blob: b02333ec58f3215c8f75898c67f4284ae30d5005 [file] [log] [blame]
/*
* Copyright 2019 The WebRTC Project Authors. All rights reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "api/task_queue/task_queue_test.h"
#include <memory>
#include "absl/cleanup/cleanup.h"
#include "absl/strings/string_view.h"
#include "api/task_queue/task_queue_base.h"
#include "api/units/time_delta.h"
#include "rtc_base/event.h"
#include "rtc_base/ref_counter.h"
#include "rtc_base/time_utils.h"
namespace webrtc {
namespace {
// Avoids a dependency to system_wrappers.
void SleepFor(TimeDelta duration) {
rtc::ScopedAllowBaseSyncPrimitivesForTesting allow;
rtc::Event event;
event.Wait(duration);
}
std::unique_ptr<TaskQueueBase, TaskQueueDeleter> CreateTaskQueue(
const std::unique_ptr<webrtc::TaskQueueFactory>& factory,
absl::string_view task_queue_name,
TaskQueueFactory::Priority priority = TaskQueueFactory::Priority::NORMAL) {
return factory->CreateTaskQueue(task_queue_name, priority);
}
TEST_P(TaskQueueTest, Construct) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
auto queue = CreateTaskQueue(factory, "Construct");
EXPECT_FALSE(queue->IsCurrent());
}
TEST_P(TaskQueueTest, PostAndCheckCurrent) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event event;
auto queue = CreateTaskQueue(factory, "PostAndCheckCurrent");
// We're not running a task, so `queue` shouldn't be current.
// Note that because rtc::Thread also supports the TQ interface and
// TestMainImpl::Init wraps the main test thread (bugs.webrtc.org/9714), that
// means that TaskQueueBase::Current() will still return a valid value.
EXPECT_FALSE(queue->IsCurrent());
queue->PostTask([&event, &queue] {
EXPECT_TRUE(queue->IsCurrent());
event.Set();
});
EXPECT_TRUE(event.Wait(TimeDelta::Seconds(1)));
}
TEST_P(TaskQueueTest, PostCustomTask) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event ran;
auto queue = CreateTaskQueue(factory, "PostCustomImplementation");
class CustomTask {
public:
explicit CustomTask(rtc::Event* ran) : ran_(ran) {}
void operator()() { ran_->Set(); }
private:
rtc::Event* const ran_;
} my_task(&ran);
queue->PostTask(my_task);
EXPECT_TRUE(ran.Wait(TimeDelta::Seconds(1)));
}
TEST_P(TaskQueueTest, PostDelayedZero) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event event;
auto queue = CreateTaskQueue(factory, "PostDelayedZero");
queue->PostDelayedTask([&event] { event.Set(); }, TimeDelta::Zero());
EXPECT_TRUE(event.Wait(TimeDelta::Seconds(1)));
}
TEST_P(TaskQueueTest, PostFromQueue) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event event;
auto queue = CreateTaskQueue(factory, "PostFromQueue");
queue->PostTask(
[&event, &queue] { queue->PostTask([&event] { event.Set(); }); });
EXPECT_TRUE(event.Wait(TimeDelta::Seconds(1)));
}
TEST_P(TaskQueueTest, PostDelayed) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event event;
auto queue =
CreateTaskQueue(factory, "PostDelayed", TaskQueueFactory::Priority::HIGH);
int64_t start = rtc::TimeMillis();
queue->PostDelayedTask(
[&event, &queue] {
EXPECT_TRUE(queue->IsCurrent());
event.Set();
},
TimeDelta::Millis(100));
EXPECT_TRUE(event.Wait(TimeDelta::Seconds(1)));
int64_t end = rtc::TimeMillis();
// These tests are a little relaxed due to how "powerful" our test bots can
// be. Most recently we've seen windows bots fire the callback after 94-99ms,
// which is why we have a little bit of leeway backwards as well.
EXPECT_GE(end - start, 90u);
EXPECT_NEAR(end - start, 190u, 100u); // Accept 90-290.
}
TEST_P(TaskQueueTest, PostMultipleDelayed) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
auto queue = CreateTaskQueue(factory, "PostMultipleDelayed");
std::vector<rtc::Event> events(100);
for (int i = 0; i < 100; ++i) {
rtc::Event* event = &events[i];
queue->PostDelayedTask(
[event, &queue] {
EXPECT_TRUE(queue->IsCurrent());
event->Set();
},
TimeDelta::Millis(i));
}
for (rtc::Event& e : events)
EXPECT_TRUE(e.Wait(TimeDelta::Seconds(1)));
}
TEST_P(TaskQueueTest, PostDelayedAfterDestruct) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event run;
rtc::Event deleted;
auto queue = CreateTaskQueue(factory, "PostDelayedAfterDestruct");
absl::Cleanup cleanup = [&deleted] { deleted.Set(); };
queue->PostDelayedTask([&run, cleanup = std::move(cleanup)] { run.Set(); },
TimeDelta::Millis(100));
// Destroy the queue.
queue = nullptr;
// Task might outlive the TaskQueue, but still should be deleted.
EXPECT_TRUE(deleted.Wait(TimeDelta::Seconds(1)));
EXPECT_FALSE(run.Wait(TimeDelta::Zero())); // and should not run.
}
TEST_P(TaskQueueTest, PostDelayedHighPrecisionAfterDestruct) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event run;
rtc::Event deleted;
auto queue =
CreateTaskQueue(factory, "PostDelayedHighPrecisionAfterDestruct");
absl::Cleanup cleanup = [&deleted] { deleted.Set(); };
queue->PostDelayedHighPrecisionTask(
[&run, cleanup = std::move(cleanup)] { run.Set(); },
TimeDelta::Millis(100));
// Destroy the queue.
queue = nullptr;
// Task might outlive the TaskQueue, but still should be deleted.
EXPECT_TRUE(deleted.Wait(TimeDelta::Seconds(1)));
EXPECT_FALSE(run.Wait(TimeDelta::Zero())); // and should not run.
}
TEST_P(TaskQueueTest, PostedUnexecutedClosureDestroyedOnTaskQueue) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
auto queue =
CreateTaskQueue(factory, "PostedUnexecutedClosureDestroyedOnTaskQueue");
TaskQueueBase* queue_ptr = queue.get();
queue->PostTask([] { SleepFor(TimeDelta::Millis(100)); });
// Give the task queue a chance to start executing the first lambda.
SleepFor(TimeDelta::Millis(10));
rtc::Event finished;
// Then ensure the next lambda (which is likely not executing yet) is
// destroyed in the task queue context when the queue is deleted.
auto cleanup = absl::Cleanup([queue_ptr, &finished] {
EXPECT_EQ(queue_ptr, TaskQueueBase::Current());
finished.Set();
});
queue->PostTask([cleanup = std::move(cleanup)] {});
queue = nullptr;
finished.Wait(TimeDelta::Seconds(1));
}
TEST_P(TaskQueueTest, PostedClosureDestroyedOnTaskQueue) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
auto queue = CreateTaskQueue(factory, "PostedClosureDestroyedOnTaskQueue");
TaskQueueBase* queue_ptr = queue.get();
rtc::Event finished;
auto cleanup = absl::Cleanup([queue_ptr, &finished] {
EXPECT_EQ(queue_ptr, TaskQueueBase::Current());
finished.Set();
});
// The cleanup task may or may not have had time to execute when the task
// queue is destroyed. Regardless, the task should be destroyed on the
// queue.
queue->PostTask([cleanup = std::move(cleanup)] {});
queue = nullptr;
finished.Wait(TimeDelta::Seconds(1));
}
TEST_P(TaskQueueTest, PostedExecutedClosureDestroyedOnTaskQueue) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
auto queue =
CreateTaskQueue(factory, "PostedExecutedClosureDestroyedOnTaskQueue");
TaskQueueBase* queue_ptr = queue.get();
// Ensure an executed lambda is destroyed on the task queue.
rtc::Event finished;
queue->PostTask([cleanup = absl::Cleanup([queue_ptr, &finished] {
EXPECT_EQ(queue_ptr, TaskQueueBase::Current());
finished.Set();
})] {});
finished.Wait(TimeDelta::Seconds(1));
}
TEST_P(TaskQueueTest, PostAndReuse) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
rtc::Event event;
auto post_queue = CreateTaskQueue(factory, "PostQueue");
auto reply_queue = CreateTaskQueue(factory, "ReplyQueue");
int call_count = 0;
class ReusedTask {
public:
ReusedTask(int* counter, TaskQueueBase* reply_queue, rtc::Event* event)
: counter_(*counter), reply_queue_(reply_queue), event_(*event) {
EXPECT_EQ(counter_, 0);
}
ReusedTask(ReusedTask&&) = default;
ReusedTask& operator=(ReusedTask&&) = delete;
void operator()() && {
if (++counter_ == 1) {
reply_queue_->PostTask(std::move(*this));
// At this point, the object is in the moved-from state.
} else {
EXPECT_EQ(counter_, 2);
EXPECT_TRUE(reply_queue_->IsCurrent());
event_.Set();
}
}
private:
int& counter_;
TaskQueueBase* const reply_queue_;
rtc::Event& event_;
};
ReusedTask task(&call_count, reply_queue.get(), &event);
post_queue->PostTask(std::move(task));
EXPECT_TRUE(event.Wait(TimeDelta::Seconds(1)));
}
TEST_P(TaskQueueTest, PostALot) {
// Waits until DecrementCount called `count` times. Thread safe.
class BlockingCounter {
public:
explicit BlockingCounter(int initial_count) : count_(initial_count) {}
void DecrementCount() {
if (count_.DecRef() == rtc::RefCountReleaseStatus::kDroppedLastRef) {
event_.Set();
}
}
bool Wait(TimeDelta give_up_after) { return event_.Wait(give_up_after); }
private:
webrtc_impl::RefCounter count_;
rtc::Event event_;
};
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
static constexpr int kTaskCount = 0xffff;
rtc::Event posting_done;
BlockingCounter all_destroyed(kTaskCount);
int tasks_executed = 0;
auto task_queue = CreateTaskQueue(factory, "PostALot");
task_queue->PostTask([&] {
// Post tasks from the queue to guarantee that the 1st task won't be
// executed before the last one is posted.
for (int i = 0; i < kTaskCount; ++i) {
absl::Cleanup cleanup = [&] { all_destroyed.DecrementCount(); };
task_queue->PostTask([&tasks_executed, cleanup = std::move(cleanup)] {
++tasks_executed;
});
}
posting_done.Set();
});
// Before destroying the task queue wait until all child tasks are posted.
posting_done.Wait(rtc::Event::kForever);
// Destroy the task queue.
task_queue = nullptr;
// Expect all tasks are destroyed eventually. In some task queue
// implementations that might happen on a different thread after task queue is
// destroyed.
EXPECT_TRUE(all_destroyed.Wait(TimeDelta::Minutes(1)));
EXPECT_LE(tasks_executed, kTaskCount);
}
// Test posting two tasks that have shared state not protected by a
// lock. The TaskQueue should guarantee memory read-write order and
// FIFO task execution order, so the second task should always see the
// changes that were made by the first task.
//
// If the TaskQueue doesn't properly synchronize the execution of
// tasks, there will be a data race, which is undefined behavior. The
// EXPECT calls may randomly catch this, but to make the most of this
// unit test, run it under TSan or some other tool that is able to
// directly detect data races.
TEST_P(TaskQueueTest, PostTwoWithSharedUnprotectedState) {
std::unique_ptr<webrtc::TaskQueueFactory> factory = GetParam()(nullptr);
struct SharedState {
// First task will set this value to 1 and second will assert it.
int state = 0;
} state;
auto queue = CreateTaskQueue(factory, "PostTwoWithSharedUnprotectedState");
rtc::Event done;
queue->PostTask([&state, &queue, &done] {
// Post tasks from queue to guarantee, that 1st task won't be
// executed before the second one will be posted.
queue->PostTask([&state] { state.state = 1; });
queue->PostTask([&state, &done] {
EXPECT_EQ(state.state, 1);
done.Set();
});
// Check, that state changing tasks didn't start yet.
EXPECT_EQ(state.state, 0);
});
EXPECT_TRUE(done.Wait(TimeDelta::Seconds(1)));
}
// TaskQueueTest is a set of tests for any implementation of the TaskQueueBase.
// Tests are instantiated next to the concrete implementation(s).
// https://github.com/google/googletest/blob/master/googletest/docs/advanced.md#creating-value-parameterized-abstract-tests
GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(TaskQueueTest);
} // namespace
} // namespace webrtc