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cobalt / cobalt / 0d1858f87ad39776d3bccd0ec75731daf232e0d3 / . / src / base / task / task_scheduler / task_tracker_unittest.cc
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// Copyright 2016 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/task/task_scheduler/task_tracker.h"
#include <memory>
#include <utility>
#include <vector>
#include "base/bind.h"
#include "base/bind_helpers.h"
#include "base/callback.h"
#include "base/logging.h"
#include "base/macros.h"
#include "base/memory/ptr_util.h"
#include "base/memory/ref_counted.h"
#include "base/metrics/histogram_base.h"
#include "base/metrics/histogram_samples.h"
#include "base/metrics/statistics_recorder.h"
#include "base/sequence_token.h"
#include "base/sequenced_task_runner.h"
#include "base/single_thread_task_runner.h"
#include "base/synchronization/atomic_flag.h"
#include "base/synchronization/waitable_event.h"
#include "base/task/task_scheduler/scheduler_lock.h"
#include "base/task/task_scheduler/task.h"
#include "base/task/task_scheduler/test_utils.h"
#include "base/task/task_traits.h"
#include "base/test/gtest_util.h"
#include "base/test/metrics/histogram_tester.h"
#include "base/test/test_simple_task_runner.h"
#include "base/test/test_timeouts.h"
#include "base/threading/platform_thread.h"
#include "base/threading/sequenced_task_runner_handle.h"
#include "base/threading/simple_thread.h"
#include "base/threading/thread_restrictions.h"
#include "base/threading/thread_task_runner_handle.h"
#include "starboard/types.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace base {
namespace internal {
namespace {
constexpr size_t kLoadTestNumIterations = 75;
class MockCanScheduleSequenceObserver : public CanScheduleSequenceObserver {
public:
void OnCanScheduleSequence(scoped_refptr<Sequence> sequence) override {
MockOnCanScheduleSequence(sequence.get());
}
MOCK_METHOD1(MockOnCanScheduleSequence, void(Sequence*));
};
// Invokes a closure asynchronously.
class CallbackThread : public SimpleThread {
public:
explicit CallbackThread(const Closure& closure)
: SimpleThread("CallbackThread"), closure_(closure) {}
// Returns true once the callback returns.
bool has_returned() { return has_returned_.IsSet(); }
private:
void Run() override {
closure_.Run();
has_returned_.Set();
}
const Closure closure_;
AtomicFlag has_returned_;
DISALLOW_COPY_AND_ASSIGN(CallbackThread);
};
class ThreadPostingAndRunningTask : public SimpleThread {
public:
enum class Action {
WILL_POST,
RUN,
WILL_POST_AND_RUN,
};
ThreadPostingAndRunningTask(TaskTracker* tracker,
Task* task,
const TaskTraits& traits,
Action action,
bool expect_post_succeeds)
: SimpleThread("ThreadPostingAndRunningTask"),
tracker_(tracker),
owned_task_(FROM_HERE, OnceClosure(), TimeDelta()),
task_(task),
traits_(traits),
action_(action),
expect_post_succeeds_(expect_post_succeeds) {
EXPECT_TRUE(task_);
// Ownership of the Task is required to run it.
EXPECT_NE(Action::RUN, action_);
EXPECT_NE(Action::WILL_POST_AND_RUN, action_);
}
ThreadPostingAndRunningTask(TaskTracker* tracker,
Task task,
const TaskTraits& traits,
Action action,
bool expect_post_succeeds)
: SimpleThread("ThreadPostingAndRunningTask"),
tracker_(tracker),
owned_task_(std::move(task)),
task_(&owned_task_),
traits_(traits),
action_(action),
expect_post_succeeds_(expect_post_succeeds) {
EXPECT_TRUE(owned_task_.task);
}
private:
void Run() override {
bool post_succeeded = true;
if (action_ == Action::WILL_POST || action_ == Action::WILL_POST_AND_RUN) {
post_succeeded =
tracker_->WillPostTask(task_, traits_.shutdown_behavior());
EXPECT_EQ(expect_post_succeeds_, post_succeeded);
}
if (post_succeeded &&
(action_ == Action::RUN || action_ == Action::WILL_POST_AND_RUN)) {
EXPECT_TRUE(owned_task_.task);
testing::StrictMock<MockCanScheduleSequenceObserver>
never_notified_observer;
auto sequence = tracker_->WillScheduleSequence(
test::CreateSequenceWithTask(std::move(owned_task_), traits_),
&never_notified_observer);
ASSERT_TRUE(sequence);
// Expect RunAndPopNextTask to return nullptr since |sequence| is empty
// after popping a task from it.
EXPECT_FALSE(tracker_->RunAndPopNextTask(std::move(sequence),
&never_notified_observer));
}
}
TaskTracker* const tracker_;
Task owned_task_;
Task* task_;
const TaskTraits traits_;
const Action action_;
const bool expect_post_succeeds_;
DISALLOW_COPY_AND_ASSIGN(ThreadPostingAndRunningTask);
};
class ScopedSetSingletonAllowed {
public:
ScopedSetSingletonAllowed(bool singleton_allowed)
: previous_value_(
ThreadRestrictions::SetSingletonAllowed(singleton_allowed)) {}
~ScopedSetSingletonAllowed() {
ThreadRestrictions::SetSingletonAllowed(previous_value_);
}
private:
const bool previous_value_;
};
class TaskSchedulerTaskTrackerTest
: public testing::TestWithParam<TaskShutdownBehavior> {
protected:
TaskSchedulerTaskTrackerTest()
: recorder_for_testing_(StatisticsRecorder::CreateTemporaryForTesting()) {
}
// Creates a task.
Task CreateTask() {
return Task(
FROM_HERE,
Bind(&TaskSchedulerTaskTrackerTest::RunTaskCallback, Unretained(this)),
TimeDelta());
}
void DispatchAndRunTaskWithTracker(Task task, const TaskTraits& traits) {
auto sequence = tracker_.WillScheduleSequence(
test::CreateSequenceWithTask(std::move(task), traits),
&never_notified_observer_);
ASSERT_TRUE(sequence);
tracker_.RunAndPopNextTask(std::move(sequence), &never_notified_observer_);
}
// Calls tracker_->Shutdown() on a new thread. When this returns, Shutdown()
// method has been entered on the new thread, but it hasn't necessarily
// returned.
void CallShutdownAsync() {
ASSERT_FALSE(thread_calling_shutdown_);
thread_calling_shutdown_.reset(new CallbackThread(
Bind(&TaskTracker::Shutdown, Unretained(&tracker_))));
thread_calling_shutdown_->Start();
while (!tracker_.HasShutdownStarted())
PlatformThread::YieldCurrentThread();
}
void WaitForAsyncIsShutdownComplete() {
ASSERT_TRUE(thread_calling_shutdown_);
thread_calling_shutdown_->Join();
EXPECT_TRUE(thread_calling_shutdown_->has_returned());
EXPECT_TRUE(tracker_.IsShutdownComplete());
}
void VerifyAsyncShutdownInProgress() {
ASSERT_TRUE(thread_calling_shutdown_);
EXPECT_FALSE(thread_calling_shutdown_->has_returned());
EXPECT_TRUE(tracker_.HasShutdownStarted());
EXPECT_FALSE(tracker_.IsShutdownComplete());
}
// Calls tracker_->FlushForTesting() on a new thread.
void CallFlushFromAnotherThread() {
ASSERT_FALSE(thread_calling_flush_);
thread_calling_flush_.reset(new CallbackThread(
Bind(&TaskTracker::FlushForTesting, Unretained(&tracker_))));
thread_calling_flush_->Start();
}
void WaitForAsyncFlushReturned() {
ASSERT_TRUE(thread_calling_flush_);
thread_calling_flush_->Join();
EXPECT_TRUE(thread_calling_flush_->has_returned());
}
void VerifyAsyncFlushInProgress() {
ASSERT_TRUE(thread_calling_flush_);
EXPECT_FALSE(thread_calling_flush_->has_returned());
}
size_t NumTasksExecuted() {
AutoSchedulerLock auto_lock(lock_);
return num_tasks_executed_;
}
std::unique_ptr<StatisticsRecorder> recorder_for_testing_;
TaskTracker tracker_ = {"Test"};
testing::StrictMock<MockCanScheduleSequenceObserver> never_notified_observer_;
private:
void RunTaskCallback() {
AutoSchedulerLock auto_lock(lock_);
++num_tasks_executed_;
}
std::unique_ptr<CallbackThread> thread_calling_shutdown_;
std::unique_ptr<CallbackThread> thread_calling_flush_;
// Synchronizes accesses to |num_tasks_executed_|.
SchedulerLock lock_;
size_t num_tasks_executed_ = 0;
DISALLOW_COPY_AND_ASSIGN(TaskSchedulerTaskTrackerTest);
};
#define WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED() \
do { \
SCOPED_TRACE(""); \
WaitForAsyncIsShutdownComplete(); \
} while (false)
#define VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS() \
do { \
SCOPED_TRACE(""); \
VerifyAsyncShutdownInProgress(); \
} while (false)
#define WAIT_FOR_ASYNC_FLUSH_RETURNED() \
do { \
SCOPED_TRACE(""); \
WaitForAsyncFlushReturned(); \
} while (false)
#define VERIFY_ASYNC_FLUSH_IN_PROGRESS() \
do { \
SCOPED_TRACE(""); \
VerifyAsyncFlushInProgress(); \
} while (false)
} // namespace
TEST_P(TaskSchedulerTaskTrackerTest, WillPostAndRunBeforeShutdown) {
Task task(CreateTask());
// Inform |task_tracker_| that |task| will be posted.
EXPECT_TRUE(tracker_.WillPostTask(&task, GetParam()));
// Run the task.
EXPECT_EQ(0U, NumTasksExecuted());
DispatchAndRunTaskWithTracker(std::move(task), GetParam());
EXPECT_EQ(1U, NumTasksExecuted());
// Shutdown() shouldn't block.
tracker_.Shutdown();
}
TEST_P(TaskSchedulerTaskTrackerTest, WillPostAndRunLongTaskBeforeShutdown) {
// Create a task that signals |task_running| and blocks until |task_barrier|
// is signaled.
WaitableEvent task_running(WaitableEvent::ResetPolicy::AUTOMATIC,
WaitableEvent::InitialState::NOT_SIGNALED);
WaitableEvent task_barrier(WaitableEvent::ResetPolicy::AUTOMATIC,
WaitableEvent::InitialState::NOT_SIGNALED);
Task blocked_task(
FROM_HERE,
Bind(
[](WaitableEvent* task_running, WaitableEvent* task_barrier) {
task_running->Signal();
task_barrier->Wait();
},
Unretained(&task_running), Unretained(&task_barrier)),
TimeDelta());
// Inform |task_tracker_| that |blocked_task| will be posted.
EXPECT_TRUE(tracker_.WillPostTask(&blocked_task, GetParam()));
// Create a thread to run the task. Wait until the task starts running.
ThreadPostingAndRunningTask thread_running_task(
&tracker_, std::move(blocked_task),
TaskTraits(WithBaseSyncPrimitives(), GetParam()),
ThreadPostingAndRunningTask::Action::RUN, false);
thread_running_task.Start();
task_running.Wait();
// Initiate shutdown after the task has started to run.
CallShutdownAsync();
if (GetParam() == TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN) {
// Shutdown should complete even with a CONTINUE_ON_SHUTDOWN in progress.
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
} else {
// Shutdown should block with any non CONTINUE_ON_SHUTDOWN task in progress.
VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS();
}
// Unblock the task.
task_barrier.Signal();
thread_running_task.Join();
// Shutdown should now complete for a non CONTINUE_ON_SHUTDOWN task.
if (GetParam() != TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN)
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
}
TEST_P(TaskSchedulerTaskTrackerTest, WillPostBeforeShutdownRunDuringShutdown) {
// Inform |task_tracker_| that a task will be posted.
Task task(CreateTask());
EXPECT_TRUE(tracker_.WillPostTask(&task, GetParam()));
// Inform |task_tracker_| that a BLOCK_SHUTDOWN task will be posted just to
// block shutdown.
Task block_shutdown_task(CreateTask());
EXPECT_TRUE(tracker_.WillPostTask(&block_shutdown_task,
TaskShutdownBehavior::BLOCK_SHUTDOWN));
// Call Shutdown() asynchronously.
CallShutdownAsync();
VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS();
// Try to run |task|. It should only run it it's BLOCK_SHUTDOWN. Otherwise it
// should be discarded.
EXPECT_EQ(0U, NumTasksExecuted());
const bool should_run = GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN;
DispatchAndRunTaskWithTracker(std::move(task), GetParam());
EXPECT_EQ(should_run ? 1U : 0U, NumTasksExecuted());
VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS();
// Unblock shutdown by running the remaining BLOCK_SHUTDOWN task.
DispatchAndRunTaskWithTracker(std::move(block_shutdown_task),
TaskShutdownBehavior::BLOCK_SHUTDOWN);
EXPECT_EQ(should_run ? 2U : 1U, NumTasksExecuted());
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
}
TEST_P(TaskSchedulerTaskTrackerTest, WillPostBeforeShutdownRunAfterShutdown) {
// Inform |task_tracker_| that a task will be posted.
Task task(CreateTask());
EXPECT_TRUE(tracker_.WillPostTask(&task, GetParam()));
// Call Shutdown() asynchronously.
CallShutdownAsync();
EXPECT_EQ(0U, NumTasksExecuted());
if (GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN) {
VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS();
// Run the task to unblock shutdown.
DispatchAndRunTaskWithTracker(std::move(task), GetParam());
EXPECT_EQ(1U, NumTasksExecuted());
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
// It is not possible to test running a BLOCK_SHUTDOWN task posted before
// shutdown after shutdown because Shutdown() won't return if there are
// pending BLOCK_SHUTDOWN tasks.
} else {
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
// The task shouldn't be allowed to run after shutdown.
DispatchAndRunTaskWithTracker(std::move(task), GetParam());
EXPECT_EQ(0U, NumTasksExecuted());
}
}
TEST_P(TaskSchedulerTaskTrackerTest, WillPostAndRunDuringShutdown) {
// Inform |task_tracker_| that a BLOCK_SHUTDOWN task will be posted just to
// block shutdown.
Task block_shutdown_task(CreateTask());
EXPECT_TRUE(tracker_.WillPostTask(&block_shutdown_task,
TaskShutdownBehavior::BLOCK_SHUTDOWN));
// Call Shutdown() asynchronously.
CallShutdownAsync();
VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS();
if (GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN) {
// Inform |task_tracker_| that a BLOCK_SHUTDOWN task will be posted.
Task task(CreateTask());
EXPECT_TRUE(tracker_.WillPostTask(&task, GetParam()));
// Run the BLOCK_SHUTDOWN task.
EXPECT_EQ(0U, NumTasksExecuted());
DispatchAndRunTaskWithTracker(std::move(task), GetParam());
EXPECT_EQ(1U, NumTasksExecuted());
} else {
// It shouldn't be allowed to post a non BLOCK_SHUTDOWN task.
Task task(CreateTask());
EXPECT_FALSE(tracker_.WillPostTask(&task, GetParam()));
// Don't try to run the task, because it wasn't allowed to be posted.
}
// Unblock shutdown by running |block_shutdown_task|.
VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS();
DispatchAndRunTaskWithTracker(std::move(block_shutdown_task),
TaskShutdownBehavior::BLOCK_SHUTDOWN);
EXPECT_EQ(GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN ? 2U : 1U,
NumTasksExecuted());
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
}
TEST_P(TaskSchedulerTaskTrackerTest, WillPostAfterShutdown) {
tracker_.Shutdown();
Task task(CreateTask());
// |task_tracker_| shouldn't allow a task to be posted after shutdown.
EXPECT_FALSE(tracker_.WillPostTask(&task, GetParam()));
}
// Verify that BLOCK_SHUTDOWN and SKIP_ON_SHUTDOWN tasks can
// AssertSingletonAllowed() but CONTINUE_ON_SHUTDOWN tasks can't.
TEST_P(TaskSchedulerTaskTrackerTest, SingletonAllowed) {
const bool can_use_singletons =
(GetParam() != TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN);
Task task(FROM_HERE, BindOnce(&ThreadRestrictions::AssertSingletonAllowed),
TimeDelta());
EXPECT_TRUE(tracker_.WillPostTask(&task, GetParam()));
// Set the singleton allowed bit to the opposite of what it is expected to be
// when |tracker| runs |task| to verify that |tracker| actually sets the
// correct value.
ScopedSetSingletonAllowed scoped_singleton_allowed(!can_use_singletons);
// Running the task should fail iff the task isn't allowed to use singletons.
if (can_use_singletons) {
DispatchAndRunTaskWithTracker(std::move(task), GetParam());
} else {
EXPECT_DCHECK_DEATH(
{ DispatchAndRunTaskWithTracker(std::move(task), GetParam()); });
}
}
// Verify that AssertIOAllowed() succeeds only for a MayBlock() task.
TEST_P(TaskSchedulerTaskTrackerTest, IOAllowed) {
// Unset the IO allowed bit. Expect TaskTracker to set it before running a
// task with the MayBlock() trait.
ThreadRestrictions::SetIOAllowed(false);
Task task_with_may_block(FROM_HERE, Bind([]() {
// Shouldn't fail.
AssertBlockingAllowed();
}),
TimeDelta());
TaskTraits traits_with_may_block = TaskTraits(MayBlock(), GetParam());
EXPECT_TRUE(tracker_.WillPostTask(&task_with_may_block,
traits_with_may_block.shutdown_behavior()));
DispatchAndRunTaskWithTracker(std::move(task_with_may_block),
traits_with_may_block);
// Set the IO allowed bit. Expect TaskTracker to unset it before running a
// task without the MayBlock() trait.
ThreadRestrictions::SetIOAllowed(true);
Task task_without_may_block(
FROM_HERE,
Bind([]() { EXPECT_DCHECK_DEATH({ AssertBlockingAllowed(); }); }),
TimeDelta());
TaskTraits traits_without_may_block = TaskTraits(GetParam());
EXPECT_TRUE(tracker_.WillPostTask(
&task_without_may_block, traits_without_may_block.shutdown_behavior()));
DispatchAndRunTaskWithTracker(std::move(task_without_may_block),
traits_without_may_block);
}
static void RunTaskRunnerHandleVerificationTask(TaskTracker* tracker,
Task verify_task,
TaskTraits traits) {
// Pretend |verify_task| is posted to respect TaskTracker's contract.
EXPECT_TRUE(tracker->WillPostTask(&verify_task, traits.shutdown_behavior()));
// Confirm that the test conditions are right (no TaskRunnerHandles set
// already).
EXPECT_FALSE(ThreadTaskRunnerHandle::IsSet());
EXPECT_FALSE(SequencedTaskRunnerHandle::IsSet());
testing::StrictMock<MockCanScheduleSequenceObserver> never_notified_observer;
auto sequence = tracker->WillScheduleSequence(
test::CreateSequenceWithTask(std::move(verify_task), traits),
&never_notified_observer);
ASSERT_TRUE(sequence);
tracker->RunAndPopNextTask(std::move(sequence), &never_notified_observer);
// TaskRunnerHandle state is reset outside of task's scope.
EXPECT_FALSE(ThreadTaskRunnerHandle::IsSet());
EXPECT_FALSE(SequencedTaskRunnerHandle::IsSet());
}
static void VerifyNoTaskRunnerHandle() {
EXPECT_FALSE(ThreadTaskRunnerHandle::IsSet());
EXPECT_FALSE(SequencedTaskRunnerHandle::IsSet());
}
TEST_P(TaskSchedulerTaskTrackerTest, TaskRunnerHandleIsNotSetOnParallel) {
// Create a task that will verify that TaskRunnerHandles are not set in its
// scope per no TaskRunner ref being set to it.
Task verify_task(FROM_HERE, BindOnce(&VerifyNoTaskRunnerHandle), TimeDelta());
RunTaskRunnerHandleVerificationTask(&tracker_, std::move(verify_task),
TaskTraits(GetParam()));
}
static void VerifySequencedTaskRunnerHandle(
const SequencedTaskRunner* expected_task_runner) {
EXPECT_FALSE(ThreadTaskRunnerHandle::IsSet());
EXPECT_TRUE(SequencedTaskRunnerHandle::IsSet());
EXPECT_EQ(expected_task_runner, SequencedTaskRunnerHandle::Get());
}
TEST_P(TaskSchedulerTaskTrackerTest,
SequencedTaskRunnerHandleIsSetOnSequenced) {
scoped_refptr<SequencedTaskRunner> test_task_runner(new TestSimpleTaskRunner);
// Create a task that will verify that SequencedTaskRunnerHandle is properly
// set to |test_task_runner| in its scope per |sequenced_task_runner_ref|
// being set to it.
Task verify_task(FROM_HERE,
BindOnce(&VerifySequencedTaskRunnerHandle,
Unretained(test_task_runner.get())),
TimeDelta());
verify_task.sequenced_task_runner_ref = test_task_runner;
RunTaskRunnerHandleVerificationTask(&tracker_, std::move(verify_task),
TaskTraits(GetParam()));
}
static void VerifyThreadTaskRunnerHandle(
const SingleThreadTaskRunner* expected_task_runner) {
EXPECT_TRUE(ThreadTaskRunnerHandle::IsSet());
// SequencedTaskRunnerHandle inherits ThreadTaskRunnerHandle for thread.
EXPECT_TRUE(SequencedTaskRunnerHandle::IsSet());
EXPECT_EQ(expected_task_runner, ThreadTaskRunnerHandle::Get());
}
TEST_P(TaskSchedulerTaskTrackerTest,
ThreadTaskRunnerHandleIsSetOnSingleThreaded) {
scoped_refptr<SingleThreadTaskRunner> test_task_runner(
new TestSimpleTaskRunner);
// Create a task that will verify that ThreadTaskRunnerHandle is properly set
// to |test_task_runner| in its scope per |single_thread_task_runner_ref|
// being set on it.
Task verify_task(FROM_HERE,
BindOnce(&VerifyThreadTaskRunnerHandle,
Unretained(test_task_runner.get())),
TimeDelta());
verify_task.single_thread_task_runner_ref = test_task_runner;
RunTaskRunnerHandleVerificationTask(&tracker_, std::move(verify_task),
TaskTraits(GetParam()));
}
TEST_P(TaskSchedulerTaskTrackerTest, FlushPendingDelayedTask) {
Task delayed_task(FROM_HERE, DoNothing(), TimeDelta::FromDays(1));
tracker_.WillPostTask(&delayed_task, GetParam());
// FlushForTesting() should return even if the delayed task didn't run.
tracker_.FlushForTesting();
}
TEST_P(TaskSchedulerTaskTrackerTest, FlushAsyncForTestingPendingDelayedTask) {
Task delayed_task(FROM_HERE, DoNothing(), TimeDelta::FromDays(1));
tracker_.WillPostTask(&delayed_task, GetParam());
// FlushAsyncForTesting() should callback even if the delayed task didn't run.
bool called_back = false;
tracker_.FlushAsyncForTesting(
BindOnce([](bool* called_back) { *called_back = true; },
Unretained(&called_back)));
EXPECT_TRUE(called_back);
}
TEST_P(TaskSchedulerTaskTrackerTest, FlushPendingUndelayedTask) {
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushForTesting() shouldn't return before the undelayed task runs.
CallFlushFromAnotherThread();
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
VERIFY_ASYNC_FLUSH_IN_PROGRESS();
// FlushForTesting() should return after the undelayed task runs.
DispatchAndRunTaskWithTracker(std::move(undelayed_task), GetParam());
WAIT_FOR_ASYNC_FLUSH_RETURNED();
}
TEST_P(TaskSchedulerTaskTrackerTest, FlushAsyncForTestingPendingUndelayedTask) {
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushAsyncForTesting() shouldn't callback before the undelayed task runs.
WaitableEvent event;
tracker_.FlushAsyncForTesting(
BindOnce(&WaitableEvent::Signal, Unretained(&event)));
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
EXPECT_FALSE(event.IsSignaled());
// FlushAsyncForTesting() should callback after the undelayed task runs.
DispatchAndRunTaskWithTracker(std::move(undelayed_task), GetParam());
event.Wait();
}
TEST_P(TaskSchedulerTaskTrackerTest, PostTaskDuringFlush) {
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushForTesting() shouldn't return before the undelayed task runs.
CallFlushFromAnotherThread();
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
VERIFY_ASYNC_FLUSH_IN_PROGRESS();
// Simulate posting another undelayed task.
Task other_undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&other_undelayed_task, GetParam());
// Run the first undelayed task.
DispatchAndRunTaskWithTracker(std::move(undelayed_task), GetParam());
// FlushForTesting() shouldn't return before the second undelayed task runs.
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
VERIFY_ASYNC_FLUSH_IN_PROGRESS();
// FlushForTesting() should return after the second undelayed task runs.
DispatchAndRunTaskWithTracker(std::move(other_undelayed_task), GetParam());
WAIT_FOR_ASYNC_FLUSH_RETURNED();
}
TEST_P(TaskSchedulerTaskTrackerTest, PostTaskDuringFlushAsyncForTesting) {
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushAsyncForTesting() shouldn't callback before the undelayed task runs.
WaitableEvent event;
tracker_.FlushAsyncForTesting(
BindOnce(&WaitableEvent::Signal, Unretained(&event)));
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
EXPECT_FALSE(event.IsSignaled());
// Simulate posting another undelayed task.
Task other_undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&other_undelayed_task, GetParam());
// Run the first undelayed task.
DispatchAndRunTaskWithTracker(std::move(undelayed_task), GetParam());
// FlushAsyncForTesting() shouldn't callback before the second undelayed task
// runs.
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
EXPECT_FALSE(event.IsSignaled());
// FlushAsyncForTesting() should callback after the second undelayed task
// runs.
DispatchAndRunTaskWithTracker(std::move(other_undelayed_task), GetParam());
event.Wait();
}
TEST_P(TaskSchedulerTaskTrackerTest, RunDelayedTaskDuringFlush) {
// Simulate posting a delayed and an undelayed task.
Task delayed_task(FROM_HERE, DoNothing(), TimeDelta::FromDays(1));
tracker_.WillPostTask(&delayed_task, GetParam());
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushForTesting() shouldn't return before the undelayed task runs.
CallFlushFromAnotherThread();
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
VERIFY_ASYNC_FLUSH_IN_PROGRESS();
// Run the delayed task.
DispatchAndRunTaskWithTracker(std::move(delayed_task), GetParam());
// FlushForTesting() shouldn't return since there is still a pending undelayed
// task.
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
VERIFY_ASYNC_FLUSH_IN_PROGRESS();
// Run the undelayed task.
DispatchAndRunTaskWithTracker(std::move(undelayed_task), GetParam());
// FlushForTesting() should now return.
WAIT_FOR_ASYNC_FLUSH_RETURNED();
}
TEST_P(TaskSchedulerTaskTrackerTest, RunDelayedTaskDuringFlushAsyncForTesting) {
// Simulate posting a delayed and an undelayed task.
Task delayed_task(FROM_HERE, DoNothing(), TimeDelta::FromDays(1));
tracker_.WillPostTask(&delayed_task, GetParam());
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushAsyncForTesting() shouldn't callback before the undelayed task runs.
WaitableEvent event;
tracker_.FlushAsyncForTesting(
BindOnce(&WaitableEvent::Signal, Unretained(&event)));
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
EXPECT_FALSE(event.IsSignaled());
// Run the delayed task.
DispatchAndRunTaskWithTracker(std::move(delayed_task), GetParam());
// FlushAsyncForTesting() shouldn't callback since there is still a pending
// undelayed task.
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
EXPECT_FALSE(event.IsSignaled());
// Run the undelayed task.
DispatchAndRunTaskWithTracker(std::move(undelayed_task), GetParam());
// FlushAsyncForTesting() should now callback.
event.Wait();
}
TEST_P(TaskSchedulerTaskTrackerTest, FlushAfterShutdown) {
if (GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN)
return;
// Simulate posting a task.
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// Shutdown() should return immediately since there are no pending
// BLOCK_SHUTDOWN tasks.
tracker_.Shutdown();
// FlushForTesting() should return immediately after shutdown, even if an
// undelayed task hasn't run.
tracker_.FlushForTesting();
}
TEST_P(TaskSchedulerTaskTrackerTest, FlushAfterShutdownAsync) {
if (GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN)
return;
// Simulate posting a task.
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// Shutdown() should return immediately since there are no pending
// BLOCK_SHUTDOWN tasks.
tracker_.Shutdown();
// FlushForTesting() should callback immediately after shutdown, even if an
// undelayed task hasn't run.
bool called_back = false;
tracker_.FlushAsyncForTesting(
BindOnce([](bool* called_back) { *called_back = true; },
Unretained(&called_back)));
EXPECT_TRUE(called_back);
}
TEST_P(TaskSchedulerTaskTrackerTest, ShutdownDuringFlush) {
if (GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN)
return;
// Simulate posting a task.
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushForTesting() shouldn't return before the undelayed task runs or
// shutdown completes.
CallFlushFromAnotherThread();
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
VERIFY_ASYNC_FLUSH_IN_PROGRESS();
// Shutdown() should return immediately since there are no pending
// BLOCK_SHUTDOWN tasks.
tracker_.Shutdown();
// FlushForTesting() should now return, even if an undelayed task hasn't run.
WAIT_FOR_ASYNC_FLUSH_RETURNED();
}
TEST_P(TaskSchedulerTaskTrackerTest, ShutdownDuringFlushAsyncForTesting) {
if (GetParam() == TaskShutdownBehavior::BLOCK_SHUTDOWN)
return;
// Simulate posting a task.
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushAsyncForTesting() shouldn't callback before the undelayed task runs or
// shutdown completes.
WaitableEvent event;
tracker_.FlushAsyncForTesting(
BindOnce(&WaitableEvent::Signal, Unretained(&event)));
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
EXPECT_FALSE(event.IsSignaled());
// Shutdown() should return immediately since there are no pending
// BLOCK_SHUTDOWN tasks.
tracker_.Shutdown();
// FlushAsyncForTesting() should now callback, even if an undelayed task
// hasn't run.
event.Wait();
}
TEST_P(TaskSchedulerTaskTrackerTest, DoublePendingFlushAsyncForTestingFails) {
Task undelayed_task(FROM_HERE, DoNothing(), TimeDelta());
tracker_.WillPostTask(&undelayed_task, GetParam());
// FlushAsyncForTesting() shouldn't callback before the undelayed task runs.
bool called_back = false;
tracker_.FlushAsyncForTesting(
BindOnce([](bool* called_back) { *called_back = true; },
Unretained(&called_back)));
EXPECT_FALSE(called_back);
EXPECT_DCHECK_DEATH({ tracker_.FlushAsyncForTesting(BindOnce([]() {})); });
}
// Verify that a delayed task does not block shutdown, regardless of its
// shutdown behavior.
TEST_P(TaskSchedulerTaskTrackerTest, DelayedTasksDoNotBlockShutdown) {
// Simulate posting a delayed task.
Task delayed_task(FROM_HERE, DoNothing(), TimeDelta::FromDays(1));
EXPECT_TRUE(tracker_.WillPostTask(&delayed_task, GetParam()));
// Since the delayed task doesn't block shutdown, a call to Shutdown() should
// not hang.
tracker_.Shutdown();
}
INSTANTIATE_TEST_CASE_P(
ContinueOnShutdown,
TaskSchedulerTaskTrackerTest,
::testing::Values(TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN));
INSTANTIATE_TEST_CASE_P(
SkipOnShutdown,
TaskSchedulerTaskTrackerTest,
::testing::Values(TaskShutdownBehavior::SKIP_ON_SHUTDOWN));
INSTANTIATE_TEST_CASE_P(
BlockShutdown,
TaskSchedulerTaskTrackerTest,
::testing::Values(TaskShutdownBehavior::BLOCK_SHUTDOWN));
namespace {
void ExpectSequenceToken(SequenceToken sequence_token) {
EXPECT_EQ(sequence_token, SequenceToken::GetForCurrentThread());
}
} // namespace
// Verify that SequenceToken::GetForCurrentThread() returns the Sequence's token
// when a Task runs.
TEST_F(TaskSchedulerTaskTrackerTest, CurrentSequenceToken) {
scoped_refptr<Sequence> sequence = MakeRefCounted<Sequence>(TaskTraits());
const SequenceToken sequence_token = sequence->token();
Task task(FROM_HERE, Bind(&ExpectSequenceToken, sequence_token), TimeDelta());
tracker_.WillPostTask(&task, sequence->traits().shutdown_behavior());
sequence->PushTask(std::move(task));
EXPECT_FALSE(SequenceToken::GetForCurrentThread().IsValid());
sequence = tracker_.WillScheduleSequence(std::move(sequence),
&never_notified_observer_);
ASSERT_TRUE(sequence);
tracker_.RunAndPopNextTask(std::move(sequence), &never_notified_observer_);
EXPECT_FALSE(SequenceToken::GetForCurrentThread().IsValid());
}
TEST_F(TaskSchedulerTaskTrackerTest, LoadWillPostAndRunBeforeShutdown) {
// Post and run tasks asynchronously.
std::vector<std::unique_ptr<ThreadPostingAndRunningTask>> threads;
for (size_t i = 0; i < kLoadTestNumIterations; ++i) {
threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, CreateTask(),
TaskTraits(TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN),
ThreadPostingAndRunningTask::Action::WILL_POST_AND_RUN, true));
threads.back()->Start();
threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, CreateTask(),
TaskTraits(TaskShutdownBehavior::SKIP_ON_SHUTDOWN),
ThreadPostingAndRunningTask::Action::WILL_POST_AND_RUN, true));
threads.back()->Start();
threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, CreateTask(),
TaskTraits(TaskShutdownBehavior::BLOCK_SHUTDOWN),
ThreadPostingAndRunningTask::Action::WILL_POST_AND_RUN, true));
threads.back()->Start();
}
for (const auto& thread : threads)
thread->Join();
// Expect all tasks to be executed.
EXPECT_EQ(kLoadTestNumIterations * 3, NumTasksExecuted());
// Should return immediately because no tasks are blocking shutdown.
tracker_.Shutdown();
}
TEST_F(TaskSchedulerTaskTrackerTest,
LoadWillPostBeforeShutdownAndRunDuringShutdown) {
// Post tasks asynchronously.
std::vector<Task> tasks_continue_on_shutdown;
std::vector<Task> tasks_skip_on_shutdown;
std::vector<Task> tasks_block_shutdown;
for (size_t i = 0; i < kLoadTestNumIterations; ++i) {
tasks_continue_on_shutdown.push_back(CreateTask());
tasks_skip_on_shutdown.push_back(CreateTask());
tasks_block_shutdown.push_back(CreateTask());
}
TaskTraits traits_continue_on_shutdown =
TaskTraits(TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN);
TaskTraits traits_skip_on_shutdown =
TaskTraits(TaskShutdownBehavior::SKIP_ON_SHUTDOWN);
TaskTraits traits_block_shutdown =
TaskTraits(TaskShutdownBehavior::BLOCK_SHUTDOWN);
std::vector<std::unique_ptr<ThreadPostingAndRunningTask>> post_threads;
for (size_t i = 0; i < kLoadTestNumIterations; ++i) {
post_threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, &tasks_continue_on_shutdown[i], traits_continue_on_shutdown,
ThreadPostingAndRunningTask::Action::WILL_POST, true));
post_threads.back()->Start();
post_threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, &tasks_skip_on_shutdown[i], traits_skip_on_shutdown,
ThreadPostingAndRunningTask::Action::WILL_POST, true));
post_threads.back()->Start();
post_threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, &tasks_block_shutdown[i], traits_block_shutdown,
ThreadPostingAndRunningTask::Action::WILL_POST, true));
post_threads.back()->Start();
}
for (const auto& thread : post_threads)
thread->Join();
// Call Shutdown() asynchronously.
CallShutdownAsync();
// Run tasks asynchronously.
std::vector<std::unique_ptr<ThreadPostingAndRunningTask>> run_threads;
for (size_t i = 0; i < kLoadTestNumIterations; ++i) {
run_threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, std::move(tasks_continue_on_shutdown[i]),
traits_continue_on_shutdown, ThreadPostingAndRunningTask::Action::RUN,
false));
run_threads.back()->Start();
run_threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, std::move(tasks_skip_on_shutdown[i]),
traits_skip_on_shutdown, ThreadPostingAndRunningTask::Action::RUN,
false));
run_threads.back()->Start();
run_threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, std::move(tasks_block_shutdown[i]), traits_block_shutdown,
ThreadPostingAndRunningTask::Action::RUN, false));
run_threads.back()->Start();
}
for (const auto& thread : run_threads)
thread->Join();
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
// Expect BLOCK_SHUTDOWN tasks to have been executed.
EXPECT_EQ(kLoadTestNumIterations, NumTasksExecuted());
}
TEST_F(TaskSchedulerTaskTrackerTest, LoadWillPostAndRunDuringShutdown) {
// Inform |task_tracker_| that a BLOCK_SHUTDOWN task will be posted just to
// block shutdown.
Task block_shutdown_task(CreateTask());
EXPECT_TRUE(tracker_.WillPostTask(&block_shutdown_task,
TaskShutdownBehavior::BLOCK_SHUTDOWN));
// Call Shutdown() asynchronously.
CallShutdownAsync();
// Post and run tasks asynchronously.
std::vector<std::unique_ptr<ThreadPostingAndRunningTask>> threads;
for (size_t i = 0; i < kLoadTestNumIterations; ++i) {
threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, CreateTask(),
TaskTraits(TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN),
ThreadPostingAndRunningTask::Action::WILL_POST_AND_RUN, false));
threads.back()->Start();
threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, CreateTask(),
TaskTraits(TaskShutdownBehavior::SKIP_ON_SHUTDOWN),
ThreadPostingAndRunningTask::Action::WILL_POST_AND_RUN, false));
threads.back()->Start();
threads.push_back(std::make_unique<ThreadPostingAndRunningTask>(
&tracker_, CreateTask(),
TaskTraits(TaskShutdownBehavior::BLOCK_SHUTDOWN),
ThreadPostingAndRunningTask::Action::WILL_POST_AND_RUN, true));
threads.back()->Start();
}
for (const auto& thread : threads)
thread->Join();
// Expect BLOCK_SHUTDOWN tasks to have been executed.
EXPECT_EQ(kLoadTestNumIterations, NumTasksExecuted());
// Shutdown() shouldn't return before |block_shutdown_task| is executed.
VERIFY_ASYNC_SHUTDOWN_IN_PROGRESS();
// Unblock shutdown by running |block_shutdown_task|.
DispatchAndRunTaskWithTracker(
std::move(block_shutdown_task),
TaskTraits(TaskShutdownBehavior::BLOCK_SHUTDOWN));
EXPECT_EQ(kLoadTestNumIterations + 1, NumTasksExecuted());
WAIT_FOR_ASYNC_SHUTDOWN_COMPLETED();
}
// Verify that RunAndPopNextTask() returns the sequence from which it ran a task
// when it can be rescheduled.
TEST_F(TaskSchedulerTaskTrackerTest,
RunAndPopNextTaskReturnsSequenceToReschedule) {
TaskTraits default_traits = {};
Task task_1(FROM_HERE, DoNothing(), TimeDelta());
EXPECT_TRUE(
tracker_.WillPostTask(&task_1, default_traits.shutdown_behavior()));
Task task_2(FROM_HERE, DoNothing(), TimeDelta());
EXPECT_TRUE(
tracker_.WillPostTask(&task_2, default_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence =
test::CreateSequenceWithTask(std::move(task_1), default_traits);
sequence->PushTask(std::move(task_2));
EXPECT_EQ(sequence, tracker_.WillScheduleSequence(sequence, nullptr));
EXPECT_EQ(sequence, tracker_.RunAndPopNextTask(sequence, nullptr));
}
namespace {
void TestWillScheduleBestEffortSequenceWithMaxBestEffortSequences(
int max_num_scheduled_best_effort_sequences,
TaskTracker& tracker) {
// Simulate posting |max_num_scheduled_best_effort_sequences| best-effort
// tasks and scheduling the associated sequences. This should succeed.
std::vector<scoped_refptr<Sequence>> scheduled_sequences;
testing::StrictMock<MockCanScheduleSequenceObserver> never_notified_observer;
TaskTraits best_effort_traits = TaskTraits(TaskPriority::BEST_EFFORT);
for (int i = 0; i < max_num_scheduled_best_effort_sequences; ++i) {
Task task(FROM_HERE, DoNothing(), TimeDelta());
EXPECT_TRUE(
tracker.WillPostTask(&task, best_effort_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence =
test::CreateSequenceWithTask(std::move(task), best_effort_traits);
EXPECT_EQ(sequence,
tracker.WillScheduleSequence(sequence, &never_notified_observer));
scheduled_sequences.push_back(std::move(sequence));
}
// Simulate posting extra best-effort tasks and scheduling the associated
// sequences. This should fail because the maximum number of best-effort
// sequences that can be scheduled concurrently is already reached.
std::vector<std::unique_ptr<bool>> extra_tasks_did_run;
std::vector<
std::unique_ptr<testing::StrictMock<MockCanScheduleSequenceObserver>>>
extra_observers;
std::vector<scoped_refptr<Sequence>> extra_sequences;
for (int i = 0; i < max_num_scheduled_best_effort_sequences; ++i) {
extra_tasks_did_run.push_back(std::make_unique<bool>());
Task extra_task(
FROM_HERE,
BindOnce([](bool* extra_task_did_run) { *extra_task_did_run = true; },
Unretained(extra_tasks_did_run.back().get())),
TimeDelta());
EXPECT_TRUE(tracker.WillPostTask(&extra_task,
best_effort_traits.shutdown_behavior()));
extra_sequences.push_back(test::CreateSequenceWithTask(
std::move(extra_task), best_effort_traits));
extra_observers.push_back(
std::make_unique<
testing::StrictMock<MockCanScheduleSequenceObserver>>());
EXPECT_EQ(nullptr,
tracker.WillScheduleSequence(extra_sequences.back(),
extra_observers.back().get()));
}
// Run the sequences scheduled at the beginning of the test. Expect an
// observer from |extra_observer| to be notified every time a task finishes to
// run.
for (int i = 0; i < max_num_scheduled_best_effort_sequences; ++i) {
EXPECT_CALL(*extra_observers[i].get(),
MockOnCanScheduleSequence(extra_sequences[i].get()));
EXPECT_FALSE(tracker.RunAndPopNextTask(scheduled_sequences[i],
&never_notified_observer));
testing::Mock::VerifyAndClear(extra_observers[i].get());
}
// Run the extra sequences.
for (int i = 0; i < max_num_scheduled_best_effort_sequences; ++i) {
EXPECT_FALSE(*extra_tasks_did_run[i]);
EXPECT_FALSE(tracker.RunAndPopNextTask(extra_sequences[i],
&never_notified_observer));
EXPECT_TRUE(*extra_tasks_did_run[i]);
}
}
} // namespace
// Verify that WillScheduleSequence() returns nullptr when it receives a
// best-effort sequence and the maximum number of best-effort sequences that can
// be scheduled concurrently is reached. Verify that an observer is notified
// when a best-effort sequence can be scheduled (i.e. when one of the previously
// scheduled best-effort sequences has run).
TEST_F(TaskSchedulerTaskTrackerTest,
WillScheduleBestEffortSequenceWithMaxBestEffortSequences) {
constexpr int kMaxNumScheduledBestEffortSequences = 2;
TaskTracker tracker("Test", kMaxNumScheduledBestEffortSequences);
TestWillScheduleBestEffortSequenceWithMaxBestEffortSequences(
kMaxNumScheduledBestEffortSequences, tracker);
}
// Verify that providing a cap for the number of BEST_EFFORT tasks to the
// constructor of TaskTracker is compatible with using an execution fence.
TEST_F(TaskSchedulerTaskTrackerTest,
WillScheduleBestEffortSequenceWithMaxBestEffortSequencesAndFence) {
constexpr int kMaxNumScheduledBestEffortSequences = 2;
TaskTracker tracker("Test", kMaxNumScheduledBestEffortSequences);
tracker.SetExecutionFenceEnabled(true);
tracker.SetExecutionFenceEnabled(false);
TestWillScheduleBestEffortSequenceWithMaxBestEffortSequences(
kMaxNumScheduledBestEffortSequences, tracker);
}
namespace {
void SetBool(bool* arg) {
ASSERT_TRUE(arg);
EXPECT_FALSE(*arg);
*arg = true;
}
} // namespace
// Verify that enabling the ScopedExecutionFence will prevent
// WillScheduleSequence() returning sequence.
TEST_F(TaskSchedulerTaskTrackerTest,
WillScheduleSequenceWithScopedExecutionFence) {
TaskTraits default_traits = {};
Task task_a(FROM_HERE, DoNothing(), TimeDelta());
EXPECT_TRUE(
tracker_.WillPostTask(&task_a, default_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence_a =
test::CreateSequenceWithTask(std::move(task_a), default_traits);
testing::StrictMock<MockCanScheduleSequenceObserver> never_notified_observer;
EXPECT_EQ(sequence_a, tracker_.WillScheduleSequence(
sequence_a, &never_notified_observer));
// Verify that WillScheduleSequence() returns nullptr for foreground sequence
// when the ScopedExecutionFence is enabled.
tracker_.SetExecutionFenceEnabled(true);
bool task_b_1_did_run = false;
Task task_b_1(FROM_HERE, BindOnce(&SetBool, Unretained(&task_b_1_did_run)),
TimeDelta());
EXPECT_TRUE(
tracker_.WillPostTask(&task_b_1, default_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence_b =
test::CreateSequenceWithTask(std::move(task_b_1), default_traits);
testing::StrictMock<MockCanScheduleSequenceObserver> observer_b_1;
EXPECT_EQ(0, tracker_.GetPreemptedSequenceCountForTesting(
TaskPriority::BEST_EFFORT));
EXPECT_FALSE(tracker_.WillScheduleSequence(sequence_b, &observer_b_1));
EXPECT_EQ(1, tracker_.GetPreemptedSequenceCountForTesting(
TaskPriority::USER_VISIBLE));
bool task_b_2_did_run = false;
Task task_b_2(FROM_HERE, BindOnce(&SetBool, Unretained(&task_b_2_did_run)),
TimeDelta());
TaskTraits best_effort_traits = TaskTraits(TaskPriority::BEST_EFFORT);
EXPECT_TRUE(
tracker_.WillPostTask(&task_b_2, best_effort_traits.shutdown_behavior()));
sequence_b->PushTask(std::move(task_b_2));
testing::StrictMock<MockCanScheduleSequenceObserver> observer_b_2;
EXPECT_EQ(nullptr, tracker_.WillScheduleSequence(sequence_b, &observer_b_2));
// The TaskPriority of the Sequence is unchanged by posting new tasks to it.
EXPECT_EQ(2, tracker_.GetPreemptedSequenceCountForTesting(
TaskPriority::USER_VISIBLE));
// Verify that WillScheduleSequence() returns nullptr for best-effort sequence
// when the ScopedExecutionFence is enabled.
bool task_c_did_run = false;
Task task_c(FROM_HERE, BindOnce(&SetBool, Unretained(&task_c_did_run)),
TimeDelta());
EXPECT_TRUE(
tracker_.WillPostTask(&task_c, best_effort_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence_c =
test::CreateSequenceWithTask(std::move(task_c), best_effort_traits);
testing::StrictMock<MockCanScheduleSequenceObserver> observer_c;
EXPECT_EQ(nullptr, tracker_.WillScheduleSequence(sequence_c, &observer_c));
EXPECT_EQ(1, tracker_.GetPreemptedSequenceCountForTesting(
TaskPriority::BEST_EFFORT));
// Verifies that the sequences preempted when the fence is on are rescheduled
// right after the fence is released.
EXPECT_CALL(observer_b_1, MockOnCanScheduleSequence(sequence_b.get()));
EXPECT_CALL(observer_b_2, MockOnCanScheduleSequence(sequence_b.get()));
EXPECT_CALL(observer_c, MockOnCanScheduleSequence(sequence_c.get()));
tracker_.SetExecutionFenceEnabled(false);
testing::Mock::VerifyAndClear(&observer_b_1);
testing::Mock::VerifyAndClear(&observer_b_2);
testing::Mock::VerifyAndClear(&observer_c);
EXPECT_EQ(0, tracker_.GetPreemptedSequenceCountForTesting(
TaskPriority::USER_VISIBLE));
EXPECT_EQ(0, tracker_.GetPreemptedSequenceCountForTesting(
TaskPriority::BEST_EFFORT));
// Runs the sequences and verifies the tasks are done.
EXPECT_FALSE(
tracker_.RunAndPopNextTask(sequence_a, &never_notified_observer));
EXPECT_FALSE(task_b_1_did_run);
EXPECT_EQ(sequence_b, tracker_.RunAndPopNextTask(sequence_b, &observer_b_1));
EXPECT_TRUE(task_b_1_did_run);
EXPECT_FALSE(task_b_2_did_run);
EXPECT_FALSE(tracker_.RunAndPopNextTask(sequence_b, &observer_b_2));
EXPECT_TRUE(task_b_2_did_run);
EXPECT_FALSE(task_c_did_run);
EXPECT_FALSE(tracker_.RunAndPopNextTask(sequence_c, &observer_c));
EXPECT_TRUE(task_c_did_run);
// Verify that WillScheduleSequence() returns the sequence when the
// ScopedExecutionFence isn't enabled.
Task task_d(FROM_HERE, DoNothing(), TimeDelta());
EXPECT_TRUE(
tracker_.WillPostTask(&task_d, default_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence_d =
test::CreateSequenceWithTask(std::move(task_d), default_traits);
EXPECT_EQ(sequence_d, tracker_.WillScheduleSequence(
sequence_d, &never_notified_observer));
}
// Verify that RunAndPopNextTask() doesn't reschedule the best-effort sequence
// it was assigned if there is a preempted best-effort sequence with an earlier
// sequence time (compared to the next task in the sequence assigned to
// RunAndPopNextTask()).
TEST_F(TaskSchedulerTaskTrackerTest,
RunNextBestEffortTaskWithEarlierPendingBestEffortTask) {
constexpr int kMaxNumScheduledBestEffortSequences = 1;
TaskTracker tracker("Test", kMaxNumScheduledBestEffortSequences);
testing::StrictMock<MockCanScheduleSequenceObserver> never_notified_observer;
TaskTraits best_effort_traits = TaskTraits(TaskPriority::BEST_EFFORT);
// Simulate posting a best-effort task and scheduling the associated sequence.
// This should succeed.
bool task_a_1_did_run = false;
Task task_a_1(FROM_HERE, BindOnce(&SetBool, Unretained(&task_a_1_did_run)),
TimeDelta());
EXPECT_TRUE(
tracker.WillPostTask(&task_a_1, best_effort_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence_a =
test::CreateSequenceWithTask(std::move(task_a_1), best_effort_traits);
EXPECT_EQ(sequence_a,
tracker.WillScheduleSequence(sequence_a, &never_notified_observer));
// Simulate posting an extra best-effort task and scheduling the associated
// sequence. This should fail because the maximum number of best-effort
// sequences that can be scheduled concurrently is already reached.
bool task_b_1_did_run = false;
Task task_b_1(FROM_HERE, BindOnce(&SetBool, Unretained(&task_b_1_did_run)),
TimeDelta());
EXPECT_TRUE(
tracker.WillPostTask(&task_b_1, best_effort_traits.shutdown_behavior()));
scoped_refptr<Sequence> sequence_b =
test::CreateSequenceWithTask(std::move(task_b_1), best_effort_traits);
testing::StrictMock<MockCanScheduleSequenceObserver> task_b_1_observer;
EXPECT_FALSE(tracker.WillScheduleSequence(sequence_b, &task_b_1_observer));
// Wait to be sure that the sequence time of |task_a_2| is after the sequenced
// time of |task_b_1|.
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
// Post an extra best-effort task in |sequence_a|.
bool task_a_2_did_run = false;
Task task_a_2(FROM_HERE, BindOnce(&SetBool, Unretained(&task_a_2_did_run)),
TimeDelta());
EXPECT_TRUE(
tracker.WillPostTask(&task_a_2, best_effort_traits.shutdown_behavior()));
sequence_a->PushTask(std::move(task_a_2));
// Run the first task in |sequence_a|. RunAndPopNextTask() should return
// nullptr since |sequence_a| can't be rescheduled immediately.
// |task_b_1_observer| should be notified that |sequence_b| can be scheduled.
testing::StrictMock<MockCanScheduleSequenceObserver> task_a_2_observer;
EXPECT_CALL(task_b_1_observer, MockOnCanScheduleSequence(sequence_b.get()));
EXPECT_FALSE(tracker.RunAndPopNextTask(sequence_a, &task_a_2_observer));
testing::Mock::VerifyAndClear(&task_b_1_observer);
EXPECT_TRUE(task_a_1_did_run);
// Run the first task in |sequence_b|. RunAndPopNextTask() should return
// nullptr since |sequence_b| is empty after popping a task from it.
// |task_a_2_observer| should be notified that |sequence_a| can be
// scheduled.
EXPECT_CALL(task_a_2_observer, MockOnCanScheduleSequence(sequence_a.get()));
EXPECT_FALSE(tracker.RunAndPopNextTask(sequence_b, &never_notified_observer));
testing::Mock::VerifyAndClear(&task_a_2_observer);
EXPECT_TRUE(task_b_1_did_run);
// Run the first task in |sequence_a|. RunAndPopNextTask() should return
// nullptr since |sequence_b| is empty after popping a task from it. No
// observer should be notified.
EXPECT_FALSE(tracker.RunAndPopNextTask(sequence_a, &never_notified_observer));
EXPECT_TRUE(task_a_2_did_run);
}
// Verify that preempted best-effort sequences are scheduled when shutdown
// starts.
TEST_F(TaskSchedulerTaskTrackerTest,
SchedulePreemptedBestEffortSequencesOnShutdown) {
constexpr int kMaxNumScheduledBestEffortSequences = 0;
TaskTracker tracker("Test", kMaxNumScheduledBestEffortSequences);
testing::StrictMock<MockCanScheduleSequenceObserver> observer;
// Simulate scheduling sequences. TaskTracker should prevent this.
std::vector<scoped_refptr<Sequence>> preempted_sequences;
for (int i = 0; i < 3; ++i) {
Task task(FROM_HERE, DoNothing(), TimeDelta());
EXPECT_TRUE(
tracker.WillPostTask(&task, TaskShutdownBehavior::BLOCK_SHUTDOWN));
scoped_refptr<Sequence> sequence = test::CreateSequenceWithTask(
std::move(task), TaskTraits(TaskPriority::BEST_EFFORT,
TaskShutdownBehavior::BLOCK_SHUTDOWN));
EXPECT_FALSE(tracker.WillScheduleSequence(sequence, &observer));
preempted_sequences.push_back(std::move(sequence));
// Wait to be sure that tasks have different |sequenced_time|.
PlatformThread::Sleep(TestTimeouts::tiny_timeout());
}
// Perform shutdown. Expect |preempted_sequences| to be scheduled in posting
// order.
{
testing::InSequence in_sequence;
for (auto& preempted_sequence : preempted_sequences) {
EXPECT_CALL(observer, MockOnCanScheduleSequence(preempted_sequence.get()))
.WillOnce(testing::Invoke([&tracker](Sequence* sequence) {
// Run the task to unblock shutdown.
tracker.RunAndPopNextTask(sequence, nullptr);
}));
}
tracker.Shutdown();
}
}
namespace {
class WaitAllowedTestThread : public SimpleThread {
public:
WaitAllowedTestThread() : SimpleThread("WaitAllowedTestThread") {}
private:
void Run() override {
std::unique_ptr<StatisticsRecorder> recorder_for_testing =
StatisticsRecorder::CreateTemporaryForTesting();
auto task_tracker = std::make_unique<TaskTracker>("Test");
// Waiting is allowed by default. Expect TaskTracker to disallow it before
// running a task without the WithBaseSyncPrimitives() trait.
internal::AssertBaseSyncPrimitivesAllowed();
Task task_without_sync_primitives(
FROM_HERE, Bind([]() {
EXPECT_DCHECK_DEATH({ internal::AssertBaseSyncPrimitivesAllowed(); });
}),
TimeDelta());
TaskTraits default_traits = {};
EXPECT_TRUE(task_tracker->WillPostTask(&task_without_sync_primitives,
default_traits.shutdown_behavior()));
testing::StrictMock<MockCanScheduleSequenceObserver>
never_notified_observer;
auto sequence_without_sync_primitives = task_tracker->WillScheduleSequence(
test::CreateSequenceWithTask(std::move(task_without_sync_primitives),
default_traits),
&never_notified_observer);
ASSERT_TRUE(sequence_without_sync_primitives);
task_tracker->RunAndPopNextTask(std::move(sequence_without_sync_primitives),
&never_notified_observer);
// Disallow waiting. Expect TaskTracker to allow it before running a task
// with the WithBaseSyncPrimitives() trait.
ThreadRestrictions::DisallowWaiting();
Task task_with_sync_primitives(
FROM_HERE, Bind([]() {
// Shouldn't fail.
internal::AssertBaseSyncPrimitivesAllowed();
}),
TimeDelta());
TaskTraits traits_with_sync_primitives =
TaskTraits(WithBaseSyncPrimitives());
EXPECT_TRUE(task_tracker->WillPostTask(
&task_with_sync_primitives,
traits_with_sync_primitives.shutdown_behavior()));
auto sequence_with_sync_primitives = task_tracker->WillScheduleSequence(
test::CreateSequenceWithTask(std::move(task_with_sync_primitives),
traits_with_sync_primitives),
&never_notified_observer);
ASSERT_TRUE(sequence_with_sync_primitives);
task_tracker->RunAndPopNextTask(std::move(sequence_with_sync_primitives),
&never_notified_observer);
ScopedAllowBaseSyncPrimitivesForTesting
allow_wait_in_task_tracker_destructor;
task_tracker.reset();
}
DISALLOW_COPY_AND_ASSIGN(WaitAllowedTestThread);
};
} // namespace
// Verify that AssertIOAllowed() succeeds only for a WithBaseSyncPrimitives()
// task.
TEST(TaskSchedulerTaskTrackerWaitAllowedTest, WaitAllowed) {
// Run the test on the separate thread since it is not possible to reset the
// "wait allowed" bit of a thread without being a friend of
// ThreadRestrictions.
testing::GTEST_FLAG(death_test_style) = "threadsafe";
WaitAllowedTestThread wait_allowed_test_thread;
wait_allowed_test_thread.Start();
wait_allowed_test_thread.Join();
}
// Verify that TaskScheduler.TaskLatency.* histograms are correctly recorded
// when a task runs.
TEST(TaskSchedulerTaskTrackerHistogramTest, TaskLatency) {
auto statistics_recorder = StatisticsRecorder::CreateTemporaryForTesting();
TaskTracker tracker("Test");
testing::StrictMock<MockCanScheduleSequenceObserver> never_notified_observer;
struct {
const TaskTraits traits;
const char* const expected_histogram;
} static CONSTEXPR kTests[] = {
{{TaskPriority::BEST_EFFORT},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"BackgroundTaskPriority"},
{{MayBlock(), TaskPriority::BEST_EFFORT},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"BackgroundTaskPriority_MayBlock"},
{{WithBaseSyncPrimitives(), TaskPriority::BEST_EFFORT},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"BackgroundTaskPriority_MayBlock"},
{{TaskPriority::USER_VISIBLE},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"UserVisibleTaskPriority"},
{{MayBlock(), TaskPriority::USER_VISIBLE},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"UserVisibleTaskPriority_MayBlock"},
{{WithBaseSyncPrimitives(), TaskPriority::USER_VISIBLE},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"UserVisibleTaskPriority_MayBlock"},
{{TaskPriority::USER_BLOCKING},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"UserBlockingTaskPriority"},
{{MayBlock(), TaskPriority::USER_BLOCKING},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"UserBlockingTaskPriority_MayBlock"},
{{WithBaseSyncPrimitives(), TaskPriority::USER_BLOCKING},
"TaskScheduler.TaskLatencyMicroseconds.Test."
"UserBlockingTaskPriority_MayBlock"}};
for (const auto& test : kTests) {
Task task(FROM_HERE, DoNothing(), TimeDelta());
ASSERT_TRUE(tracker.WillPostTask(&task, test.traits.shutdown_behavior()));
HistogramTester tester;
auto sequence = tracker.WillScheduleSequence(
test::CreateSequenceWithTask(std::move(task), test.traits),
&never_notified_observer);
ASSERT_TRUE(sequence);
tracker.RunAndPopNextTask(std::move(sequence), &never_notified_observer);
tester.ExpectTotalCount(test.expected_histogram, 1);
}
}
} // namespace internal
} // namespace base