/* * Copyright 2016 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 "webrtc/base/task_queue.h" #include #include #include #include "base/third_party/libevent/event.h" #include "webrtc/base/checks.h" #include "webrtc/base/logging.h" #include "webrtc/base/task_queue_posix.h" #include "webrtc/base/timeutils.h" namespace rtc { using internal::GetQueuePtrTls; using internal::AutoSetCurrentQueuePtr; namespace { static const char kQuit = 1; static const char kRunTask = 2; struct TimerEvent { explicit TimerEvent(std::unique_ptr task) : task(std::move(task)) {} ~TimerEvent() { event_del(&ev); } event ev; std::unique_ptr task; }; bool SetNonBlocking(int fd) { const int flags = fcntl(fd, F_GETFL); RTC_CHECK(flags != -1); return (flags & O_NONBLOCK) || fcntl(fd, F_SETFL, flags | O_NONBLOCK) != -1; } } // namespace struct TaskQueue::QueueContext { explicit QueueContext(TaskQueue* q) : queue(q), is_active(true) {} TaskQueue* queue; bool is_active; // Holds a list of events pending timers for cleanup when the loop exits. std::list pending_timers_; }; class TaskQueue::PostAndReplyTask : public QueuedTask { public: PostAndReplyTask(std::unique_ptr task, std::unique_ptr reply, TaskQueue* reply_queue) : task_(std::move(task)), reply_(std::move(reply)), reply_queue_(reply_queue) { reply_queue->PrepareReplyTask(this); } ~PostAndReplyTask() override { CritScope lock(&lock_); if (reply_queue_) reply_queue_->ReplyTaskDone(this); } void OnReplyQueueGone() { CritScope lock(&lock_); reply_queue_ = nullptr; } private: bool Run() override { if (!task_->Run()) task_.release(); CritScope lock(&lock_); if (reply_queue_) reply_queue_->PostTask(std::move(reply_)); return true; } CriticalSection lock_; std::unique_ptr task_; std::unique_ptr reply_; TaskQueue* reply_queue_ GUARDED_BY(lock_); }; class TaskQueue::SetTimerTask : public QueuedTask { public: SetTimerTask(std::unique_ptr task, uint32_t milliseconds) : task_(std::move(task)), milliseconds_(milliseconds), posted_(Time32()) {} private: bool Run() override { // Compensate for the time that has passed since construction // and until we got here. uint32_t post_time = Time32() - posted_; TaskQueue::Current()->PostDelayedTask( std::move(task_), post_time > milliseconds_ ? 0 : milliseconds_ - post_time); return true; } std::unique_ptr task_; const uint32_t milliseconds_; const uint32_t posted_; }; TaskQueue::TaskQueue(const char* queue_name) : event_base_(event_base_new()), wakeup_event_(new event()), thread_(&TaskQueue::ThreadMain, this, queue_name) { RTC_DCHECK(queue_name); int fds[2]; RTC_CHECK(pipe(fds) == 0); SetNonBlocking(fds[0]); SetNonBlocking(fds[1]); wakeup_pipe_out_ = fds[0]; wakeup_pipe_in_ = fds[1]; event_set(wakeup_event_.get(), wakeup_pipe_out_, EV_READ | EV_PERSIST, OnWakeup, this); event_base_set(event_base_, wakeup_event_.get()); event_add(wakeup_event_.get(), 0); thread_.Start(); } TaskQueue::~TaskQueue() { RTC_DCHECK(!IsCurrent()); struct timespec ts; char message = kQuit; while (write(wakeup_pipe_in_, &message, sizeof(message)) != sizeof(message)) { // The queue is full, so we have no choice but to wait and retry. RTC_CHECK_EQ(EAGAIN, errno); ts.tv_sec = 0; ts.tv_nsec = 1000000; nanosleep(&ts, nullptr); } thread_.Stop(); event_del(wakeup_event_.get()); close(wakeup_pipe_in_); close(wakeup_pipe_out_); wakeup_pipe_in_ = -1; wakeup_pipe_out_ = -1; { // Synchronize against any pending reply tasks that might be running on // other queues. CritScope lock(&pending_lock_); for (auto* reply : pending_replies_) reply->OnReplyQueueGone(); pending_replies_.clear(); } event_base_free(event_base_); } // static TaskQueue* TaskQueue::Current() { QueueContext* ctx = static_cast(pthread_getspecific(GetQueuePtrTls())); return ctx ? ctx->queue : nullptr; } // static bool TaskQueue::IsCurrent(const char* queue_name) { TaskQueue* current = Current(); return current && current->thread_.name().compare(queue_name) == 0; } bool TaskQueue::IsCurrent() const { return IsThreadRefEqual(thread_.GetThreadRef(), CurrentThreadRef()); } void TaskQueue::PostTask(std::unique_ptr task) { RTC_DCHECK(task.get()); // libevent isn't thread safe. This means that we can't use methods such // as event_base_once to post tasks to the worker thread from a different // thread. However, we can use it when posting from the worker thread itself. if (IsCurrent()) { if (event_base_once(event_base_, -1, EV_TIMEOUT, &TaskQueue::RunTask, task.get(), nullptr) == 0) { task.release(); } } else { QueuedTask* task_id = task.get(); // Only used for comparison. { CritScope lock(&pending_lock_); pending_.push_back(std::move(task)); } char message = kRunTask; if (write(wakeup_pipe_in_, &message, sizeof(message)) != sizeof(message)) { LOG(WARNING) << "Failed to queue task."; CritScope lock(&pending_lock_); pending_.remove_if([task_id](std::unique_ptr& t) { return t.get() == task_id; }); } } } void TaskQueue::PostDelayedTask(std::unique_ptr task, uint32_t milliseconds) { if (IsCurrent()) { TimerEvent* timer = new TimerEvent(std::move(task)); evtimer_set(&timer->ev, &TaskQueue::RunTimer, timer); event_base_set(event_base_, &timer->ev); QueueContext* ctx = static_cast(pthread_getspecific(GetQueuePtrTls())); ctx->pending_timers_.push_back(timer); timeval tv = {milliseconds / 1000, (milliseconds % 1000) * 1000}; event_add(&timer->ev, &tv); } else { PostTask(std::unique_ptr( new SetTimerTask(std::move(task), milliseconds))); } } void TaskQueue::PostTaskAndReply(std::unique_ptr task, std::unique_ptr reply, TaskQueue* reply_queue) { std::unique_ptr wrapper_task( new PostAndReplyTask(std::move(task), std::move(reply), reply_queue)); PostTask(std::move(wrapper_task)); } void TaskQueue::PostTaskAndReply(std::unique_ptr task, std::unique_ptr reply) { return PostTaskAndReply(std::move(task), std::move(reply), Current()); } // static bool TaskQueue::ThreadMain(void* context) { TaskQueue* me = static_cast(context); QueueContext queue_context(me); pthread_setspecific(GetQueuePtrTls(), &queue_context); while (queue_context.is_active) event_base_loop(me->event_base_, 0); pthread_setspecific(GetQueuePtrTls(), nullptr); for (TimerEvent* timer : queue_context.pending_timers_) delete timer; return false; } // static void TaskQueue::OnWakeup(int socket, short flags, void* context) { // NOLINT QueueContext* ctx = static_cast(pthread_getspecific(GetQueuePtrTls())); RTC_DCHECK(ctx->queue->wakeup_pipe_out_ == socket); char buf; RTC_CHECK(sizeof(buf) == read(socket, &buf, sizeof(buf))); switch (buf) { case kQuit: ctx->is_active = false; event_base_loopbreak(ctx->queue->event_base_); break; case kRunTask: { std::unique_ptr task; { CritScope lock(&ctx->queue->pending_lock_); RTC_DCHECK(!ctx->queue->pending_.empty()); task = std::move(ctx->queue->pending_.front()); ctx->queue->pending_.pop_front(); RTC_DCHECK(task.get()); } if (!task->Run()) task.release(); break; } default: RTC_NOTREACHED(); break; } } // static void TaskQueue::RunTask(int fd, short flags, void* context) { // NOLINT auto* task = static_cast(context); if (task->Run()) delete task; } // static void TaskQueue::RunTimer(int fd, short flags, void* context) { // NOLINT TimerEvent* timer = static_cast(context); if (!timer->task->Run()) timer->task.release(); QueueContext* ctx = static_cast(pthread_getspecific(GetQueuePtrTls())); ctx->pending_timers_.remove(timer); delete timer; } void TaskQueue::PrepareReplyTask(PostAndReplyTask* reply_task) { RTC_DCHECK(reply_task); CritScope lock(&pending_lock_); pending_replies_.push_back(reply_task); } void TaskQueue::ReplyTaskDone(PostAndReplyTask* reply_task) { CritScope lock(&pending_lock_); pending_replies_.remove(reply_task); } } // namespace rtc