/* * Copyright (c) 2012 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/rtp_video_stream_receiver2.h" #include #include #include #include #include #include "absl/algorithm/container.h" #include "absl/base/macros.h" #include "absl/memory/memory.h" #include "absl/types/optional.h" #include "media/base/media_constants.h" #include "modules/pacing/packet_router.h" #include "modules/remote_bitrate_estimator/include/remote_bitrate_estimator.h" #include "modules/rtp_rtcp/include/receive_statistics.h" #include "modules/rtp_rtcp/include/rtp_cvo.h" #include "modules/rtp_rtcp/include/ulpfec_receiver.h" #include "modules/rtp_rtcp/source/create_video_rtp_depacketizer.h" #include "modules/rtp_rtcp/source/rtp_dependency_descriptor_extension.h" #include "modules/rtp_rtcp/source/rtp_format.h" #include "modules/rtp_rtcp/source/rtp_generic_frame_descriptor.h" #include "modules/rtp_rtcp/source/rtp_generic_frame_descriptor_extension.h" #include "modules/rtp_rtcp/source/rtp_header_extensions.h" #include "modules/rtp_rtcp/source/rtp_packet_received.h" #include "modules/rtp_rtcp/source/rtp_rtcp_config.h" #include "modules/rtp_rtcp/source/video_rtp_depacketizer.h" #include "modules/rtp_rtcp/source/video_rtp_depacketizer_raw.h" #include "modules/utility/include/process_thread.h" #include "modules/video_coding/frame_object.h" #include "modules/video_coding/h264_sprop_parameter_sets.h" #include "modules/video_coding/h264_sps_pps_tracker.h" #include "modules/video_coding/nack_module2.h" #include "modules/video_coding/packet_buffer.h" #include "rtc_base/checks.h" #include "rtc_base/location.h" #include "rtc_base/logging.h" #include "rtc_base/strings/string_builder.h" #include "system_wrappers/include/field_trial.h" #include "system_wrappers/include/metrics.h" #include "system_wrappers/include/ntp_time.h" #include "video/receive_statistics_proxy2.h" namespace webrtc { namespace { // TODO(philipel): Change kPacketBufferStartSize back to 32 in M63 see: // crbug.com/752886 constexpr int kPacketBufferStartSize = 512; constexpr int kPacketBufferMaxSize = 2048; int PacketBufferMaxSize() { // The group here must be a positive power of 2, in which case that is used as // size. All other values shall result in the default value being used. const std::string group_name = webrtc::field_trial::FindFullName("WebRTC-PacketBufferMaxSize"); int packet_buffer_max_size = kPacketBufferMaxSize; if (!group_name.empty() && (sscanf(group_name.c_str(), "%d", &packet_buffer_max_size) != 1 || packet_buffer_max_size <= 0 || // Verify that the number is a positive power of 2. (packet_buffer_max_size & (packet_buffer_max_size - 1)) != 0)) { RTC_LOG(LS_WARNING) << "Invalid packet buffer max size: " << group_name; packet_buffer_max_size = kPacketBufferMaxSize; } return packet_buffer_max_size; } std::unique_ptr CreateRtpRtcpModule( Clock* clock, ReceiveStatistics* receive_statistics, Transport* outgoing_transport, RtcpRttStats* rtt_stats, RtcpPacketTypeCounterObserver* rtcp_packet_type_counter_observer, RtcpCnameCallback* rtcp_cname_callback, uint32_t local_ssrc) { RtpRtcpInterface::Configuration configuration; configuration.clock = clock; configuration.audio = false; configuration.receiver_only = true; configuration.receive_statistics = receive_statistics; configuration.outgoing_transport = outgoing_transport; configuration.rtt_stats = rtt_stats; configuration.rtcp_packet_type_counter_observer = rtcp_packet_type_counter_observer; configuration.rtcp_cname_callback = rtcp_cname_callback; configuration.local_media_ssrc = local_ssrc; std::unique_ptr rtp_rtcp = ModuleRtpRtcpImpl2::Create(configuration); rtp_rtcp->SetRTCPStatus(RtcpMode::kCompound); return rtp_rtcp; } std::unique_ptr MaybeConstructNackModule( TaskQueueBase* current_queue, const VideoReceiveStream::Config& config, Clock* clock, NackSender* nack_sender, KeyFrameRequestSender* keyframe_request_sender) { if (config.rtp.nack.rtp_history_ms == 0) return nullptr; return std::make_unique(current_queue, clock, nack_sender, keyframe_request_sender); } static const int kPacketLogIntervalMs = 10000; } // namespace RtpVideoStreamReceiver2::RtcpFeedbackBuffer::RtcpFeedbackBuffer( KeyFrameRequestSender* key_frame_request_sender, NackSender* nack_sender, LossNotificationSender* loss_notification_sender) : key_frame_request_sender_(key_frame_request_sender), nack_sender_(nack_sender), loss_notification_sender_(loss_notification_sender), request_key_frame_(false) { RTC_DCHECK(key_frame_request_sender_); RTC_DCHECK(nack_sender_); RTC_DCHECK(loss_notification_sender_); } void RtpVideoStreamReceiver2::RtcpFeedbackBuffer::RequestKeyFrame() { RTC_DCHECK_RUN_ON(&worker_task_checker_); request_key_frame_ = true; } void RtpVideoStreamReceiver2::RtcpFeedbackBuffer::SendNack( const std::vector& sequence_numbers, bool buffering_allowed) { RTC_DCHECK_RUN_ON(&worker_task_checker_); RTC_DCHECK(!sequence_numbers.empty()); nack_sequence_numbers_.insert(nack_sequence_numbers_.end(), sequence_numbers.cbegin(), sequence_numbers.cend()); if (!buffering_allowed) { // Note that while *buffering* is not allowed, *batching* is, meaning that // previously buffered messages may be sent along with the current message. SendBufferedRtcpFeedback(); } } void RtpVideoStreamReceiver2::RtcpFeedbackBuffer::SendLossNotification( uint16_t last_decoded_seq_num, uint16_t last_received_seq_num, bool decodability_flag, bool buffering_allowed) { RTC_DCHECK_RUN_ON(&worker_task_checker_); RTC_DCHECK(buffering_allowed); RTC_DCHECK(!lntf_state_) << "SendLossNotification() called twice in a row with no call to " "SendBufferedRtcpFeedback() in between."; lntf_state_ = absl::make_optional( last_decoded_seq_num, last_received_seq_num, decodability_flag); } void RtpVideoStreamReceiver2::RtcpFeedbackBuffer::SendBufferedRtcpFeedback() { RTC_DCHECK_RUN_ON(&worker_task_checker_); bool request_key_frame = false; std::vector nack_sequence_numbers; absl::optional lntf_state; std::swap(request_key_frame, request_key_frame_); std::swap(nack_sequence_numbers, nack_sequence_numbers_); std::swap(lntf_state, lntf_state_); if (lntf_state) { // If either a NACK or a key frame request is sent, we should buffer // the LNTF and wait for them (NACK or key frame request) to trigger // the compound feedback message. // Otherwise, the LNTF should be sent out immediately. const bool buffering_allowed = request_key_frame || !nack_sequence_numbers.empty(); loss_notification_sender_->SendLossNotification( lntf_state->last_decoded_seq_num, lntf_state->last_received_seq_num, lntf_state->decodability_flag, buffering_allowed); } if (request_key_frame) { key_frame_request_sender_->RequestKeyFrame(); } else if (!nack_sequence_numbers.empty()) { nack_sender_->SendNack(nack_sequence_numbers, true); } } RtpVideoStreamReceiver2::RtpVideoStreamReceiver2( TaskQueueBase* current_queue, Clock* clock, Transport* transport, RtcpRttStats* rtt_stats, PacketRouter* packet_router, const VideoReceiveStream::Config* config, ReceiveStatistics* rtp_receive_statistics, RtcpPacketTypeCounterObserver* rtcp_packet_type_counter_observer, RtcpCnameCallback* rtcp_cname_callback, ProcessThread* process_thread, NackSender* nack_sender, KeyFrameRequestSender* keyframe_request_sender, video_coding::OnCompleteFrameCallback* complete_frame_callback, rtc::scoped_refptr frame_decryptor, rtc::scoped_refptr frame_transformer) : clock_(clock), config_(*config), packet_router_(packet_router), process_thread_(process_thread), ntp_estimator_(clock), rtp_header_extensions_(config_.rtp.extensions), forced_playout_delay_max_ms_("max_ms", absl::nullopt), forced_playout_delay_min_ms_("min_ms", absl::nullopt), rtp_receive_statistics_(rtp_receive_statistics), ulpfec_receiver_(UlpfecReceiver::Create(config->rtp.remote_ssrc, this, config->rtp.extensions)), receiving_(false), last_packet_log_ms_(-1), rtp_rtcp_(CreateRtpRtcpModule(clock, rtp_receive_statistics_, transport, rtt_stats, rtcp_packet_type_counter_observer, rtcp_cname_callback, config_.rtp.local_ssrc)), complete_frame_callback_(complete_frame_callback), keyframe_request_sender_(keyframe_request_sender), // TODO(bugs.webrtc.org/10336): Let |rtcp_feedback_buffer_| communicate // directly with |rtp_rtcp_|. rtcp_feedback_buffer_(this, nack_sender, this), nack_module_(MaybeConstructNackModule(current_queue, config_, clock_, &rtcp_feedback_buffer_, &rtcp_feedback_buffer_)), packet_buffer_(clock_, kPacketBufferStartSize, PacketBufferMaxSize()), has_received_frame_(false), frames_decryptable_(false), absolute_capture_time_receiver_(clock) { constexpr bool remb_candidate = true; if (packet_router_) packet_router_->AddReceiveRtpModule(rtp_rtcp_.get(), remb_candidate); RTC_DCHECK(config_.rtp.rtcp_mode != RtcpMode::kOff) << "A stream should not be configured with RTCP disabled. This value is " "reserved for internal usage."; // TODO(pbos): What's an appropriate local_ssrc for receive-only streams? RTC_DCHECK(config_.rtp.local_ssrc != 0); RTC_DCHECK(config_.rtp.remote_ssrc != config_.rtp.local_ssrc); rtp_rtcp_->SetRTCPStatus(config_.rtp.rtcp_mode); rtp_rtcp_->SetRemoteSSRC(config_.rtp.remote_ssrc); static const int kMaxPacketAgeToNack = 450; const int max_reordering_threshold = (config_.rtp.nack.rtp_history_ms > 0) ? kMaxPacketAgeToNack : kDefaultMaxReorderingThreshold; rtp_receive_statistics_->SetMaxReorderingThreshold(config_.rtp.remote_ssrc, max_reordering_threshold); // TODO(nisse): For historic reasons, we applied the above // max_reordering_threshold also for RTX stats, which makes little sense since // we don't NACK rtx packets. Consider deleting the below block, and rely on // the default threshold. if (config_.rtp.rtx_ssrc) { rtp_receive_statistics_->SetMaxReorderingThreshold( config_.rtp.rtx_ssrc, max_reordering_threshold); } if (config_.rtp.rtcp_xr.receiver_reference_time_report) rtp_rtcp_->SetRtcpXrRrtrStatus(true); ParseFieldTrial( {&forced_playout_delay_max_ms_, &forced_playout_delay_min_ms_}, field_trial::FindFullName("WebRTC-ForcePlayoutDelay")); process_thread_->RegisterModule(rtp_rtcp_.get(), RTC_FROM_HERE); if (config_.rtp.lntf.enabled) { loss_notification_controller_ = std::make_unique(&rtcp_feedback_buffer_, &rtcp_feedback_buffer_); } reference_finder_ = std::make_unique(this); // Only construct the encrypted receiver if frame encryption is enabled. if (config_.crypto_options.sframe.require_frame_encryption) { buffered_frame_decryptor_ = std::make_unique(this, this); if (frame_decryptor != nullptr) { buffered_frame_decryptor_->SetFrameDecryptor(std::move(frame_decryptor)); } } if (frame_transformer) { frame_transformer_delegate_ = new rtc::RefCountedObject< RtpVideoStreamReceiverFrameTransformerDelegate>( this, std::move(frame_transformer), rtc::Thread::Current(), config_.rtp.remote_ssrc); frame_transformer_delegate_->Init(); } } RtpVideoStreamReceiver2::~RtpVideoStreamReceiver2() { RTC_DCHECK(secondary_sinks_.empty()); process_thread_->DeRegisterModule(rtp_rtcp_.get()); if (packet_router_) packet_router_->RemoveReceiveRtpModule(rtp_rtcp_.get()); UpdateHistograms(); if (frame_transformer_delegate_) frame_transformer_delegate_->Reset(); } void RtpVideoStreamReceiver2::AddReceiveCodec( uint8_t payload_type, const VideoCodec& video_codec, const std::map& codec_params, bool raw_payload) { RTC_DCHECK_RUN_ON(&worker_task_checker_); payload_type_map_.emplace( payload_type, raw_payload ? std::make_unique() : CreateVideoRtpDepacketizer(video_codec.codecType)); pt_codec_params_.emplace(payload_type, codec_params); } absl::optional RtpVideoStreamReceiver2::GetSyncInfo() const { RTC_DCHECK_RUN_ON(&worker_task_checker_); Syncable::Info info; if (rtp_rtcp_->RemoteNTP(&info.capture_time_ntp_secs, &info.capture_time_ntp_frac, nullptr, nullptr, &info.capture_time_source_clock) != 0) { return absl::nullopt; } if (!last_received_rtp_timestamp_ || !last_received_rtp_system_time_ms_) { return absl::nullopt; } info.latest_received_capture_timestamp = *last_received_rtp_timestamp_; info.latest_receive_time_ms = *last_received_rtp_system_time_ms_; // Leaves info.current_delay_ms uninitialized. return info; } RtpVideoStreamReceiver2::ParseGenericDependenciesResult RtpVideoStreamReceiver2::ParseGenericDependenciesExtension( const RtpPacketReceived& rtp_packet, RTPVideoHeader* video_header) { if (rtp_packet.HasExtension()) { webrtc::DependencyDescriptor dependency_descriptor; if (!rtp_packet.GetExtension( video_structure_.get(), &dependency_descriptor)) { // Descriptor is there, but failed to parse. Either it is invalid, // or too old packet (after relevant video_structure_ changed), // or too new packet (before relevant video_structure_ arrived). // Drop such packet to be on the safe side. // TODO(bugs.webrtc.org/10342): Stash too new packet. RTC_LOG(LS_WARNING) << "ssrc: " << rtp_packet.Ssrc() << " Failed to parse dependency descriptor."; return kDropPacket; } if (dependency_descriptor.attached_structure != nullptr && !dependency_descriptor.first_packet_in_frame) { RTC_LOG(LS_WARNING) << "ssrc: " << rtp_packet.Ssrc() << "Invalid dependency descriptor: structure " "attached to non first packet of a frame."; return kDropPacket; } video_header->is_first_packet_in_frame = dependency_descriptor.first_packet_in_frame; video_header->is_last_packet_in_frame = dependency_descriptor.last_packet_in_frame; int64_t frame_id = frame_id_unwrapper_.Unwrap(dependency_descriptor.frame_number); auto& generic_descriptor_info = video_header->generic.emplace(); generic_descriptor_info.frame_id = frame_id; generic_descriptor_info.spatial_index = dependency_descriptor.frame_dependencies.spatial_id; generic_descriptor_info.temporal_index = dependency_descriptor.frame_dependencies.temporal_id; for (int fdiff : dependency_descriptor.frame_dependencies.frame_diffs) { generic_descriptor_info.dependencies.push_back(frame_id - fdiff); } generic_descriptor_info.decode_target_indications = dependency_descriptor.frame_dependencies.decode_target_indications; if (dependency_descriptor.resolution) { video_header->width = dependency_descriptor.resolution->Width(); video_header->height = dependency_descriptor.resolution->Height(); } // FrameDependencyStructure is sent in dependency descriptor of the first // packet of a key frame and required for parsed dependency descriptor in // all the following packets until next key frame. // Save it if there is a (potentially) new structure. if (dependency_descriptor.attached_structure) { RTC_DCHECK(dependency_descriptor.first_packet_in_frame); if (video_structure_frame_id_ > frame_id) { RTC_LOG(LS_WARNING) << "Arrived key frame with id " << frame_id << " and structure id " << dependency_descriptor.attached_structure->structure_id << " is older than the latest received key frame with id " << *video_structure_frame_id_ << " and structure id " << video_structure_->structure_id; return kDropPacket; } video_structure_ = std::move(dependency_descriptor.attached_structure); video_structure_frame_id_ = frame_id; video_header->frame_type = VideoFrameType::kVideoFrameKey; } else { video_header->frame_type = VideoFrameType::kVideoFrameDelta; } return kHasGenericDescriptor; } RtpGenericFrameDescriptor generic_frame_descriptor; if (!rtp_packet.GetExtension( &generic_frame_descriptor)) { return kNoGenericDescriptor; } video_header->is_first_packet_in_frame = generic_frame_descriptor.FirstPacketInSubFrame(); video_header->is_last_packet_in_frame = generic_frame_descriptor.LastPacketInSubFrame(); if (generic_frame_descriptor.FirstPacketInSubFrame()) { video_header->frame_type = generic_frame_descriptor.FrameDependenciesDiffs().empty() ? VideoFrameType::kVideoFrameKey : VideoFrameType::kVideoFrameDelta; auto& generic_descriptor_info = video_header->generic.emplace(); int64_t frame_id = frame_id_unwrapper_.Unwrap(generic_frame_descriptor.FrameId()); generic_descriptor_info.frame_id = frame_id; generic_descriptor_info.spatial_index = generic_frame_descriptor.SpatialLayer(); generic_descriptor_info.temporal_index = generic_frame_descriptor.TemporalLayer(); for (uint16_t fdiff : generic_frame_descriptor.FrameDependenciesDiffs()) { generic_descriptor_info.dependencies.push_back(frame_id - fdiff); } } video_header->width = generic_frame_descriptor.Width(); video_header->height = generic_frame_descriptor.Height(); return kHasGenericDescriptor; } void RtpVideoStreamReceiver2::OnReceivedPayloadData( rtc::CopyOnWriteBuffer codec_payload, const RtpPacketReceived& rtp_packet, const RTPVideoHeader& video) { RTC_DCHECK_RUN_ON(&worker_task_checker_); auto packet = std::make_unique( rtp_packet, video, ntp_estimator_.Estimate(rtp_packet.Timestamp()), clock_->TimeInMilliseconds()); // Try to extrapolate absolute capture time if it is missing. packet->packet_info.set_absolute_capture_time( absolute_capture_time_receiver_.OnReceivePacket( AbsoluteCaptureTimeReceiver::GetSource(packet->packet_info.ssrc(), packet->packet_info.csrcs()), packet->packet_info.rtp_timestamp(), // Assume frequency is the same one for all video frames. kVideoPayloadTypeFrequency, packet->packet_info.absolute_capture_time())); RTPVideoHeader& video_header = packet->video_header; video_header.rotation = kVideoRotation_0; video_header.content_type = VideoContentType::UNSPECIFIED; video_header.video_timing.flags = VideoSendTiming::kInvalid; video_header.is_last_packet_in_frame |= rtp_packet.Marker(); if (const auto* vp9_header = absl::get_if(&video_header.video_type_header)) { video_header.is_last_packet_in_frame |= vp9_header->end_of_frame; video_header.is_first_packet_in_frame |= vp9_header->beginning_of_frame; } rtp_packet.GetExtension(&video_header.rotation); rtp_packet.GetExtension( &video_header.content_type); rtp_packet.GetExtension(&video_header.video_timing); if (forced_playout_delay_max_ms_ && forced_playout_delay_min_ms_) { video_header.playout_delay.max_ms = *forced_playout_delay_max_ms_; video_header.playout_delay.min_ms = *forced_playout_delay_min_ms_; } else { rtp_packet.GetExtension(&video_header.playout_delay); } ParseGenericDependenciesResult generic_descriptor_state = ParseGenericDependenciesExtension(rtp_packet, &video_header); if (generic_descriptor_state == kDropPacket) return; // Color space should only be transmitted in the last packet of a frame, // therefore, neglect it otherwise so that last_color_space_ is not reset by // mistake. if (video_header.is_last_packet_in_frame) { video_header.color_space = rtp_packet.GetExtension(); if (video_header.color_space || video_header.frame_type == VideoFrameType::kVideoFrameKey) { // Store color space since it's only transmitted when changed or for key // frames. Color space will be cleared if a key frame is transmitted // without color space information. last_color_space_ = video_header.color_space; } else if (last_color_space_) { video_header.color_space = last_color_space_; } } if (loss_notification_controller_) { if (rtp_packet.recovered()) { // TODO(bugs.webrtc.org/10336): Implement support for reordering. RTC_LOG(LS_INFO) << "LossNotificationController does not support reordering."; } else if (generic_descriptor_state == kNoGenericDescriptor) { RTC_LOG(LS_WARNING) << "LossNotificationController requires generic " "frame descriptor, but it is missing."; } else { if (video_header.is_first_packet_in_frame) { RTC_DCHECK(video_header.generic); LossNotificationController::FrameDetails frame; frame.is_keyframe = video_header.frame_type == VideoFrameType::kVideoFrameKey; frame.frame_id = video_header.generic->frame_id; frame.frame_dependencies = video_header.generic->dependencies; loss_notification_controller_->OnReceivedPacket( rtp_packet.SequenceNumber(), &frame); } else { loss_notification_controller_->OnReceivedPacket( rtp_packet.SequenceNumber(), nullptr); } } } if (nack_module_) { const bool is_keyframe = video_header.is_first_packet_in_frame && video_header.frame_type == VideoFrameType::kVideoFrameKey; packet->times_nacked = nack_module_->OnReceivedPacket( rtp_packet.SequenceNumber(), is_keyframe, rtp_packet.recovered()); } else { packet->times_nacked = -1; } if (codec_payload.size() == 0) { NotifyReceiverOfEmptyPacket(packet->seq_num); rtcp_feedback_buffer_.SendBufferedRtcpFeedback(); return; } if (packet->codec() == kVideoCodecH264) { // Only when we start to receive packets will we know what payload type // that will be used. When we know the payload type insert the correct // sps/pps into the tracker. if (packet->payload_type != last_payload_type_) { last_payload_type_ = packet->payload_type; InsertSpsPpsIntoTracker(packet->payload_type); } video_coding::H264SpsPpsTracker::FixedBitstream fixed = tracker_.CopyAndFixBitstream( rtc::MakeArrayView(codec_payload.cdata(), codec_payload.size()), &packet->video_header); switch (fixed.action) { case video_coding::H264SpsPpsTracker::kRequestKeyframe: rtcp_feedback_buffer_.RequestKeyFrame(); rtcp_feedback_buffer_.SendBufferedRtcpFeedback(); ABSL_FALLTHROUGH_INTENDED; case video_coding::H264SpsPpsTracker::kDrop: return; case video_coding::H264SpsPpsTracker::kInsert: packet->video_payload = std::move(fixed.bitstream); break; } } #ifndef DISABLE_H265 else if (packet->codec() == kVideoCodecH265) { // Only when we start to receive packets will we know what payload type // that will be used. When we know the payload type insert the correct // sps/pps into the tracker. if (packet->payload_type != last_payload_type_) { last_payload_type_ = packet->payload_type; InsertSpsPpsIntoTracker(packet->payload_type); } video_coding::H265VpsSpsPpsTracker::FixedBitstream fixed = h265_tracker_.CopyAndFixBitstream( rtc::MakeArrayView(codec_payload.cdata(), codec_payload.size()), &packet->video_header); switch (fixed.action) { case video_coding::H265VpsSpsPpsTracker::kRequestKeyframe: rtcp_feedback_buffer_.RequestKeyFrame(); rtcp_feedback_buffer_.SendBufferedRtcpFeedback(); ABSL_FALLTHROUGH_INTENDED; case video_coding::H265VpsSpsPpsTracker::kDrop: return; case video_coding::H265VpsSpsPpsTracker::kInsert: packet->video_payload = std::move(fixed.bitstream); break; } } #endif else { packet->video_payload = std::move(codec_payload); } rtcp_feedback_buffer_.SendBufferedRtcpFeedback(); frame_counter_.Add(packet->timestamp); OnInsertedPacket(packet_buffer_.InsertPacket(std::move(packet))); } void RtpVideoStreamReceiver2::OnRecoveredPacket(const uint8_t* rtp_packet, size_t rtp_packet_length) { RtpPacketReceived packet; if (!packet.Parse(rtp_packet, rtp_packet_length)) return; if (packet.PayloadType() == config_.rtp.red_payload_type) { RTC_LOG(LS_WARNING) << "Discarding recovered packet with RED encapsulation"; return; } packet.IdentifyExtensions(rtp_header_extensions_); packet.set_payload_type_frequency(kVideoPayloadTypeFrequency); // TODO(nisse): UlpfecReceiverImpl::ProcessReceivedFec passes both // original (decapsulated) media packets and recovered packets to // this callback. We need a way to distinguish, for setting // packet.recovered() correctly. Ideally, move RED decapsulation out // of the Ulpfec implementation. ReceivePacket(packet); } // This method handles both regular RTP packets and packets recovered // via FlexFEC. void RtpVideoStreamReceiver2::OnRtpPacket(const RtpPacketReceived& packet) { RTC_DCHECK_RUN_ON(&worker_task_checker_); if (!receiving_) { return; } if (!packet.recovered()) { // TODO(nisse): Exclude out-of-order packets? int64_t now_ms = clock_->TimeInMilliseconds(); last_received_rtp_timestamp_ = packet.Timestamp(); last_received_rtp_system_time_ms_ = now_ms; // Periodically log the RTP header of incoming packets. if (now_ms - last_packet_log_ms_ > kPacketLogIntervalMs) { rtc::StringBuilder ss; ss << "Packet received on SSRC: " << packet.Ssrc() << " with payload type: " << static_cast(packet.PayloadType()) << ", timestamp: " << packet.Timestamp() << ", sequence number: " << packet.SequenceNumber() << ", arrival time: " << packet.arrival_time_ms(); int32_t time_offset; if (packet.GetExtension(&time_offset)) { ss << ", toffset: " << time_offset; } uint32_t send_time; if (packet.GetExtension(&send_time)) { ss << ", abs send time: " << send_time; } RTC_LOG(LS_INFO) << ss.str(); last_packet_log_ms_ = now_ms; } } ReceivePacket(packet); // Update receive statistics after ReceivePacket. // Receive statistics will be reset if the payload type changes (make sure // that the first packet is included in the stats). if (!packet.recovered()) { rtp_receive_statistics_->OnRtpPacket(packet); } for (RtpPacketSinkInterface* secondary_sink : secondary_sinks_) { secondary_sink->OnRtpPacket(packet); } } void RtpVideoStreamReceiver2::RequestKeyFrame() { RTC_DCHECK_RUN_ON(&worker_task_checker_); // TODO(bugs.webrtc.org/10336): Allow the sender to ignore key frame requests // issued by anything other than the LossNotificationController if it (the // sender) is relying on LNTF alone. if (keyframe_request_sender_) { keyframe_request_sender_->RequestKeyFrame(); } else { rtp_rtcp_->SendPictureLossIndication(); } } void RtpVideoStreamReceiver2::SendLossNotification( uint16_t last_decoded_seq_num, uint16_t last_received_seq_num, bool decodability_flag, bool buffering_allowed) { RTC_DCHECK(config_.rtp.lntf.enabled); rtp_rtcp_->SendLossNotification(last_decoded_seq_num, last_received_seq_num, decodability_flag, buffering_allowed); } bool RtpVideoStreamReceiver2::IsUlpfecEnabled() const { return config_.rtp.ulpfec_payload_type != -1; } bool RtpVideoStreamReceiver2::IsRetransmissionsEnabled() const { return config_.rtp.nack.rtp_history_ms > 0; } void RtpVideoStreamReceiver2::RequestPacketRetransmit( const std::vector& sequence_numbers) { RTC_DCHECK_RUN_ON(&worker_task_checker_); rtp_rtcp_->SendNack(sequence_numbers); } bool RtpVideoStreamReceiver2::IsDecryptable() const { RTC_DCHECK_RUN_ON(&worker_task_checker_); return frames_decryptable_; } void RtpVideoStreamReceiver2::OnInsertedPacket( video_coding::PacketBuffer::InsertResult result) { RTC_DCHECK_RUN_ON(&worker_task_checker_); video_coding::PacketBuffer::Packet* first_packet = nullptr; int max_nack_count; int64_t min_recv_time; int64_t max_recv_time; std::vector> payloads; RtpPacketInfos::vector_type packet_infos; bool frame_boundary = true; for (auto& packet : result.packets) { // PacketBuffer promisses frame boundaries are correctly set on each // packet. Document that assumption with the DCHECKs. RTC_DCHECK_EQ(frame_boundary, packet->is_first_packet_in_frame()); if (packet->is_first_packet_in_frame()) { first_packet = packet.get(); max_nack_count = packet->times_nacked; min_recv_time = packet->packet_info.receive_time_ms(); max_recv_time = packet->packet_info.receive_time_ms(); payloads.clear(); packet_infos.clear(); } else { max_nack_count = std::max(max_nack_count, packet->times_nacked); min_recv_time = std::min(min_recv_time, packet->packet_info.receive_time_ms()); max_recv_time = std::max(max_recv_time, packet->packet_info.receive_time_ms()); } payloads.emplace_back(packet->video_payload); packet_infos.push_back(packet->packet_info); frame_boundary = packet->is_last_packet_in_frame(); if (packet->is_last_packet_in_frame()) { auto depacketizer_it = payload_type_map_.find(first_packet->payload_type); RTC_CHECK(depacketizer_it != payload_type_map_.end()); rtc::scoped_refptr bitstream = depacketizer_it->second->AssembleFrame(payloads); if (!bitstream) { // Failed to assemble a frame. Discard and continue. continue; } const video_coding::PacketBuffer::Packet& last_packet = *packet; OnAssembledFrame(std::make_unique( first_packet->seq_num, // last_packet.seq_num, // last_packet.marker_bit, // max_nack_count, // min_recv_time, // max_recv_time, // first_packet->timestamp, // first_packet->ntp_time_ms, // last_packet.video_header.video_timing, // first_packet->payload_type, // first_packet->codec(), // last_packet.video_header.rotation, // last_packet.video_header.content_type, // first_packet->video_header, // last_packet.video_header.color_space, // RtpPacketInfos(std::move(packet_infos)), // std::move(bitstream))); } } RTC_DCHECK(frame_boundary); if (result.buffer_cleared) { RequestKeyFrame(); } } void RtpVideoStreamReceiver2::OnAssembledFrame( std::unique_ptr frame) { RTC_DCHECK_RUN_ON(&worker_task_checker_); RTC_DCHECK(frame); const absl::optional& descriptor = frame->GetRtpVideoHeader().generic; if (loss_notification_controller_ && descriptor) { loss_notification_controller_->OnAssembledFrame( frame->first_seq_num(), descriptor->frame_id, absl::c_linear_search(descriptor->decode_target_indications, DecodeTargetIndication::kDiscardable), descriptor->dependencies); } // If frames arrive before a key frame, they would not be decodable. // In that case, request a key frame ASAP. if (!has_received_frame_) { if (frame->FrameType() != VideoFrameType::kVideoFrameKey) { // |loss_notification_controller_|, if present, would have already // requested a key frame when the first packet for the non-key frame // had arrived, so no need to replicate the request. if (!loss_notification_controller_) { RequestKeyFrame(); } } has_received_frame_ = true; } // Reset |reference_finder_| if |frame| is new and the codec have changed. if (current_codec_) { bool frame_is_newer = AheadOf(frame->Timestamp(), last_assembled_frame_rtp_timestamp_); if (frame->codec_type() != current_codec_) { if (frame_is_newer) { // When we reset the |reference_finder_| we don't want new picture ids // to overlap with old picture ids. To ensure that doesn't happen we // start from the |last_completed_picture_id_| and add an offset in case // of reordering. reference_finder_ = std::make_unique( this, last_completed_picture_id_ + std::numeric_limits::max()); current_codec_ = frame->codec_type(); } else { // Old frame from before the codec switch, discard it. return; } } if (frame_is_newer) { last_assembled_frame_rtp_timestamp_ = frame->Timestamp(); } } else { current_codec_ = frame->codec_type(); last_assembled_frame_rtp_timestamp_ = frame->Timestamp(); } if (buffered_frame_decryptor_ != nullptr) { buffered_frame_decryptor_->ManageEncryptedFrame(std::move(frame)); } else if (frame_transformer_delegate_) { frame_transformer_delegate_->TransformFrame(std::move(frame)); } else { reference_finder_->ManageFrame(std::move(frame)); } } void RtpVideoStreamReceiver2::OnCompleteFrame( std::unique_ptr frame) { RTC_DCHECK_RUN_ON(&worker_task_checker_); video_coding::RtpFrameObject* rtp_frame = static_cast(frame.get()); last_seq_num_for_pic_id_[rtp_frame->id.picture_id] = rtp_frame->last_seq_num(); last_completed_picture_id_ = std::max(last_completed_picture_id_, frame->id.picture_id); complete_frame_callback_->OnCompleteFrame(std::move(frame)); } void RtpVideoStreamReceiver2::OnDecryptedFrame( std::unique_ptr frame) { RTC_DCHECK_RUN_ON(&worker_task_checker_); reference_finder_->ManageFrame(std::move(frame)); } void RtpVideoStreamReceiver2::OnDecryptionStatusChange( FrameDecryptorInterface::Status status) { RTC_DCHECK_RUN_ON(&worker_task_checker_); // Called from BufferedFrameDecryptor::DecryptFrame. frames_decryptable_ = (status == FrameDecryptorInterface::Status::kOk) || (status == FrameDecryptorInterface::Status::kRecoverable); } void RtpVideoStreamReceiver2::SetFrameDecryptor( rtc::scoped_refptr frame_decryptor) { RTC_DCHECK_RUN_ON(&worker_task_checker_); if (buffered_frame_decryptor_ == nullptr) { buffered_frame_decryptor_ = std::make_unique(this, this); } buffered_frame_decryptor_->SetFrameDecryptor(std::move(frame_decryptor)); } void RtpVideoStreamReceiver2::SetDepacketizerToDecoderFrameTransformer( rtc::scoped_refptr frame_transformer) { RTC_DCHECK_RUN_ON(&worker_task_checker_); frame_transformer_delegate_ = new rtc::RefCountedObject( this, std::move(frame_transformer), rtc::Thread::Current(), config_.rtp.remote_ssrc); frame_transformer_delegate_->Init(); } void RtpVideoStreamReceiver2::UpdateRtt(int64_t max_rtt_ms) { RTC_DCHECK_RUN_ON(&worker_task_checker_); if (nack_module_) nack_module_->UpdateRtt(max_rtt_ms); } absl::optional RtpVideoStreamReceiver2::LastReceivedPacketMs() const { return packet_buffer_.LastReceivedPacketMs(); } absl::optional RtpVideoStreamReceiver2::LastReceivedKeyframePacketMs() const { return packet_buffer_.LastReceivedKeyframePacketMs(); } void RtpVideoStreamReceiver2::AddSecondarySink(RtpPacketSinkInterface* sink) { RTC_DCHECK_RUN_ON(&worker_task_checker_); RTC_DCHECK(!absl::c_linear_search(secondary_sinks_, sink)); secondary_sinks_.push_back(sink); } void RtpVideoStreamReceiver2::RemoveSecondarySink( const RtpPacketSinkInterface* sink) { RTC_DCHECK_RUN_ON(&worker_task_checker_); auto it = absl::c_find(secondary_sinks_, sink); if (it == secondary_sinks_.end()) { // We might be rolling-back a call whose setup failed mid-way. In such a // case, it's simpler to remove "everything" rather than remember what // has already been added. RTC_LOG(LS_WARNING) << "Removal of unknown sink."; return; } secondary_sinks_.erase(it); } void RtpVideoStreamReceiver2::ManageFrame( std::unique_ptr frame) { RTC_DCHECK_RUN_ON(&worker_task_checker_); reference_finder_->ManageFrame(std::move(frame)); } void RtpVideoStreamReceiver2::ReceivePacket(const RtpPacketReceived& packet) { RTC_DCHECK_RUN_ON(&worker_task_checker_); if (packet.payload_size() == 0) { // Padding or keep-alive packet. // TODO(nisse): Could drop empty packets earlier, but need to figure out how // they should be counted in stats. NotifyReceiverOfEmptyPacket(packet.SequenceNumber()); return; } if (packet.PayloadType() == config_.rtp.red_payload_type) { ParseAndHandleEncapsulatingHeader(packet); return; } const auto type_it = payload_type_map_.find(packet.PayloadType()); if (type_it == payload_type_map_.end()) { return; } absl::optional parsed_payload = type_it->second->Parse(packet.PayloadBuffer()); if (parsed_payload == absl::nullopt) { RTC_LOG(LS_WARNING) << "Failed parsing payload."; return; } OnReceivedPayloadData(std::move(parsed_payload->video_payload), packet, parsed_payload->video_header); } void RtpVideoStreamReceiver2::ParseAndHandleEncapsulatingHeader( const RtpPacketReceived& packet) { RTC_DCHECK_RUN_ON(&worker_task_checker_); if (packet.PayloadType() == config_.rtp.red_payload_type && packet.payload_size() > 0) { if (packet.payload()[0] == config_.rtp.ulpfec_payload_type) { // Notify video_receiver about received FEC packets to avoid NACKing these // packets. NotifyReceiverOfEmptyPacket(packet.SequenceNumber()); } if (!ulpfec_receiver_->AddReceivedRedPacket( packet, config_.rtp.ulpfec_payload_type)) { return; } ulpfec_receiver_->ProcessReceivedFec(); } } // In the case of a video stream without picture ids and no rtx the // RtpFrameReferenceFinder will need to know about padding to // correctly calculate frame references. void RtpVideoStreamReceiver2::NotifyReceiverOfEmptyPacket(uint16_t seq_num) { RTC_DCHECK_RUN_ON(&worker_task_checker_); reference_finder_->PaddingReceived(seq_num); OnInsertedPacket(packet_buffer_.InsertPadding(seq_num)); if (nack_module_) { nack_module_->OnReceivedPacket(seq_num, /* is_keyframe = */ false, /* is _recovered = */ false); } if (loss_notification_controller_) { // TODO(bugs.webrtc.org/10336): Handle empty packets. RTC_LOG(LS_WARNING) << "LossNotificationController does not expect empty packets."; } } bool RtpVideoStreamReceiver2::DeliverRtcp(const uint8_t* rtcp_packet, size_t rtcp_packet_length) { RTC_DCHECK_RUN_ON(&worker_task_checker_); if (!receiving_) { return false; } rtp_rtcp_->IncomingRtcpPacket(rtcp_packet, rtcp_packet_length); int64_t rtt = 0; rtp_rtcp_->RTT(config_.rtp.remote_ssrc, &rtt, nullptr, nullptr, nullptr); if (rtt == 0) { // Waiting for valid rtt. return true; } uint32_t ntp_secs = 0; uint32_t ntp_frac = 0; uint32_t rtp_timestamp = 0; uint32_t recieved_ntp_secs = 0; uint32_t recieved_ntp_frac = 0; if (rtp_rtcp_->RemoteNTP(&ntp_secs, &ntp_frac, &recieved_ntp_secs, &recieved_ntp_frac, &rtp_timestamp) != 0) { // Waiting for RTCP. return true; } NtpTime recieved_ntp(recieved_ntp_secs, recieved_ntp_frac); int64_t time_since_recieved = clock_->CurrentNtpInMilliseconds() - recieved_ntp.ToMs(); // Don't use old SRs to estimate time. if (time_since_recieved <= 1) { ntp_estimator_.UpdateRtcpTimestamp(rtt, ntp_secs, ntp_frac, rtp_timestamp); absl::optional remote_to_local_clock_offset_ms = ntp_estimator_.EstimateRemoteToLocalClockOffsetMs(); if (remote_to_local_clock_offset_ms.has_value()) { absolute_capture_time_receiver_.SetRemoteToLocalClockOffset( Int64MsToQ32x32(*remote_to_local_clock_offset_ms)); } } return true; } void RtpVideoStreamReceiver2::FrameContinuous(int64_t picture_id) { RTC_DCHECK_RUN_ON(&worker_task_checker_); if (!nack_module_) return; int seq_num = -1; auto seq_num_it = last_seq_num_for_pic_id_.find(picture_id); if (seq_num_it != last_seq_num_for_pic_id_.end()) seq_num = seq_num_it->second; if (seq_num != -1) nack_module_->ClearUpTo(seq_num); } void RtpVideoStreamReceiver2::FrameDecoded(int64_t picture_id) { RTC_DCHECK_RUN_ON(&worker_task_checker_); // Running on the decoder thread. int seq_num = -1; auto seq_num_it = last_seq_num_for_pic_id_.find(picture_id); if (seq_num_it != last_seq_num_for_pic_id_.end()) { seq_num = seq_num_it->second; last_seq_num_for_pic_id_.erase(last_seq_num_for_pic_id_.begin(), ++seq_num_it); } if (seq_num != -1) { packet_buffer_.ClearTo(seq_num); reference_finder_->ClearTo(seq_num); } } void RtpVideoStreamReceiver2::SignalNetworkState(NetworkState state) { RTC_DCHECK_RUN_ON(&worker_task_checker_); rtp_rtcp_->SetRTCPStatus(state == kNetworkUp ? config_.rtp.rtcp_mode : RtcpMode::kOff); } void RtpVideoStreamReceiver2::StartReceive() { RTC_DCHECK_RUN_ON(&worker_task_checker_); receiving_ = true; } void RtpVideoStreamReceiver2::StopReceive() { RTC_DCHECK_RUN_ON(&worker_task_checker_); receiving_ = false; } void RtpVideoStreamReceiver2::UpdateHistograms() { FecPacketCounter counter = ulpfec_receiver_->GetPacketCounter(); if (counter.first_packet_time_ms == -1) return; int64_t elapsed_sec = (clock_->TimeInMilliseconds() - counter.first_packet_time_ms) / 1000; if (elapsed_sec < metrics::kMinRunTimeInSeconds) return; if (counter.num_packets > 0) { RTC_HISTOGRAM_PERCENTAGE( "WebRTC.Video.ReceivedFecPacketsInPercent", static_cast(counter.num_fec_packets * 100 / counter.num_packets)); } if (counter.num_fec_packets > 0) { RTC_HISTOGRAM_PERCENTAGE("WebRTC.Video.RecoveredMediaPacketsInPercentOfFec", static_cast(counter.num_recovered_packets * 100 / counter.num_fec_packets)); } if (config_.rtp.ulpfec_payload_type != -1) { RTC_HISTOGRAM_COUNTS_10000( "WebRTC.Video.FecBitrateReceivedInKbps", static_cast(counter.num_bytes * 8 / elapsed_sec / 1000)); } } void RtpVideoStreamReceiver2::InsertSpsPpsIntoTracker(uint8_t payload_type) { RTC_DCHECK_RUN_ON(&worker_task_checker_); auto codec_params_it = pt_codec_params_.find(payload_type); if (codec_params_it == pt_codec_params_.end()) return; RTC_LOG(LS_INFO) << "Found out of band supplied codec parameters for" " payload type: " << static_cast(payload_type); H264SpropParameterSets sprop_decoder; auto sprop_base64_it = codec_params_it->second.find(cricket::kH264FmtpSpropParameterSets); if (sprop_base64_it == codec_params_it->second.end()) return; if (!sprop_decoder.DecodeSprop(sprop_base64_it->second.c_str())) return; tracker_.InsertSpsPpsNalus(sprop_decoder.sps_nalu(), sprop_decoder.pps_nalu()); } } // namespace webrtc