/* * Copyright (c) 2022 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 "video/decode_synchronizer.h" #include #include #include #include #include "api/sequence_checker.h" #include "api/units/time_delta.h" #include "api/units/timestamp.h" #include "rtc_base/checks.h" #include "rtc_base/logging.h" #include "video/frame_decode_scheduler.h" #include "video/frame_decode_timing.h" namespace webrtc { DecodeSynchronizer::ScheduledFrame::ScheduledFrame( uint32_t rtp_timestamp, FrameDecodeTiming::FrameSchedule schedule, FrameDecodeScheduler::FrameReleaseCallback callback) : rtp_timestamp_(rtp_timestamp), schedule_(std::move(schedule)), callback_(std::move(callback)) {} void DecodeSynchronizer::ScheduledFrame::RunFrameReleaseCallback() && { // Inspiration from Chromium base::OnceCallback. Move `*this` to a local // before execution to ensure internal state is cleared after callback // execution. auto sf = std::move(*this); std::move(sf.callback_)(sf.rtp_timestamp_, sf.schedule_.render_time); } Timestamp DecodeSynchronizer::ScheduledFrame::LatestDecodeTime() const { return schedule_.latest_decode_time; } DecodeSynchronizer::SynchronizedFrameDecodeScheduler:: SynchronizedFrameDecodeScheduler(DecodeSynchronizer* sync) : sync_(sync) { RTC_DCHECK(sync_); } DecodeSynchronizer::SynchronizedFrameDecodeScheduler:: ~SynchronizedFrameDecodeScheduler() { RTC_DCHECK(!next_frame_); RTC_DCHECK(stopped_); } absl::optional DecodeSynchronizer::SynchronizedFrameDecodeScheduler::ScheduledRtpTimestamp() { return next_frame_.has_value() ? absl::make_optional(next_frame_->rtp_timestamp()) : absl::nullopt; } DecodeSynchronizer::ScheduledFrame DecodeSynchronizer::SynchronizedFrameDecodeScheduler::ReleaseNextFrame() { RTC_DCHECK(next_frame_); auto res = std::move(*next_frame_); next_frame_.reset(); return res; } Timestamp DecodeSynchronizer::SynchronizedFrameDecodeScheduler::LatestDecodeTime() { RTC_DCHECK(next_frame_); return next_frame_->LatestDecodeTime(); } void DecodeSynchronizer::SynchronizedFrameDecodeScheduler::ScheduleFrame( uint32_t rtp, FrameDecodeTiming::FrameSchedule schedule, FrameReleaseCallback cb) { RTC_DCHECK(!next_frame_) << "Can not schedule two frames at once."; next_frame_ = ScheduledFrame(rtp, std::move(schedule), std::move(cb)); sync_->OnFrameScheduled(this); } void DecodeSynchronizer::SynchronizedFrameDecodeScheduler::CancelOutstanding() { next_frame_.reset(); } void DecodeSynchronizer::SynchronizedFrameDecodeScheduler::Stop() { CancelOutstanding(); stopped_ = true; sync_->RemoveFrameScheduler(this); } DecodeSynchronizer::DecodeSynchronizer(Clock* clock, Metronome* metronome, TaskQueueBase* worker_queue) : clock_(clock), worker_queue_(worker_queue), metronome_(metronome) { RTC_DCHECK(metronome_); RTC_DCHECK(worker_queue_); } DecodeSynchronizer::~DecodeSynchronizer() { RTC_DCHECK(schedulers_.empty()); } std::unique_ptr DecodeSynchronizer::CreateSynchronizedFrameScheduler() { RTC_DCHECK_RUN_ON(worker_queue_); auto scheduler = std::make_unique(this); auto [it, inserted] = schedulers_.emplace(scheduler.get()); // If this is the first `scheduler` added, start listening to the metronome. if (inserted && schedulers_.size() == 1) { RTC_DLOG(LS_VERBOSE) << "Listening to metronome"; metronome_->AddListener(this); } return std::move(scheduler); } void DecodeSynchronizer::OnFrameScheduled( SynchronizedFrameDecodeScheduler* scheduler) { RTC_DCHECK_RUN_ON(worker_queue_); RTC_DCHECK(scheduler->ScheduledRtpTimestamp()); Timestamp now = clock_->CurrentTime(); Timestamp next_tick = expected_next_tick_; // If no tick has registered yet assume it will occur in the tick period. if (next_tick.IsInfinite()) { next_tick = now + metronome_->TickPeriod(); } // Release the frame right away if the decode time is too soon. Otherwise // the stream may fall behind too much. bool decode_before_next_tick = scheduler->LatestDecodeTime() < (next_tick - FrameDecodeTiming::kMaxAllowedFrameDelay); // Decode immediately if the decode time is in the past. bool decode_time_in_past = scheduler->LatestDecodeTime() < now; if (decode_before_next_tick || decode_time_in_past) { ScheduledFrame scheduled_frame = scheduler->ReleaseNextFrame(); std::move(scheduled_frame).RunFrameReleaseCallback(); } } void DecodeSynchronizer::RemoveFrameScheduler( SynchronizedFrameDecodeScheduler* scheduler) { RTC_DCHECK_RUN_ON(worker_queue_); RTC_DCHECK(scheduler); auto it = schedulers_.find(scheduler); if (it == schedulers_.end()) { return; } schedulers_.erase(it); // If there are no more schedulers active, stop listening for metronome ticks. if (schedulers_.empty()) { RTC_DLOG(LS_VERBOSE) << "Not listening to metronome"; metronome_->RemoveListener(this); expected_next_tick_ = Timestamp::PlusInfinity(); } } void DecodeSynchronizer::OnTick() { RTC_DCHECK_RUN_ON(worker_queue_); expected_next_tick_ = clock_->CurrentTime() + metronome_->TickPeriod(); for (auto* scheduler : schedulers_) { if (scheduler->ScheduledRtpTimestamp() && scheduler->LatestDecodeTime() < expected_next_tick_) { auto scheduled_frame = scheduler->ReleaseNextFrame(); std::move(scheduled_frame).RunFrameReleaseCallback(); } } } TaskQueueBase* DecodeSynchronizer::OnTickTaskQueue() { return worker_queue_; } } // namespace webrtc