueNotifierTest::Notify, base::Unretained(this)),
	delay);

	EXPECT_EQ(0, NotificationCount());

	// Schedule for \|delay\| seconds from now.
	base::TimeTicks schedule_time =
	notifier.Now() + base::TimeDelta::FromInternalValue(10);
	notifier.SetNow(schedule_time);

	// Shutdown the notifier.
	notifier.Shutdown();

	// Scheduling a task no longer does anything.
	notifier.Schedule();
	std::deque<base::TestPendingTask> tasks = TakePendingTasks();
	ASSERT_EQ(0u, tasks.size());

	// Verify after the scheduled time happens there is still no task.
	notifier.SetNow(notifier.Now() + delay);
	tasks = TakePendingTasks();
	ASSERT_EQ(0u, tasks.size());
	}

	} // namespace
	} // namespace cc