/* * Copyright (c) 2013 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/video_receive_stream.h" #include #include #include #include #include #include #include #include "absl/algorithm/container.h" #include "absl/types/optional.h" #include "api/array_view.h" #include "api/crypto/frame_decryptor_interface.h" #include "api/video/encoded_image.h" #include "api/video_codecs/sdp_video_format.h" #include "api/video_codecs/video_codec.h" #include "api/video_codecs/video_decoder_factory.h" #include "api/video_codecs/video_encoder.h" #include "call/rtp_stream_receiver_controller_interface.h" #include "call/rtx_receive_stream.h" #include "common_video/include/incoming_video_stream.h" #include "media/base/h264_profile_level_id.h" #include "modules/utility/include/process_thread.h" #include "modules/video_coding/include/video_codec_interface.h" #include "modules/video_coding/include/video_coding_defines.h" #include "modules/video_coding/include/video_error_codes.h" #include "modules/video_coding/timing.h" #include "modules/video_coding/utility/vp8_header_parser.h" #include "rtc_base/checks.h" #include "rtc_base/experiments/keyframe_interval_settings.h" #include "rtc_base/location.h" #include "rtc_base/logging.h" #include "rtc_base/strings/string_builder.h" #include "rtc_base/system/thread_registry.h" #include "rtc_base/time_utils.h" #include "rtc_base/trace_event.h" #include "system_wrappers/include/clock.h" #include "system_wrappers/include/field_trial.h" #include "video/call_stats.h" #include "video/frame_dumping_decoder.h" #include "video/receive_statistics_proxy.h" namespace webrtc { namespace internal { constexpr int VideoReceiveStream::kMaxWaitForKeyFrameMs; } // namespace internal namespace { using video_coding::EncodedFrame; using ReturnReason = video_coding::FrameBuffer::ReturnReason; constexpr int kMinBaseMinimumDelayMs = 0; constexpr int kMaxBaseMinimumDelayMs = 10000; constexpr int kMaxWaitForFrameMs = 3000; // Concrete instance of RecordableEncodedFrame wrapping needed content // from video_coding::EncodedFrame. class WebRtcRecordableEncodedFrame : public RecordableEncodedFrame { public: explicit WebRtcRecordableEncodedFrame(const EncodedFrame& frame) : buffer_(frame.GetEncodedData()), render_time_ms_(frame.RenderTime()), codec_(frame.CodecSpecific()->codecType), is_key_frame_(frame.FrameType() == VideoFrameType::kVideoFrameKey), resolution_{frame.EncodedImage()._encodedWidth, frame.EncodedImage()._encodedHeight} { if (frame.ColorSpace()) { color_space_ = *frame.ColorSpace(); } } // VideoEncodedSinkInterface::FrameBuffer rtc::scoped_refptr encoded_buffer() const override { return buffer_; } absl::optional color_space() const override { return color_space_; } VideoCodecType codec() const override { return codec_; } bool is_key_frame() const override { return is_key_frame_; } EncodedResolution resolution() const override { return resolution_; } Timestamp render_time() const override { return Timestamp::Millis(render_time_ms_); } private: rtc::scoped_refptr buffer_; int64_t render_time_ms_; VideoCodecType codec_; bool is_key_frame_; EncodedResolution resolution_; absl::optional color_space_; }; VideoCodec CreateDecoderVideoCodec(const VideoReceiveStream::Decoder& decoder) { VideoCodec codec; memset(&codec, 0, sizeof(codec)); codec.codecType = PayloadStringToCodecType(decoder.video_format.name); if (codec.codecType == kVideoCodecVP8) { *(codec.VP8()) = VideoEncoder::GetDefaultVp8Settings(); } else if (codec.codecType == kVideoCodecVP9) { *(codec.VP9()) = VideoEncoder::GetDefaultVp9Settings(); } else if (codec.codecType == kVideoCodecH264) { *(codec.H264()) = VideoEncoder::GetDefaultH264Settings(); } else if (codec.codecType == kVideoCodecMultiplex) { VideoReceiveStream::Decoder associated_decoder = decoder; associated_decoder.video_format = SdpVideoFormat(CodecTypeToPayloadString(kVideoCodecVP9)); VideoCodec associated_codec = CreateDecoderVideoCodec(associated_decoder); associated_codec.codecType = kVideoCodecMultiplex; return associated_codec; } #ifndef DISABLE_H265 else if (codec.codecType == kVideoCodecH265) { *(codec.H265()) = VideoEncoder::GetDefaultH265Settings(); } #endif codec.width = 320; codec.height = 180; const int kDefaultStartBitrate = 300; codec.startBitrate = codec.minBitrate = codec.maxBitrate = kDefaultStartBitrate; return codec; } // Video decoder class to be used for unknown codecs. Doesn't support decoding // but logs messages to LS_ERROR. class NullVideoDecoder : public webrtc::VideoDecoder { public: int32_t InitDecode(const webrtc::VideoCodec* codec_settings, int32_t number_of_cores) override { RTC_LOG(LS_ERROR) << "Can't initialize NullVideoDecoder."; return WEBRTC_VIDEO_CODEC_OK; } int32_t Decode(const webrtc::EncodedImage& input_image, bool missing_frames, int64_t render_time_ms) override { RTC_LOG(LS_ERROR) << "The NullVideoDecoder doesn't support decoding."; return WEBRTC_VIDEO_CODEC_OK; } int32_t RegisterDecodeCompleteCallback( webrtc::DecodedImageCallback* callback) override { RTC_LOG(LS_ERROR) << "Can't register decode complete callback on NullVideoDecoder."; return WEBRTC_VIDEO_CODEC_OK; } int32_t Release() override { return WEBRTC_VIDEO_CODEC_OK; } const char* ImplementationName() const override { return "NullVideoDecoder"; } }; // TODO(https://bugs.webrtc.org/9974): Consider removing this workaround. // Maximum time between frames before resetting the FrameBuffer to avoid RTP // timestamps wraparound to affect FrameBuffer. constexpr int kInactiveStreamThresholdMs = 600000; // 10 minutes. } // namespace namespace internal { VideoReceiveStream::VideoReceiveStream( TaskQueueFactory* task_queue_factory, RtpStreamReceiverControllerInterface* receiver_controller, int num_cpu_cores, PacketRouter* packet_router, VideoReceiveStream::Config config, ProcessThread* process_thread, CallStats* call_stats, Clock* clock, VCMTiming* timing) : task_queue_factory_(task_queue_factory), transport_adapter_(config.rtcp_send_transport), config_(std::move(config)), num_cpu_cores_(num_cpu_cores), process_thread_(process_thread), clock_(clock), call_stats_(call_stats), source_tracker_(clock_), stats_proxy_(&config_, clock_), rtp_receive_statistics_(ReceiveStatistics::Create(clock_)), timing_(timing), video_receiver_(clock_, timing_.get()), rtp_video_stream_receiver_(clock_, &transport_adapter_, call_stats, packet_router, &config_, rtp_receive_statistics_.get(), &stats_proxy_, &stats_proxy_, process_thread_, this, // NackSender nullptr, // Use default KeyFrameRequestSender this, // OnCompleteFrameCallback config_.frame_decryptor, config_.frame_transformer), rtp_stream_sync_(this), max_wait_for_keyframe_ms_(KeyframeIntervalSettings::ParseFromFieldTrials() .MaxWaitForKeyframeMs() .value_or(kMaxWaitForKeyFrameMs)), max_wait_for_frame_ms_(KeyframeIntervalSettings::ParseFromFieldTrials() .MaxWaitForFrameMs() .value_or(kMaxWaitForFrameMs)), decode_queue_(task_queue_factory_->CreateTaskQueue( "DecodingQueue", TaskQueueFactory::Priority::HIGH)) { RTC_LOG(LS_INFO) << "VideoReceiveStream: " << config_.ToString(); RTC_DCHECK(config_.renderer); RTC_DCHECK(process_thread_); RTC_DCHECK(call_stats_); module_process_sequence_checker_.Detach(); network_sequence_checker_.Detach(); RTC_DCHECK(!config_.decoders.empty()); RTC_CHECK(config_.decoder_factory); std::set decoder_payload_types; for (const Decoder& decoder : config_.decoders) { RTC_CHECK(decoder_payload_types.find(decoder.payload_type) == decoder_payload_types.end()) << "Duplicate payload type (" << decoder.payload_type << ") for different decoders."; decoder_payload_types.insert(decoder.payload_type); } timing_->set_render_delay(config_.render_delay_ms); frame_buffer_.reset( new video_coding::FrameBuffer(clock_, timing_.get(), &stats_proxy_)); process_thread_->RegisterModule(&rtp_stream_sync_, RTC_FROM_HERE); // Register with RtpStreamReceiverController. media_receiver_ = receiver_controller->CreateReceiver( config_.rtp.remote_ssrc, &rtp_video_stream_receiver_); if (config_.rtp.rtx_ssrc) { rtx_receive_stream_ = std::make_unique( &rtp_video_stream_receiver_, config.rtp.rtx_associated_payload_types, config_.rtp.remote_ssrc, rtp_receive_statistics_.get()); rtx_receiver_ = receiver_controller->CreateReceiver( config_.rtp.rtx_ssrc, rtx_receive_stream_.get()); } else { rtp_receive_statistics_->EnableRetransmitDetection(config.rtp.remote_ssrc, true); } } VideoReceiveStream::VideoReceiveStream( TaskQueueFactory* task_queue_factory, RtpStreamReceiverControllerInterface* receiver_controller, int num_cpu_cores, PacketRouter* packet_router, VideoReceiveStream::Config config, ProcessThread* process_thread, CallStats* call_stats, Clock* clock) : VideoReceiveStream(task_queue_factory, receiver_controller, num_cpu_cores, packet_router, std::move(config), process_thread, call_stats, clock, new VCMTiming(clock)) {} VideoReceiveStream::~VideoReceiveStream() { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); RTC_LOG(LS_INFO) << "~VideoReceiveStream: " << config_.ToString(); Stop(); process_thread_->DeRegisterModule(&rtp_stream_sync_); } void VideoReceiveStream::SignalNetworkState(NetworkState state) { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); rtp_video_stream_receiver_.SignalNetworkState(state); } bool VideoReceiveStream::DeliverRtcp(const uint8_t* packet, size_t length) { return rtp_video_stream_receiver_.DeliverRtcp(packet, length); } void VideoReceiveStream::SetSync(Syncable* audio_syncable) { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); rtp_stream_sync_.ConfigureSync(audio_syncable); } void VideoReceiveStream::Start() { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); if (decoder_running_) { return; } const bool protected_by_fec = config_.rtp.protected_by_flexfec || rtp_video_stream_receiver_.IsUlpfecEnabled(); if (rtp_video_stream_receiver_.IsRetransmissionsEnabled() && protected_by_fec) { frame_buffer_->SetProtectionMode(kProtectionNackFEC); } transport_adapter_.Enable(); rtc::VideoSinkInterface* renderer = nullptr; if (config_.enable_prerenderer_smoothing) { incoming_video_stream_.reset(new IncomingVideoStream( task_queue_factory_, config_.render_delay_ms, this)); renderer = incoming_video_stream_.get(); } else { renderer = this; } for (const Decoder& decoder : config_.decoders) { std::unique_ptr video_decoder = config_.decoder_factory->LegacyCreateVideoDecoder(decoder.video_format, config_.stream_id); // If we still have no valid decoder, we have to create a "Null" decoder // that ignores all calls. The reason we can get into this state is that the // old decoder factory interface doesn't have a way to query supported // codecs. if (!video_decoder) { video_decoder = std::make_unique(); } std::string decoded_output_file = field_trial::FindFullName("WebRTC-DecoderDataDumpDirectory"); // Because '/' can't be used inside a field trial parameter, we use ';' // instead. // This is only relevant to WebRTC-DecoderDataDumpDirectory // field trial. ';' is chosen arbitrary. Even though it's a legal character // in some file systems, we can sacrifice ability to use it in the path to // dumped video, since it's developers-only feature for debugging. absl::c_replace(decoded_output_file, ';', '/'); if (!decoded_output_file.empty()) { char filename_buffer[256]; rtc::SimpleStringBuilder ssb(filename_buffer); ssb << decoded_output_file << "/webrtc_receive_stream_" << this->config_.rtp.remote_ssrc << "-" << rtc::TimeMicros() << ".ivf"; video_decoder = CreateFrameDumpingDecoderWrapper( std::move(video_decoder), FileWrapper::OpenWriteOnly(ssb.str())); } video_decoders_.push_back(std::move(video_decoder)); video_receiver_.RegisterExternalDecoder(video_decoders_.back().get(), decoder.payload_type); VideoCodec codec = CreateDecoderVideoCodec(decoder); const bool raw_payload = config_.rtp.raw_payload_types.count(decoder.payload_type) > 0; rtp_video_stream_receiver_.AddReceiveCodec(decoder.payload_type, codec, decoder.video_format.parameters, raw_payload); RTC_CHECK_EQ(VCM_OK, video_receiver_.RegisterReceiveCodec( decoder.payload_type, &codec, num_cpu_cores_)); } RTC_DCHECK(renderer != nullptr); video_stream_decoder_.reset( new VideoStreamDecoder(&video_receiver_, &stats_proxy_, renderer)); // Make sure we register as a stats observer *after* we've prepared the // |video_stream_decoder_|. call_stats_->RegisterStatsObserver(this); // Start decoding on task queue. video_receiver_.DecoderThreadStarting(); stats_proxy_.DecoderThreadStarting(); decode_queue_.PostTask([this] { RTC_DCHECK_RUN_ON(&decode_queue_); decoder_stopped_ = false; StartNextDecode(); }); decoder_running_ = true; rtp_video_stream_receiver_.StartReceive(); } void VideoReceiveStream::Stop() { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); rtp_video_stream_receiver_.StopReceive(); stats_proxy_.OnUniqueFramesCounted( rtp_video_stream_receiver_.GetUniqueFramesSeen()); decode_queue_.PostTask([this] { frame_buffer_->Stop(); }); call_stats_->DeregisterStatsObserver(this); if (decoder_running_) { rtc::Event done; decode_queue_.PostTask([this, &done] { RTC_DCHECK_RUN_ON(&decode_queue_); decoder_stopped_ = true; done.Set(); }); done.Wait(rtc::Event::kForever); decoder_running_ = false; video_receiver_.DecoderThreadStopped(); stats_proxy_.DecoderThreadStopped(); // Deregister external decoders so they are no longer running during // destruction. This effectively stops the VCM since the decoder thread is // stopped, the VCM is deregistered and no asynchronous decoder threads are // running. for (const Decoder& decoder : config_.decoders) video_receiver_.RegisterExternalDecoder(nullptr, decoder.payload_type); UpdateHistograms(); } video_stream_decoder_.reset(); incoming_video_stream_.reset(); transport_adapter_.Disable(); } VideoReceiveStream::Stats VideoReceiveStream::GetStats() const { VideoReceiveStream::Stats stats = stats_proxy_.GetStats(); stats.total_bitrate_bps = 0; StreamStatistician* statistician = rtp_receive_statistics_->GetStatistician(stats.ssrc); if (statistician) { stats.rtp_stats = statistician->GetStats(); stats.total_bitrate_bps = statistician->BitrateReceived(); } if (config_.rtp.rtx_ssrc) { StreamStatistician* rtx_statistician = rtp_receive_statistics_->GetStatistician(config_.rtp.rtx_ssrc); if (rtx_statistician) stats.total_bitrate_bps += rtx_statistician->BitrateReceived(); } return stats; } void VideoReceiveStream::UpdateHistograms() { absl::optional fraction_lost; StreamDataCounters rtp_stats; StreamStatistician* statistician = rtp_receive_statistics_->GetStatistician(config_.rtp.remote_ssrc); if (statistician) { fraction_lost = statistician->GetFractionLostInPercent(); rtp_stats = statistician->GetReceiveStreamDataCounters(); } if (config_.rtp.rtx_ssrc) { StreamStatistician* rtx_statistician = rtp_receive_statistics_->GetStatistician(config_.rtp.rtx_ssrc); if (rtx_statistician) { StreamDataCounters rtx_stats = rtx_statistician->GetReceiveStreamDataCounters(); stats_proxy_.UpdateHistograms(fraction_lost, rtp_stats, &rtx_stats); return; } } stats_proxy_.UpdateHistograms(fraction_lost, rtp_stats, nullptr); } void VideoReceiveStream::AddSecondarySink(RtpPacketSinkInterface* sink) { rtp_video_stream_receiver_.AddSecondarySink(sink); } void VideoReceiveStream::RemoveSecondarySink( const RtpPacketSinkInterface* sink) { rtp_video_stream_receiver_.RemoveSecondarySink(sink); } bool VideoReceiveStream::SetBaseMinimumPlayoutDelayMs(int delay_ms) { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); if (delay_ms < kMinBaseMinimumDelayMs || delay_ms > kMaxBaseMinimumDelayMs) { return false; } MutexLock lock(&playout_delay_lock_); base_minimum_playout_delay_ms_ = delay_ms; UpdatePlayoutDelays(); return true; } int VideoReceiveStream::GetBaseMinimumPlayoutDelayMs() const { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); MutexLock lock(&playout_delay_lock_); return base_minimum_playout_delay_ms_; } // TODO(tommi): This method grabs a lock 6 times. void VideoReceiveStream::OnFrame(const VideoFrame& video_frame) { int64_t video_playout_ntp_ms; int64_t sync_offset_ms; double estimated_freq_khz; // TODO(tommi): GetStreamSyncOffsetInMs grabs three locks. One inside the // function itself, another in GetChannel() and a third in // GetPlayoutTimestamp. Seems excessive. Anyhow, I'm assuming the function // succeeds most of the time, which leads to grabbing a fourth lock. if (rtp_stream_sync_.GetStreamSyncOffsetInMs( video_frame.timestamp(), video_frame.render_time_ms(), &video_playout_ntp_ms, &sync_offset_ms, &estimated_freq_khz)) { // TODO(tommi): OnSyncOffsetUpdated grabs a lock. stats_proxy_.OnSyncOffsetUpdated(video_playout_ntp_ms, sync_offset_ms, estimated_freq_khz); } source_tracker_.OnFrameDelivered(video_frame.packet_infos()); config_.renderer->OnFrame(video_frame); // TODO(tommi): OnRenderFrame grabs a lock too. stats_proxy_.OnRenderedFrame(video_frame); } void VideoReceiveStream::SetFrameDecryptor( rtc::scoped_refptr frame_decryptor) { rtp_video_stream_receiver_.SetFrameDecryptor(std::move(frame_decryptor)); } void VideoReceiveStream::SetDepacketizerToDecoderFrameTransformer( rtc::scoped_refptr frame_transformer) { rtp_video_stream_receiver_.SetDepacketizerToDecoderFrameTransformer( std::move(frame_transformer)); } void VideoReceiveStream::SendNack(const std::vector& sequence_numbers, bool buffering_allowed) { RTC_DCHECK(buffering_allowed); rtp_video_stream_receiver_.RequestPacketRetransmit(sequence_numbers); } void VideoReceiveStream::RequestKeyFrame(int64_t timestamp_ms) { rtp_video_stream_receiver_.RequestKeyFrame(); last_keyframe_request_ms_ = timestamp_ms; } void VideoReceiveStream::OnCompleteFrame( std::unique_ptr frame) { RTC_DCHECK_RUN_ON(&network_sequence_checker_); // TODO(https://bugs.webrtc.org/9974): Consider removing this workaround. int64_t time_now_ms = clock_->TimeInMilliseconds(); if (last_complete_frame_time_ms_ > 0 && time_now_ms - last_complete_frame_time_ms_ > kInactiveStreamThresholdMs) { frame_buffer_->Clear(); } last_complete_frame_time_ms_ = time_now_ms; const PlayoutDelay& playout_delay = frame->EncodedImage().playout_delay_; if (playout_delay.min_ms >= 0) { MutexLock lock(&playout_delay_lock_); frame_minimum_playout_delay_ms_ = playout_delay.min_ms; UpdatePlayoutDelays(); } if (playout_delay.max_ms >= 0) { MutexLock lock(&playout_delay_lock_); frame_maximum_playout_delay_ms_ = playout_delay.max_ms; UpdatePlayoutDelays(); } int64_t last_continuous_pid = frame_buffer_->InsertFrame(std::move(frame)); if (last_continuous_pid != -1) rtp_video_stream_receiver_.FrameContinuous(last_continuous_pid); } void VideoReceiveStream::OnRttUpdate(int64_t avg_rtt_ms, int64_t max_rtt_ms) { RTC_DCHECK_RUN_ON(&module_process_sequence_checker_); frame_buffer_->UpdateRtt(max_rtt_ms); rtp_video_stream_receiver_.UpdateRtt(max_rtt_ms); } uint32_t VideoReceiveStream::id() const { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); return config_.rtp.remote_ssrc; } absl::optional VideoReceiveStream::GetInfo() const { RTC_DCHECK_RUN_ON(&module_process_sequence_checker_); absl::optional info = rtp_video_stream_receiver_.GetSyncInfo(); if (!info) return absl::nullopt; info->current_delay_ms = timing_->TargetVideoDelay(); return info; } bool VideoReceiveStream::GetPlayoutRtpTimestamp(uint32_t* rtp_timestamp, int64_t* time_ms) const { RTC_NOTREACHED(); return 0; } void VideoReceiveStream::SetEstimatedPlayoutNtpTimestampMs( int64_t ntp_timestamp_ms, int64_t time_ms) { RTC_NOTREACHED(); } void VideoReceiveStream::SetMinimumPlayoutDelay(int delay_ms) { RTC_DCHECK_RUN_ON(&module_process_sequence_checker_); MutexLock lock(&playout_delay_lock_); syncable_minimum_playout_delay_ms_ = delay_ms; UpdatePlayoutDelays(); } int64_t VideoReceiveStream::GetWaitMs() const { return keyframe_required_ ? max_wait_for_keyframe_ms_ : max_wait_for_frame_ms_; } void VideoReceiveStream::StartNextDecode() { TRACE_EVENT0("webrtc", "VideoReceiveStream::StartNextDecode"); frame_buffer_->NextFrame( GetWaitMs(), keyframe_required_, &decode_queue_, /* encoded frame handler */ [this](std::unique_ptr frame, ReturnReason res) { RTC_DCHECK_EQ(frame == nullptr, res == ReturnReason::kTimeout); RTC_DCHECK_EQ(frame != nullptr, res == ReturnReason::kFrameFound); decode_queue_.PostTask([this, frame = std::move(frame)]() mutable { RTC_DCHECK_RUN_ON(&decode_queue_); if (decoder_stopped_) return; if (frame) { HandleEncodedFrame(std::move(frame)); } else { HandleFrameBufferTimeout(); } StartNextDecode(); }); }); } void VideoReceiveStream::HandleEncodedFrame( std::unique_ptr frame) { int64_t now_ms = clock_->TimeInMilliseconds(); // Current OnPreDecode only cares about QP for VP8. int qp = -1; if (frame->CodecSpecific()->codecType == kVideoCodecVP8) { if (!vp8::GetQp(frame->data(), frame->size(), &qp)) { RTC_LOG(LS_WARNING) << "Failed to extract QP from VP8 video frame"; } } stats_proxy_.OnPreDecode(frame->CodecSpecific()->codecType, qp); HandleKeyFrameGeneration(frame->FrameType() == VideoFrameType::kVideoFrameKey, now_ms); int decode_result = video_receiver_.Decode(frame.get()); if (decode_result == WEBRTC_VIDEO_CODEC_OK || decode_result == WEBRTC_VIDEO_CODEC_OK_REQUEST_KEYFRAME) { keyframe_required_ = false; frame_decoded_ = true; rtp_video_stream_receiver_.FrameDecoded(frame->id.picture_id); if (decode_result == WEBRTC_VIDEO_CODEC_OK_REQUEST_KEYFRAME) RequestKeyFrame(now_ms); } else if (!frame_decoded_ || !keyframe_required_ || (last_keyframe_request_ms_ + max_wait_for_keyframe_ms_ < now_ms)) { keyframe_required_ = true; // TODO(philipel): Remove this keyframe request when downstream project // has been fixed. RequestKeyFrame(now_ms); } if (encoded_frame_buffer_function_) { frame->Retain(); encoded_frame_buffer_function_(WebRtcRecordableEncodedFrame(*frame)); } } void VideoReceiveStream::HandleKeyFrameGeneration( bool received_frame_is_keyframe, int64_t now_ms) { // Repeat sending keyframe requests if we've requested a keyframe. if (!keyframe_generation_requested_) { return; } if (received_frame_is_keyframe) { keyframe_generation_requested_ = false; } else if (last_keyframe_request_ms_ + max_wait_for_keyframe_ms_ <= now_ms) { if (!IsReceivingKeyFrame(now_ms)) { RequestKeyFrame(now_ms); } } else { // It hasn't been long enough since the last keyframe request, do nothing. } } void VideoReceiveStream::HandleFrameBufferTimeout() { int64_t now_ms = clock_->TimeInMilliseconds(); absl::optional last_packet_ms = rtp_video_stream_receiver_.LastReceivedPacketMs(); // To avoid spamming keyframe requests for a stream that is not active we // check if we have received a packet within the last 5 seconds. bool stream_is_active = last_packet_ms && now_ms - *last_packet_ms < 5000; if (!stream_is_active) stats_proxy_.OnStreamInactive(); if (stream_is_active && !IsReceivingKeyFrame(now_ms) && (!config_.crypto_options.sframe.require_frame_encryption || rtp_video_stream_receiver_.IsDecryptable())) { RTC_LOG(LS_WARNING) << "No decodable frame in " << GetWaitMs() << " ms, requesting keyframe."; RequestKeyFrame(now_ms); } } bool VideoReceiveStream::IsReceivingKeyFrame(int64_t timestamp_ms) const { absl::optional last_keyframe_packet_ms = rtp_video_stream_receiver_.LastReceivedKeyframePacketMs(); // If we recently have been receiving packets belonging to a keyframe then // we assume a keyframe is currently being received. bool receiving_keyframe = last_keyframe_packet_ms && timestamp_ms - *last_keyframe_packet_ms < max_wait_for_keyframe_ms_; return receiving_keyframe; } void VideoReceiveStream::UpdatePlayoutDelays() const { const int minimum_delay_ms = std::max({frame_minimum_playout_delay_ms_, base_minimum_playout_delay_ms_, syncable_minimum_playout_delay_ms_}); if (minimum_delay_ms >= 0) { timing_->set_min_playout_delay(minimum_delay_ms); } const int maximum_delay_ms = frame_maximum_playout_delay_ms_; if (maximum_delay_ms >= 0) { timing_->set_max_playout_delay(maximum_delay_ms); } } std::vector VideoReceiveStream::GetSources() const { return source_tracker_.GetSources(); } VideoReceiveStream::RecordingState VideoReceiveStream::SetAndGetRecordingState( RecordingState state, bool generate_key_frame) { RTC_DCHECK_RUN_ON(&worker_sequence_checker_); rtc::Event event; RecordingState old_state; decode_queue_.PostTask([this, &event, &old_state, generate_key_frame, state = std::move(state)] { RTC_DCHECK_RUN_ON(&decode_queue_); // Save old state. old_state.callback = std::move(encoded_frame_buffer_function_); old_state.keyframe_needed = keyframe_generation_requested_; old_state.last_keyframe_request_ms = last_keyframe_request_ms_; // Set new state. encoded_frame_buffer_function_ = std::move(state.callback); if (generate_key_frame) { RequestKeyFrame(clock_->TimeInMilliseconds()); keyframe_generation_requested_ = true; } else { keyframe_generation_requested_ = state.keyframe_needed; last_keyframe_request_ms_ = state.last_keyframe_request_ms.value_or(0); } event.Set(); }); event.Wait(rtc::Event::kForever); return old_state; } void VideoReceiveStream::GenerateKeyFrame() { decode_queue_.PostTask([this]() { RTC_DCHECK_RUN_ON(&decode_queue_); RequestKeyFrame(clock_->TimeInMilliseconds()); keyframe_generation_requested_ = true; }); } } // namespace internal } // namespace webrtc