/* * 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 "pc/rtc_stats_collector.h" #include #include #include #include #include #include "api/candidate.h" #include "api/media_stream_interface.h" #include "api/peer_connection_interface.h" #include "api/video/video_content_type.h" #include "media/base/media_channel.h" #include "p2p/base/p2p_constants.h" #include "p2p/base/port.h" #include "pc/peer_connection.h" #include "pc/rtc_stats_traversal.h" #include "pc/webrtc_sdp.h" #include "rtc_base/checks.h" #include "rtc_base/strings/string_builder.h" #include "rtc_base/time_utils.h" #include "rtc_base/trace_event.h" namespace webrtc { namespace { // TODO(https://crbug.com/webrtc/10656): Consider making IDs less predictable. std::string RTCCertificateIDFromFingerprint(const std::string& fingerprint) { return "RTCCertificate_" + fingerprint; } std::string RTCCodecStatsIDFromMidDirectionAndPayload(const std::string& mid, bool inbound, uint32_t payload_type) { char buf[1024]; rtc::SimpleStringBuilder sb(buf); sb << "RTCCodec_" << mid << (inbound ? "_Inbound_" : "_Outbound_") << payload_type; return sb.str(); } std::string RTCIceCandidatePairStatsIDFromConnectionInfo( const cricket::ConnectionInfo& info) { char buf[4096]; rtc::SimpleStringBuilder sb(buf); sb << "RTCIceCandidatePair_" << info.local_candidate.id() << "_" << info.remote_candidate.id(); return sb.str(); } const char kSender[] = "sender"; const char kReceiver[] = "receiver"; std::string RTCMediaStreamTrackStatsIDFromDirectionAndAttachment( const char* direction, int attachment_id) { char buf[1024]; rtc::SimpleStringBuilder sb(buf); sb << "RTCMediaStreamTrack_" << direction << "_" << attachment_id; return sb.str(); } std::string RTCTransportStatsIDFromTransportChannel( const std::string& transport_name, int channel_component) { char buf[1024]; rtc::SimpleStringBuilder sb(buf); sb << "RTCTransport_" << transport_name << "_" << channel_component; return sb.str(); } std::string RTCInboundRTPStreamStatsIDFromSSRC(bool audio, uint32_t ssrc) { char buf[1024]; rtc::SimpleStringBuilder sb(buf); sb << "RTCInboundRTP" << (audio ? "Audio" : "Video") << "Stream_" << ssrc; return sb.str(); } std::string RTCOutboundRTPStreamStatsIDFromSSRC(bool audio, uint32_t ssrc) { char buf[1024]; rtc::SimpleStringBuilder sb(buf); sb << "RTCOutboundRTP" << (audio ? "Audio" : "Video") << "Stream_" << ssrc; return sb.str(); } std::string RTCRemoteInboundRtpStreamStatsIdFromSourceSsrc( cricket::MediaType media_type, uint32_t source_ssrc) { char buf[1024]; rtc::SimpleStringBuilder sb(buf); sb << "RTCRemoteInboundRtp" << (media_type == cricket::MEDIA_TYPE_AUDIO ? "Audio" : "Video") << "Stream_" << source_ssrc; return sb.str(); } std::string RTCMediaSourceStatsIDFromKindAndAttachment( cricket::MediaType media_type, int attachment_id) { char buf[1024]; rtc::SimpleStringBuilder sb(buf); sb << "RTC" << (media_type == cricket::MEDIA_TYPE_AUDIO ? "Audio" : "Video") << "Source_" << attachment_id; return sb.str(); } const char* CandidateTypeToRTCIceCandidateType(const std::string& type) { if (type == cricket::LOCAL_PORT_TYPE) return RTCIceCandidateType::kHost; if (type == cricket::STUN_PORT_TYPE) return RTCIceCandidateType::kSrflx; if (type == cricket::PRFLX_PORT_TYPE) return RTCIceCandidateType::kPrflx; if (type == cricket::RELAY_PORT_TYPE) return RTCIceCandidateType::kRelay; RTC_NOTREACHED(); return nullptr; } const char* DataStateToRTCDataChannelState( DataChannelInterface::DataState state) { switch (state) { case DataChannelInterface::kConnecting: return RTCDataChannelState::kConnecting; case DataChannelInterface::kOpen: return RTCDataChannelState::kOpen; case DataChannelInterface::kClosing: return RTCDataChannelState::kClosing; case DataChannelInterface::kClosed: return RTCDataChannelState::kClosed; default: RTC_NOTREACHED(); return nullptr; } } const char* IceCandidatePairStateToRTCStatsIceCandidatePairState( cricket::IceCandidatePairState state) { switch (state) { case cricket::IceCandidatePairState::WAITING: return RTCStatsIceCandidatePairState::kWaiting; case cricket::IceCandidatePairState::IN_PROGRESS: return RTCStatsIceCandidatePairState::kInProgress; case cricket::IceCandidatePairState::SUCCEEDED: return RTCStatsIceCandidatePairState::kSucceeded; case cricket::IceCandidatePairState::FAILED: return RTCStatsIceCandidatePairState::kFailed; default: RTC_NOTREACHED(); return nullptr; } } const char* DtlsTransportStateToRTCDtlsTransportState( cricket::DtlsTransportState state) { switch (state) { case cricket::DTLS_TRANSPORT_NEW: return RTCDtlsTransportState::kNew; case cricket::DTLS_TRANSPORT_CONNECTING: return RTCDtlsTransportState::kConnecting; case cricket::DTLS_TRANSPORT_CONNECTED: return RTCDtlsTransportState::kConnected; case cricket::DTLS_TRANSPORT_CLOSED: return RTCDtlsTransportState::kClosed; case cricket::DTLS_TRANSPORT_FAILED: return RTCDtlsTransportState::kFailed; default: RTC_NOTREACHED(); return nullptr; } } const char* NetworkAdapterTypeToStatsType(rtc::AdapterType type) { switch (type) { case rtc::ADAPTER_TYPE_CELLULAR: case rtc::ADAPTER_TYPE_CELLULAR_2G: case rtc::ADAPTER_TYPE_CELLULAR_3G: case rtc::ADAPTER_TYPE_CELLULAR_4G: case rtc::ADAPTER_TYPE_CELLULAR_5G: return RTCNetworkType::kCellular; case rtc::ADAPTER_TYPE_ETHERNET: return RTCNetworkType::kEthernet; case rtc::ADAPTER_TYPE_WIFI: return RTCNetworkType::kWifi; case rtc::ADAPTER_TYPE_VPN: return RTCNetworkType::kVpn; case rtc::ADAPTER_TYPE_UNKNOWN: case rtc::ADAPTER_TYPE_LOOPBACK: case rtc::ADAPTER_TYPE_ANY: return RTCNetworkType::kUnknown; } RTC_NOTREACHED(); return nullptr; } const char* QualityLimitationReasonToRTCQualityLimitationReason( QualityLimitationReason reason) { switch (reason) { case QualityLimitationReason::kNone: return RTCQualityLimitationReason::kNone; case QualityLimitationReason::kCpu: return RTCQualityLimitationReason::kCpu; case QualityLimitationReason::kBandwidth: return RTCQualityLimitationReason::kBandwidth; case QualityLimitationReason::kOther: return RTCQualityLimitationReason::kOther; } RTC_CHECK_NOTREACHED(); } double DoubleAudioLevelFromIntAudioLevel(int audio_level) { RTC_DCHECK_GE(audio_level, 0); RTC_DCHECK_LE(audio_level, 32767); return audio_level / 32767.0; } std::unique_ptr CodecStatsFromRtpCodecParameters( uint64_t timestamp_us, const std::string& mid, const std::string& transport_id, bool inbound, const RtpCodecParameters& codec_params) { RTC_DCHECK_GE(codec_params.payload_type, 0); RTC_DCHECK_LE(codec_params.payload_type, 127); RTC_DCHECK(codec_params.clock_rate); uint32_t payload_type = static_cast(codec_params.payload_type); std::unique_ptr codec_stats(new RTCCodecStats( RTCCodecStatsIDFromMidDirectionAndPayload(mid, inbound, payload_type), timestamp_us)); codec_stats->payload_type = payload_type; codec_stats->mime_type = codec_params.mime_type(); if (codec_params.clock_rate) { codec_stats->clock_rate = static_cast(*codec_params.clock_rate); } if (codec_params.num_channels) { codec_stats->channels = *codec_params.num_channels; } rtc::StringBuilder fmtp; if (WriteFmtpParameters(codec_params.parameters, &fmtp)) { codec_stats->sdp_fmtp_line = fmtp.Release(); } codec_stats->transport_id = transport_id; return codec_stats; } void SetMediaStreamTrackStatsFromMediaStreamTrackInterface( const MediaStreamTrackInterface& track, RTCMediaStreamTrackStats* track_stats) { track_stats->track_identifier = track.id(); track_stats->ended = (track.state() == MediaStreamTrackInterface::kEnded); } // Provides the media independent counters (both audio and video). void SetInboundRTPStreamStatsFromMediaReceiverInfo( const cricket::MediaReceiverInfo& media_receiver_info, RTCInboundRTPStreamStats* inbound_stats) { RTC_DCHECK(inbound_stats); inbound_stats->ssrc = media_receiver_info.ssrc(); // TODO(hbos): Support the remote case. https://crbug.com/657855 inbound_stats->is_remote = false; inbound_stats->packets_received = static_cast(media_receiver_info.packets_rcvd); inbound_stats->bytes_received = static_cast(media_receiver_info.payload_bytes_rcvd); inbound_stats->header_bytes_received = static_cast(media_receiver_info.header_and_padding_bytes_rcvd); inbound_stats->packets_lost = static_cast(media_receiver_info.packets_lost); } void SetInboundRTPStreamStatsFromVoiceReceiverInfo( const std::string& mid, const cricket::VoiceReceiverInfo& voice_receiver_info, RTCInboundRTPStreamStats* inbound_audio) { SetInboundRTPStreamStatsFromMediaReceiverInfo(voice_receiver_info, inbound_audio); inbound_audio->media_type = "audio"; inbound_audio->kind = "audio"; if (voice_receiver_info.codec_payload_type) { inbound_audio->codec_id = RTCCodecStatsIDFromMidDirectionAndPayload( mid, true, *voice_receiver_info.codec_payload_type); } inbound_audio->jitter = static_cast(voice_receiver_info.jitter_ms) / rtc::kNumMillisecsPerSec; inbound_audio->jitter_buffer_delay = voice_receiver_info.jitter_buffer_delay_seconds; inbound_audio->jitter_buffer_emitted_count = voice_receiver_info.jitter_buffer_emitted_count; inbound_audio->total_samples_received = voice_receiver_info.total_samples_received; inbound_audio->concealed_samples = voice_receiver_info.concealed_samples; inbound_audio->silent_concealed_samples = voice_receiver_info.silent_concealed_samples; inbound_audio->concealment_events = voice_receiver_info.concealment_events; inbound_audio->inserted_samples_for_deceleration = voice_receiver_info.inserted_samples_for_deceleration; inbound_audio->removed_samples_for_acceleration = voice_receiver_info.removed_samples_for_acceleration; if (voice_receiver_info.audio_level >= 0) { inbound_audio->audio_level = DoubleAudioLevelFromIntAudioLevel(voice_receiver_info.audio_level); } inbound_audio->total_audio_energy = voice_receiver_info.total_output_energy; inbound_audio->total_samples_duration = voice_receiver_info.total_output_duration; // |fir_count|, |pli_count| and |sli_count| are only valid for video and are // purposefully left undefined for audio. if (voice_receiver_info.last_packet_received_timestamp_ms) { inbound_audio->last_packet_received_timestamp = static_cast( *voice_receiver_info.last_packet_received_timestamp_ms) / rtc::kNumMillisecsPerSec; } if (voice_receiver_info.estimated_playout_ntp_timestamp_ms) { inbound_audio->estimated_playout_timestamp = static_cast( *voice_receiver_info.estimated_playout_ntp_timestamp_ms); } inbound_audio->fec_packets_received = voice_receiver_info.fec_packets_received; inbound_audio->fec_packets_discarded = voice_receiver_info.fec_packets_discarded; } void SetInboundRTPStreamStatsFromVideoReceiverInfo( const std::string& mid, const cricket::VideoReceiverInfo& video_receiver_info, RTCInboundRTPStreamStats* inbound_video) { SetInboundRTPStreamStatsFromMediaReceiverInfo(video_receiver_info, inbound_video); inbound_video->media_type = "video"; inbound_video->kind = "video"; if (video_receiver_info.codec_payload_type) { inbound_video->codec_id = RTCCodecStatsIDFromMidDirectionAndPayload( mid, true, *video_receiver_info.codec_payload_type); } inbound_video->fir_count = static_cast(video_receiver_info.firs_sent); inbound_video->pli_count = static_cast(video_receiver_info.plis_sent); inbound_video->nack_count = static_cast(video_receiver_info.nacks_sent); inbound_video->frames_received = video_receiver_info.frames_received; inbound_video->frames_decoded = video_receiver_info.frames_decoded; inbound_video->frames_dropped = video_receiver_info.frames_dropped; inbound_video->key_frames_decoded = video_receiver_info.key_frames_decoded; if (video_receiver_info.frame_width > 0) { inbound_video->frame_width = static_cast(video_receiver_info.frame_width); } if (video_receiver_info.frame_height > 0) { inbound_video->frame_height = static_cast(video_receiver_info.frame_height); } if (video_receiver_info.framerate_rcvd > 0) { inbound_video->frames_per_second = video_receiver_info.framerate_rcvd; } if (video_receiver_info.qp_sum) inbound_video->qp_sum = *video_receiver_info.qp_sum; inbound_video->total_decode_time = static_cast(video_receiver_info.total_decode_time_ms) / rtc::kNumMillisecsPerSec; inbound_video->total_inter_frame_delay = video_receiver_info.total_inter_frame_delay; inbound_video->total_squared_inter_frame_delay = video_receiver_info.total_squared_inter_frame_delay; if (video_receiver_info.last_packet_received_timestamp_ms) { inbound_video->last_packet_received_timestamp = static_cast( *video_receiver_info.last_packet_received_timestamp_ms) / rtc::kNumMillisecsPerSec; } if (video_receiver_info.estimated_playout_ntp_timestamp_ms) { inbound_video->estimated_playout_timestamp = static_cast( *video_receiver_info.estimated_playout_ntp_timestamp_ms); } // TODO(https://crbug.com/webrtc/10529): When info's |content_info| is // optional, support the "unspecified" value. if (video_receiver_info.content_type == VideoContentType::SCREENSHARE) inbound_video->content_type = RTCContentType::kScreenshare; if (!video_receiver_info.decoder_implementation_name.empty()) { inbound_video->decoder_implementation = video_receiver_info.decoder_implementation_name; } } // Provides the media independent counters (both audio and video). void SetOutboundRTPStreamStatsFromMediaSenderInfo( const cricket::MediaSenderInfo& media_sender_info, RTCOutboundRTPStreamStats* outbound_stats) { RTC_DCHECK(outbound_stats); outbound_stats->ssrc = media_sender_info.ssrc(); // TODO(hbos): Support the remote case. https://crbug.com/657856 outbound_stats->is_remote = false; outbound_stats->packets_sent = static_cast(media_sender_info.packets_sent); outbound_stats->retransmitted_packets_sent = media_sender_info.retransmitted_packets_sent; outbound_stats->bytes_sent = static_cast(media_sender_info.payload_bytes_sent); outbound_stats->header_bytes_sent = static_cast(media_sender_info.header_and_padding_bytes_sent); outbound_stats->retransmitted_bytes_sent = media_sender_info.retransmitted_bytes_sent; } void SetOutboundRTPStreamStatsFromVoiceSenderInfo( const std::string& mid, const cricket::VoiceSenderInfo& voice_sender_info, RTCOutboundRTPStreamStats* outbound_audio) { SetOutboundRTPStreamStatsFromMediaSenderInfo(voice_sender_info, outbound_audio); outbound_audio->media_type = "audio"; outbound_audio->kind = "audio"; if (voice_sender_info.codec_payload_type) { outbound_audio->codec_id = RTCCodecStatsIDFromMidDirectionAndPayload( mid, false, *voice_sender_info.codec_payload_type); } // |fir_count|, |pli_count| and |sli_count| are only valid for video and are // purposefully left undefined for audio. } void SetOutboundRTPStreamStatsFromVideoSenderInfo( const std::string& mid, const cricket::VideoSenderInfo& video_sender_info, RTCOutboundRTPStreamStats* outbound_video) { SetOutboundRTPStreamStatsFromMediaSenderInfo(video_sender_info, outbound_video); outbound_video->media_type = "video"; outbound_video->kind = "video"; if (video_sender_info.codec_payload_type) { outbound_video->codec_id = RTCCodecStatsIDFromMidDirectionAndPayload( mid, false, *video_sender_info.codec_payload_type); } outbound_video->fir_count = static_cast(video_sender_info.firs_rcvd); outbound_video->pli_count = static_cast(video_sender_info.plis_rcvd); outbound_video->nack_count = static_cast(video_sender_info.nacks_rcvd); if (video_sender_info.qp_sum) outbound_video->qp_sum = *video_sender_info.qp_sum; outbound_video->frames_encoded = video_sender_info.frames_encoded; outbound_video->key_frames_encoded = video_sender_info.key_frames_encoded; outbound_video->total_encode_time = static_cast(video_sender_info.total_encode_time_ms) / rtc::kNumMillisecsPerSec; outbound_video->total_encoded_bytes_target = video_sender_info.total_encoded_bytes_target; if (video_sender_info.send_frame_width > 0) { outbound_video->frame_width = static_cast(video_sender_info.send_frame_width); } if (video_sender_info.send_frame_height > 0) { outbound_video->frame_height = static_cast(video_sender_info.send_frame_height); } if (video_sender_info.framerate_sent > 0) { outbound_video->frames_per_second = video_sender_info.framerate_sent; } outbound_video->frames_sent = video_sender_info.frames_sent; outbound_video->huge_frames_sent = video_sender_info.huge_frames_sent; outbound_video->total_packet_send_delay = static_cast(video_sender_info.total_packet_send_delay_ms) / rtc::kNumMillisecsPerSec; outbound_video->quality_limitation_reason = QualityLimitationReasonToRTCQualityLimitationReason( video_sender_info.quality_limitation_reason); outbound_video->quality_limitation_resolution_changes = video_sender_info.quality_limitation_resolution_changes; // TODO(https://crbug.com/webrtc/10529): When info's |content_info| is // optional, support the "unspecified" value. if (video_sender_info.content_type == VideoContentType::SCREENSHARE) outbound_video->content_type = RTCContentType::kScreenshare; if (!video_sender_info.encoder_implementation_name.empty()) { outbound_video->encoder_implementation = video_sender_info.encoder_implementation_name; } if (video_sender_info.rid) { outbound_video->rid = *video_sender_info.rid; } } std::unique_ptr ProduceRemoteInboundRtpStreamStatsFromReportBlockData( const ReportBlockData& report_block_data, cricket::MediaType media_type, const std::map& outbound_rtps, const RTCStatsReport& report) { const auto& report_block = report_block_data.report_block(); // RTCStats' timestamp generally refers to when the metric was sampled, but // for "remote-[outbound/inbound]-rtp" it refers to the local time when the // Report Block was received. auto remote_inbound = std::make_unique( RTCRemoteInboundRtpStreamStatsIdFromSourceSsrc(media_type, report_block.source_ssrc), /*timestamp=*/report_block_data.report_block_timestamp_utc_us()); remote_inbound->ssrc = report_block.source_ssrc; remote_inbound->kind = media_type == cricket::MEDIA_TYPE_AUDIO ? "audio" : "video"; remote_inbound->packets_lost = report_block.packets_lost; remote_inbound->round_trip_time = static_cast(report_block_data.last_rtt_ms()) / rtc::kNumMillisecsPerSec; std::string local_id = RTCOutboundRTPStreamStatsIDFromSSRC( media_type == cricket::MEDIA_TYPE_AUDIO, report_block.source_ssrc); // Look up local stat from |outbound_rtps| where the pointers are non-const. auto local_id_it = outbound_rtps.find(local_id); if (local_id_it != outbound_rtps.end()) { remote_inbound->local_id = local_id; auto& outbound_rtp = *local_id_it->second; outbound_rtp.remote_id = remote_inbound->id(); // The RTP/RTCP transport is obtained from the // RTCOutboundRtpStreamStats's transport. const auto* transport_from_id = outbound_rtp.transport_id.is_defined() ? report.Get(*outbound_rtp.transport_id) : nullptr; if (transport_from_id) { const auto& transport = transport_from_id->cast_to(); // If RTP and RTCP are not multiplexed, there is a separate RTCP // transport paired with the RTP transport, otherwise the same // transport is used for RTCP and RTP. remote_inbound->transport_id = transport.rtcp_transport_stats_id.is_defined() ? *transport.rtcp_transport_stats_id : *outbound_rtp.transport_id; } // We're assuming the same codec is used on both ends. However if the // codec is switched out on the fly we may have received a Report Block // based on the previous codec and there is no way to tell which point in // time the codec changed for the remote end. const auto* codec_from_id = outbound_rtp.codec_id.is_defined() ? report.Get(*outbound_rtp.codec_id) : nullptr; if (codec_from_id) { remote_inbound->codec_id = *outbound_rtp.codec_id; const auto& codec = codec_from_id->cast_to(); if (codec.clock_rate.is_defined()) { // The Report Block jitter is expressed in RTP timestamp units // (https://tools.ietf.org/html/rfc3550#section-6.4.1). To convert this // to seconds we divide by the codec's clock rate. remote_inbound->jitter = static_cast(report_block.jitter) / *codec.clock_rate; } } } return remote_inbound; } void ProduceCertificateStatsFromSSLCertificateStats( int64_t timestamp_us, const rtc::SSLCertificateStats& certificate_stats, RTCStatsReport* report) { RTCCertificateStats* prev_certificate_stats = nullptr; for (const rtc::SSLCertificateStats* s = &certificate_stats; s; s = s->issuer.get()) { std::string certificate_stats_id = RTCCertificateIDFromFingerprint(s->fingerprint); // It is possible for the same certificate to show up multiple times, e.g. // if local and remote side use the same certificate in a loopback call. // If the report already contains stats for this certificate, skip it. if (report->Get(certificate_stats_id)) { RTC_DCHECK_EQ(s, &certificate_stats); break; } RTCCertificateStats* certificate_stats = new RTCCertificateStats(certificate_stats_id, timestamp_us); certificate_stats->fingerprint = s->fingerprint; certificate_stats->fingerprint_algorithm = s->fingerprint_algorithm; certificate_stats->base64_certificate = s->base64_certificate; if (prev_certificate_stats) prev_certificate_stats->issuer_certificate_id = certificate_stats->id(); report->AddStats(std::unique_ptr(certificate_stats)); prev_certificate_stats = certificate_stats; } } const std::string& ProduceIceCandidateStats(int64_t timestamp_us, const cricket::Candidate& candidate, bool is_local, const std::string& transport_id, RTCStatsReport* report) { const std::string& id = "RTCIceCandidate_" + candidate.id(); const RTCStats* stats = report->Get(id); if (!stats) { std::unique_ptr candidate_stats; if (is_local) candidate_stats.reset(new RTCLocalIceCandidateStats(id, timestamp_us)); else candidate_stats.reset(new RTCRemoteIceCandidateStats(id, timestamp_us)); candidate_stats->transport_id = transport_id; if (is_local) { candidate_stats->network_type = NetworkAdapterTypeToStatsType(candidate.network_type()); if (candidate.type() == cricket::RELAY_PORT_TYPE) { std::string relay_protocol = candidate.relay_protocol(); RTC_DCHECK(relay_protocol.compare("udp") == 0 || relay_protocol.compare("tcp") == 0 || relay_protocol.compare("tls") == 0); candidate_stats->relay_protocol = relay_protocol; } } else { // We don't expect to know the adapter type of remote candidates. RTC_DCHECK_EQ(rtc::ADAPTER_TYPE_UNKNOWN, candidate.network_type()); } candidate_stats->ip = candidate.address().ipaddr().ToString(); candidate_stats->port = static_cast(candidate.address().port()); candidate_stats->protocol = candidate.protocol(); candidate_stats->candidate_type = CandidateTypeToRTCIceCandidateType(candidate.type()); candidate_stats->priority = static_cast(candidate.priority()); stats = candidate_stats.get(); report->AddStats(std::move(candidate_stats)); } RTC_DCHECK_EQ(stats->type(), is_local ? RTCLocalIceCandidateStats::kType : RTCRemoteIceCandidateStats::kType); return stats->id(); } std::unique_ptr ProduceMediaStreamTrackStatsFromVoiceSenderInfo( int64_t timestamp_us, const AudioTrackInterface& audio_track, const cricket::VoiceSenderInfo& voice_sender_info, int attachment_id) { std::unique_ptr audio_track_stats( new RTCMediaStreamTrackStats( RTCMediaStreamTrackStatsIDFromDirectionAndAttachment(kSender, attachment_id), timestamp_us, RTCMediaStreamTrackKind::kAudio)); SetMediaStreamTrackStatsFromMediaStreamTrackInterface( audio_track, audio_track_stats.get()); audio_track_stats->media_source_id = RTCMediaSourceStatsIDFromKindAndAttachment(cricket::MEDIA_TYPE_AUDIO, attachment_id); audio_track_stats->remote_source = false; audio_track_stats->detached = false; if (voice_sender_info.apm_statistics.echo_return_loss) { audio_track_stats->echo_return_loss = *voice_sender_info.apm_statistics.echo_return_loss; } if (voice_sender_info.apm_statistics.echo_return_loss_enhancement) { audio_track_stats->echo_return_loss_enhancement = *voice_sender_info.apm_statistics.echo_return_loss_enhancement; } return audio_track_stats; } std::unique_ptr ProduceMediaStreamTrackStatsFromVoiceReceiverInfo( int64_t timestamp_us, const AudioTrackInterface& audio_track, const cricket::VoiceReceiverInfo& voice_receiver_info, int attachment_id) { // Since receiver tracks can't be reattached, we use the SSRC as // an attachment identifier. std::unique_ptr audio_track_stats( new RTCMediaStreamTrackStats( RTCMediaStreamTrackStatsIDFromDirectionAndAttachment(kReceiver, attachment_id), timestamp_us, RTCMediaStreamTrackKind::kAudio)); SetMediaStreamTrackStatsFromMediaStreamTrackInterface( audio_track, audio_track_stats.get()); audio_track_stats->remote_source = true; audio_track_stats->detached = false; if (voice_receiver_info.audio_level >= 0) { audio_track_stats->audio_level = DoubleAudioLevelFromIntAudioLevel(voice_receiver_info.audio_level); } audio_track_stats->jitter_buffer_delay = voice_receiver_info.jitter_buffer_delay_seconds; audio_track_stats->jitter_buffer_emitted_count = voice_receiver_info.jitter_buffer_emitted_count; audio_track_stats->inserted_samples_for_deceleration = voice_receiver_info.inserted_samples_for_deceleration; audio_track_stats->removed_samples_for_acceleration = voice_receiver_info.removed_samples_for_acceleration; audio_track_stats->total_audio_energy = voice_receiver_info.total_output_energy; audio_track_stats->total_samples_received = voice_receiver_info.total_samples_received; audio_track_stats->total_samples_duration = voice_receiver_info.total_output_duration; audio_track_stats->concealed_samples = voice_receiver_info.concealed_samples; audio_track_stats->silent_concealed_samples = voice_receiver_info.silent_concealed_samples; audio_track_stats->concealment_events = voice_receiver_info.concealment_events; audio_track_stats->jitter_buffer_flushes = voice_receiver_info.jitter_buffer_flushes; audio_track_stats->delayed_packet_outage_samples = voice_receiver_info.delayed_packet_outage_samples; audio_track_stats->relative_packet_arrival_delay = voice_receiver_info.relative_packet_arrival_delay_seconds; audio_track_stats->jitter_buffer_target_delay = voice_receiver_info.jitter_buffer_target_delay_seconds; audio_track_stats->interruption_count = voice_receiver_info.interruption_count >= 0 ? voice_receiver_info.interruption_count : 0; audio_track_stats->total_interruption_duration = static_cast(voice_receiver_info.total_interruption_duration_ms) / rtc::kNumMillisecsPerSec; return audio_track_stats; } std::unique_ptr ProduceMediaStreamTrackStatsFromVideoSenderInfo( int64_t timestamp_us, const VideoTrackInterface& video_track, const cricket::VideoSenderInfo& video_sender_info, int attachment_id) { std::unique_ptr video_track_stats( new RTCMediaStreamTrackStats( RTCMediaStreamTrackStatsIDFromDirectionAndAttachment(kSender, attachment_id), timestamp_us, RTCMediaStreamTrackKind::kVideo)); SetMediaStreamTrackStatsFromMediaStreamTrackInterface( video_track, video_track_stats.get()); video_track_stats->media_source_id = RTCMediaSourceStatsIDFromKindAndAttachment(cricket::MEDIA_TYPE_VIDEO, attachment_id); video_track_stats->remote_source = false; video_track_stats->detached = false; video_track_stats->frame_width = static_cast(video_sender_info.send_frame_width); video_track_stats->frame_height = static_cast(video_sender_info.send_frame_height); // TODO(hbos): Will reduce this by frames dropped due to congestion control // when available. https://crbug.com/659137 video_track_stats->frames_sent = video_sender_info.frames_encoded; video_track_stats->huge_frames_sent = video_sender_info.huge_frames_sent; return video_track_stats; } std::unique_ptr ProduceMediaStreamTrackStatsFromVideoReceiverInfo( int64_t timestamp_us, const VideoTrackInterface& video_track, const cricket::VideoReceiverInfo& video_receiver_info, int attachment_id) { std::unique_ptr video_track_stats( new RTCMediaStreamTrackStats( RTCMediaStreamTrackStatsIDFromDirectionAndAttachment(kReceiver, attachment_id), timestamp_us, RTCMediaStreamTrackKind::kVideo)); SetMediaStreamTrackStatsFromMediaStreamTrackInterface( video_track, video_track_stats.get()); video_track_stats->remote_source = true; video_track_stats->detached = false; if (video_receiver_info.frame_width > 0 && video_receiver_info.frame_height > 0) { video_track_stats->frame_width = static_cast(video_receiver_info.frame_width); video_track_stats->frame_height = static_cast(video_receiver_info.frame_height); } video_track_stats->jitter_buffer_delay = video_receiver_info.jitter_buffer_delay_seconds; video_track_stats->jitter_buffer_emitted_count = video_receiver_info.jitter_buffer_emitted_count; video_track_stats->frames_received = video_receiver_info.frames_received; // TODO(hbos): When we support receiving simulcast, this should be the total // number of frames correctly decoded, independent of which SSRC it was // received from. Since we don't support that, this is correct and is the same // value as "RTCInboundRTPStreamStats.framesDecoded". https://crbug.com/659137 video_track_stats->frames_decoded = video_receiver_info.frames_decoded; video_track_stats->frames_dropped = video_receiver_info.frames_dropped; video_track_stats->freeze_count = video_receiver_info.freeze_count; video_track_stats->pause_count = video_receiver_info.pause_count; video_track_stats->total_freezes_duration = static_cast(video_receiver_info.total_freezes_duration_ms) / rtc::kNumMillisecsPerSec; video_track_stats->total_pauses_duration = static_cast(video_receiver_info.total_pauses_duration_ms) / rtc::kNumMillisecsPerSec; video_track_stats->total_frames_duration = static_cast(video_receiver_info.total_frames_duration_ms) / rtc::kNumMillisecsPerSec; video_track_stats->sum_squared_frame_durations = video_receiver_info.sum_squared_frame_durations; return video_track_stats; } void ProduceSenderMediaTrackStats( int64_t timestamp_us, const TrackMediaInfoMap& track_media_info_map, std::vector> senders, RTCStatsReport* report) { // This function iterates over the senders to generate outgoing track stats. // TODO(hbos): Return stats of detached tracks. We have to perform stats // gathering at the time of detachment to get accurate stats and timestamps. // https://crbug.com/659137 for (const auto& sender : senders) { if (sender->media_type() == cricket::MEDIA_TYPE_AUDIO) { AudioTrackInterface* track = static_cast(sender->track().get()); if (!track) continue; cricket::VoiceSenderInfo null_sender_info; const cricket::VoiceSenderInfo* voice_sender_info = &null_sender_info; // TODO(hta): Checking on ssrc is not proper. There should be a way // to see from a sender whether it's connected or not. // Related to https://crbug.com/8694 (using ssrc 0 to indicate "none") if (sender->ssrc() != 0) { // When pc.close is called, sender info is discarded, so // we generate zeroes instead. Bug: It should be retained. // https://crbug.com/807174 const cricket::VoiceSenderInfo* sender_info = track_media_info_map.GetVoiceSenderInfoBySsrc(sender->ssrc()); if (sender_info) { voice_sender_info = sender_info; } else { RTC_LOG(LS_INFO) << "RTCStatsCollector: No voice sender info for sender with ssrc " << sender->ssrc(); } } std::unique_ptr audio_track_stats = ProduceMediaStreamTrackStatsFromVoiceSenderInfo( timestamp_us, *track, *voice_sender_info, sender->AttachmentId()); report->AddStats(std::move(audio_track_stats)); } else if (sender->media_type() == cricket::MEDIA_TYPE_VIDEO) { VideoTrackInterface* track = static_cast(sender->track().get()); if (!track) continue; cricket::VideoSenderInfo null_sender_info; const cricket::VideoSenderInfo* video_sender_info = &null_sender_info; // TODO(hta): Check on state not ssrc when state is available // Related to https://bugs.webrtc.org/8694 (using ssrc 0 to indicate // "none") if (sender->ssrc() != 0) { // When pc.close is called, sender info is discarded, so // we generate zeroes instead. Bug: It should be retained. // https://crbug.com/807174 const cricket::VideoSenderInfo* sender_info = track_media_info_map.GetVideoSenderInfoBySsrc(sender->ssrc()); if (sender_info) { video_sender_info = sender_info; } else { RTC_LOG(LS_INFO) << "No video sender info for sender with ssrc " << sender->ssrc(); } } std::unique_ptr video_track_stats = ProduceMediaStreamTrackStatsFromVideoSenderInfo( timestamp_us, *track, *video_sender_info, sender->AttachmentId()); report->AddStats(std::move(video_track_stats)); } else { RTC_NOTREACHED(); } } } void ProduceReceiverMediaTrackStats( int64_t timestamp_us, const TrackMediaInfoMap& track_media_info_map, std::vector> receivers, RTCStatsReport* report) { // This function iterates over the receivers to find the remote tracks. for (const auto& receiver : receivers) { if (receiver->media_type() == cricket::MEDIA_TYPE_AUDIO) { AudioTrackInterface* track = static_cast(receiver->track().get()); const cricket::VoiceReceiverInfo* voice_receiver_info = track_media_info_map.GetVoiceReceiverInfo(*track); if (!voice_receiver_info) { continue; } std::unique_ptr audio_track_stats = ProduceMediaStreamTrackStatsFromVoiceReceiverInfo( timestamp_us, *track, *voice_receiver_info, receiver->AttachmentId()); report->AddStats(std::move(audio_track_stats)); } else if (receiver->media_type() == cricket::MEDIA_TYPE_VIDEO) { VideoTrackInterface* track = static_cast(receiver->track().get()); const cricket::VideoReceiverInfo* video_receiver_info = track_media_info_map.GetVideoReceiverInfo(*track); if (!video_receiver_info) { continue; } std::unique_ptr video_track_stats = ProduceMediaStreamTrackStatsFromVideoReceiverInfo( timestamp_us, *track, *video_receiver_info, receiver->AttachmentId()); report->AddStats(std::move(video_track_stats)); } else { RTC_NOTREACHED(); } } } rtc::scoped_refptr CreateReportFilteredBySelector( bool filter_by_sender_selector, rtc::scoped_refptr report, rtc::scoped_refptr sender_selector, rtc::scoped_refptr receiver_selector) { std::vector rtpstream_ids; if (filter_by_sender_selector) { // Filter mode: RTCStatsCollector::RequestInfo::kSenderSelector if (sender_selector) { // Find outbound-rtp(s) of the sender, i.e. the outbound-rtp(s) that // reference the sender stats. // Because we do not implement sender stats, we look at outbound-rtp(s) // that reference the track attachment stats for the sender instead. std::string track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment( kSender, sender_selector->AttachmentId()); for (const auto& stats : *report) { if (stats.type() != RTCOutboundRTPStreamStats::kType) continue; const auto& outbound_rtp = stats.cast_to(); if (outbound_rtp.track_id.is_defined() && *outbound_rtp.track_id == track_id) { rtpstream_ids.push_back(outbound_rtp.id()); } } } } else { // Filter mode: RTCStatsCollector::RequestInfo::kReceiverSelector if (receiver_selector) { // Find inbound-rtp(s) of the receiver, i.e. the inbound-rtp(s) that // reference the receiver stats. // Because we do not implement receiver stats, we look at inbound-rtp(s) // that reference the track attachment stats for the receiver instead. std::string track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment( kReceiver, receiver_selector->AttachmentId()); for (const auto& stats : *report) { if (stats.type() != RTCInboundRTPStreamStats::kType) continue; const auto& inbound_rtp = stats.cast_to(); if (inbound_rtp.track_id.is_defined() && *inbound_rtp.track_id == track_id) { rtpstream_ids.push_back(inbound_rtp.id()); } } } } if (rtpstream_ids.empty()) return RTCStatsReport::Create(report->timestamp_us()); return TakeReferencedStats(report->Copy(), rtpstream_ids); } } // namespace RTCStatsCollector::RequestInfo::RequestInfo( rtc::scoped_refptr callback) : RequestInfo(FilterMode::kAll, std::move(callback), nullptr, nullptr) {} RTCStatsCollector::RequestInfo::RequestInfo( rtc::scoped_refptr selector, rtc::scoped_refptr callback) : RequestInfo(FilterMode::kSenderSelector, std::move(callback), std::move(selector), nullptr) {} RTCStatsCollector::RequestInfo::RequestInfo( rtc::scoped_refptr selector, rtc::scoped_refptr callback) : RequestInfo(FilterMode::kReceiverSelector, std::move(callback), nullptr, std::move(selector)) {} RTCStatsCollector::RequestInfo::RequestInfo( RTCStatsCollector::RequestInfo::FilterMode filter_mode, rtc::scoped_refptr callback, rtc::scoped_refptr sender_selector, rtc::scoped_refptr receiver_selector) : filter_mode_(filter_mode), callback_(std::move(callback)), sender_selector_(std::move(sender_selector)), receiver_selector_(std::move(receiver_selector)) { RTC_DCHECK(callback_); RTC_DCHECK(!sender_selector_ || !receiver_selector_); } rtc::scoped_refptr RTCStatsCollector::Create( PeerConnectionInternal* pc, int64_t cache_lifetime_us) { return rtc::scoped_refptr( new rtc::RefCountedObject(pc, cache_lifetime_us)); } RTCStatsCollector::RTCStatsCollector(PeerConnectionInternal* pc, int64_t cache_lifetime_us) : pc_(pc), signaling_thread_(pc->signaling_thread()), worker_thread_(pc->worker_thread()), network_thread_(pc->network_thread()), num_pending_partial_reports_(0), partial_report_timestamp_us_(0), network_report_event_(true /* manual_reset */, true /* initially_signaled */), cache_timestamp_us_(0), cache_lifetime_us_(cache_lifetime_us) { RTC_DCHECK(pc_); RTC_DCHECK(signaling_thread_); RTC_DCHECK(worker_thread_); RTC_DCHECK(network_thread_); RTC_DCHECK_GE(cache_lifetime_us_, 0); pc_->SignalRtpDataChannelCreated().connect( this, &RTCStatsCollector::OnRtpDataChannelCreated); pc_->SignalSctpDataChannelCreated().connect( this, &RTCStatsCollector::OnSctpDataChannelCreated); } RTCStatsCollector::~RTCStatsCollector() { RTC_DCHECK_EQ(num_pending_partial_reports_, 0); } void RTCStatsCollector::GetStatsReport( rtc::scoped_refptr callback) { GetStatsReportInternal(RequestInfo(std::move(callback))); } void RTCStatsCollector::GetStatsReport( rtc::scoped_refptr selector, rtc::scoped_refptr callback) { GetStatsReportInternal(RequestInfo(std::move(selector), std::move(callback))); } void RTCStatsCollector::GetStatsReport( rtc::scoped_refptr selector, rtc::scoped_refptr callback) { GetStatsReportInternal(RequestInfo(std::move(selector), std::move(callback))); } void RTCStatsCollector::GetStatsReportInternal( RTCStatsCollector::RequestInfo request) { RTC_DCHECK(signaling_thread_->IsCurrent()); requests_.push_back(std::move(request)); // "Now" using a monotonically increasing timer. int64_t cache_now_us = rtc::TimeMicros(); if (cached_report_ && cache_now_us - cache_timestamp_us_ <= cache_lifetime_us_) { // We have a fresh cached report to deliver. Deliver asynchronously, since // the caller may not be expecting a synchronous callback, and it avoids // reentrancy problems. std::vector requests; requests.swap(requests_); signaling_thread_->PostTask( RTC_FROM_HERE, rtc::Bind(&RTCStatsCollector::DeliverCachedReport, this, cached_report_, std::move(requests))); } else if (!num_pending_partial_reports_) { // Only start gathering stats if we're not already gathering stats. In the // case of already gathering stats, |callback_| will be invoked when there // are no more pending partial reports. // "Now" using a system clock, relative to the UNIX epoch (Jan 1, 1970, // UTC), in microseconds. The system clock could be modified and is not // necessarily monotonically increasing. int64_t timestamp_us = rtc::TimeUTCMicros(); num_pending_partial_reports_ = 2; partial_report_timestamp_us_ = cache_now_us; // Prepare |transceiver_stats_infos_| and |call_stats_| for use in // |ProducePartialResultsOnNetworkThread| and // |ProducePartialResultsOnSignalingThread|. PrepareTransceiverStatsInfosAndCallStats_s_w(); // Prepare |transport_names_| for use in // |ProducePartialResultsOnNetworkThread|. transport_names_ = PrepareTransportNames_s(); // Don't touch |network_report_| on the signaling thread until // ProducePartialResultsOnNetworkThread() has signaled the // |network_report_event_|. network_report_event_.Reset(); network_thread_->PostTask( RTC_FROM_HERE, rtc::Bind(&RTCStatsCollector::ProducePartialResultsOnNetworkThread, this, timestamp_us)); ProducePartialResultsOnSignalingThread(timestamp_us); } } void RTCStatsCollector::ClearCachedStatsReport() { RTC_DCHECK(signaling_thread_->IsCurrent()); cached_report_ = nullptr; } void RTCStatsCollector::WaitForPendingRequest() { RTC_DCHECK(signaling_thread_->IsCurrent()); // If a request is pending, blocks until the |network_report_event_| is // signaled and then delivers the result. Otherwise this is a NO-OP. MergeNetworkReport_s(); } void RTCStatsCollector::ProducePartialResultsOnSignalingThread( int64_t timestamp_us) { RTC_DCHECK(signaling_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; partial_report_ = RTCStatsReport::Create(timestamp_us); ProducePartialResultsOnSignalingThreadImpl(timestamp_us, partial_report_.get()); // ProducePartialResultsOnSignalingThread() is running synchronously on the // signaling thread, so it is always the first partial result delivered on the // signaling thread. The request is not complete until MergeNetworkReport_s() // happens; we don't have to do anything here. RTC_DCHECK_GT(num_pending_partial_reports_, 1); --num_pending_partial_reports_; } void RTCStatsCollector::ProducePartialResultsOnSignalingThreadImpl( int64_t timestamp_us, RTCStatsReport* partial_report) { RTC_DCHECK(signaling_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; ProduceDataChannelStats_s(timestamp_us, partial_report); ProduceMediaStreamStats_s(timestamp_us, partial_report); ProduceMediaStreamTrackStats_s(timestamp_us, partial_report); ProduceMediaSourceStats_s(timestamp_us, partial_report); ProducePeerConnectionStats_s(timestamp_us, partial_report); } void RTCStatsCollector::ProducePartialResultsOnNetworkThread( int64_t timestamp_us) { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; // Touching |network_report_| on this thread is safe by this method because // |network_report_event_| is reset before this method is invoked. network_report_ = RTCStatsReport::Create(timestamp_us); std::map transport_stats_by_name = pc_->GetTransportStatsByNames(transport_names_); std::map transport_cert_stats = PrepareTransportCertificateStats_n(transport_stats_by_name); ProducePartialResultsOnNetworkThreadImpl( timestamp_us, transport_stats_by_name, transport_cert_stats, network_report_.get()); // Signal that it is now safe to touch |network_report_| on the signaling // thread, and post a task to merge it into the final results. network_report_event_.Set(); signaling_thread_->PostTask( RTC_FROM_HERE, rtc::Bind(&RTCStatsCollector::MergeNetworkReport_s, this)); } void RTCStatsCollector::ProducePartialResultsOnNetworkThreadImpl( int64_t timestamp_us, const std::map& transport_stats_by_name, const std::map& transport_cert_stats, RTCStatsReport* partial_report) { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; ProduceCertificateStats_n(timestamp_us, transport_cert_stats, partial_report); ProduceCodecStats_n(timestamp_us, transceiver_stats_infos_, partial_report); ProduceIceCandidateAndPairStats_n(timestamp_us, transport_stats_by_name, call_stats_, partial_report); ProduceTransportStats_n(timestamp_us, transport_stats_by_name, transport_cert_stats, partial_report); ProduceRTPStreamStats_n(timestamp_us, transceiver_stats_infos_, partial_report); } void RTCStatsCollector::MergeNetworkReport_s() { RTC_DCHECK(signaling_thread_->IsCurrent()); // The |network_report_event_| must be signaled for it to be safe to touch // |network_report_|. This is normally not blocking, but if // WaitForPendingRequest() is called while a request is pending, we might have // to wait until the network thread is done touching |network_report_|. network_report_event_.Wait(rtc::Event::kForever); if (!network_report_) { // Normally, MergeNetworkReport_s() is executed because it is posted from // the network thread. But if WaitForPendingRequest() is called while a // request is pending, an early call to MergeNetworkReport_s() is made, // merging the report and setting |network_report_| to null. If so, when the // previously posted MergeNetworkReport_s() is later executed, the report is // already null and nothing needs to be done here. return; } RTC_DCHECK_GT(num_pending_partial_reports_, 0); RTC_DCHECK(partial_report_); partial_report_->TakeMembersFrom(network_report_); network_report_ = nullptr; --num_pending_partial_reports_; // |network_report_| is currently the only partial report collected // asynchronously, so |num_pending_partial_reports_| must now be 0 and we are // ready to deliver the result. RTC_DCHECK_EQ(num_pending_partial_reports_, 0); cache_timestamp_us_ = partial_report_timestamp_us_; cached_report_ = partial_report_; partial_report_ = nullptr; transceiver_stats_infos_.clear(); // Trace WebRTC Stats when getStats is called on Javascript. // This allows access to WebRTC stats from trace logs. To enable them, // select the "webrtc_stats" category when recording traces. TRACE_EVENT_INSTANT1("webrtc_stats", "webrtc_stats", "report", cached_report_->ToJson()); // Deliver report and clear |requests_|. std::vector requests; requests.swap(requests_); DeliverCachedReport(cached_report_, std::move(requests)); } void RTCStatsCollector::DeliverCachedReport( rtc::scoped_refptr cached_report, std::vector requests) { RTC_DCHECK(signaling_thread_->IsCurrent()); RTC_DCHECK(!requests.empty()); RTC_DCHECK(cached_report); for (const RequestInfo& request : requests) { if (request.filter_mode() == RequestInfo::FilterMode::kAll) { request.callback()->OnStatsDelivered(cached_report); } else { bool filter_by_sender_selector; rtc::scoped_refptr sender_selector; rtc::scoped_refptr receiver_selector; if (request.filter_mode() == RequestInfo::FilterMode::kSenderSelector) { filter_by_sender_selector = true; sender_selector = request.sender_selector(); } else { RTC_DCHECK(request.filter_mode() == RequestInfo::FilterMode::kReceiverSelector); filter_by_sender_selector = false; receiver_selector = request.receiver_selector(); } request.callback()->OnStatsDelivered(CreateReportFilteredBySelector( filter_by_sender_selector, cached_report, sender_selector, receiver_selector)); } } } void RTCStatsCollector::ProduceCertificateStats_n( int64_t timestamp_us, const std::map& transport_cert_stats, RTCStatsReport* report) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const auto& transport_cert_stats_pair : transport_cert_stats) { if (transport_cert_stats_pair.second.local) { ProduceCertificateStatsFromSSLCertificateStats( timestamp_us, *transport_cert_stats_pair.second.local.get(), report); } if (transport_cert_stats_pair.second.remote) { ProduceCertificateStatsFromSSLCertificateStats( timestamp_us, *transport_cert_stats_pair.second.remote.get(), report); } } } void RTCStatsCollector::ProduceCodecStats_n( int64_t timestamp_us, const std::vector& transceiver_stats_infos, RTCStatsReport* report) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const auto& stats : transceiver_stats_infos) { if (!stats.mid) { continue; } std::string transport_id = RTCTransportStatsIDFromTransportChannel( *stats.transport_name, cricket::ICE_CANDIDATE_COMPONENT_RTP); const cricket::VoiceMediaInfo* voice_media_info = stats.track_media_info_map->voice_media_info(); const cricket::VideoMediaInfo* video_media_info = stats.track_media_info_map->video_media_info(); // Audio if (voice_media_info) { // Inbound for (const auto& pair : voice_media_info->receive_codecs) { report->AddStats(CodecStatsFromRtpCodecParameters( timestamp_us, *stats.mid, transport_id, true, pair.second)); } // Outbound for (const auto& pair : voice_media_info->send_codecs) { report->AddStats(CodecStatsFromRtpCodecParameters( timestamp_us, *stats.mid, transport_id, false, pair.second)); } } // Video if (video_media_info) { // Inbound for (const auto& pair : video_media_info->receive_codecs) { report->AddStats(CodecStatsFromRtpCodecParameters( timestamp_us, *stats.mid, transport_id, true, pair.second)); } // Outbound for (const auto& pair : video_media_info->send_codecs) { report->AddStats(CodecStatsFromRtpCodecParameters( timestamp_us, *stats.mid, transport_id, false, pair.second)); } } } } void RTCStatsCollector::ProduceDataChannelStats_s( int64_t timestamp_us, RTCStatsReport* report) const { RTC_DCHECK_RUN_ON(signaling_thread_); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; std::vector data_stats = pc_->GetDataChannelStats(); for (const auto& stats : data_stats) { std::unique_ptr data_channel_stats( new RTCDataChannelStats( "RTCDataChannel_" + rtc::ToString(stats.internal_id), timestamp_us)); data_channel_stats->label = std::move(stats.label); data_channel_stats->protocol = std::move(stats.protocol); data_channel_stats->data_channel_identifier = stats.id; data_channel_stats->state = DataStateToRTCDataChannelState(stats.state); data_channel_stats->messages_sent = stats.messages_sent; data_channel_stats->bytes_sent = stats.bytes_sent; data_channel_stats->messages_received = stats.messages_received; data_channel_stats->bytes_received = stats.bytes_received; report->AddStats(std::move(data_channel_stats)); } } void RTCStatsCollector::ProduceIceCandidateAndPairStats_n( int64_t timestamp_us, const std::map& transport_stats_by_name, const Call::Stats& call_stats, RTCStatsReport* report) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const auto& entry : transport_stats_by_name) { const std::string& transport_name = entry.first; const cricket::TransportStats& transport_stats = entry.second; for (const auto& channel_stats : transport_stats.channel_stats) { std::string transport_id = RTCTransportStatsIDFromTransportChannel( transport_name, channel_stats.component); for (const cricket::ConnectionInfo& info : channel_stats.ice_transport_stats.connection_infos) { std::unique_ptr candidate_pair_stats( new RTCIceCandidatePairStats( RTCIceCandidatePairStatsIDFromConnectionInfo(info), timestamp_us)); candidate_pair_stats->transport_id = transport_id; // TODO(hbos): There could be other candidates that are not paired with // anything. We don't have a complete list. Local candidates come from // Port objects, and prflx candidates (both local and remote) are only // stored in candidate pairs. https://crbug.com/632723 candidate_pair_stats->local_candidate_id = ProduceIceCandidateStats( timestamp_us, info.local_candidate, true, transport_id, report); candidate_pair_stats->remote_candidate_id = ProduceIceCandidateStats( timestamp_us, info.remote_candidate, false, transport_id, report); candidate_pair_stats->state = IceCandidatePairStateToRTCStatsIceCandidatePairState(info.state); candidate_pair_stats->priority = info.priority; candidate_pair_stats->nominated = info.nominated; // TODO(hbos): This writable is different than the spec. It goes to // false after a certain amount of time without a response passes. // https://crbug.com/633550 candidate_pair_stats->writable = info.writable; candidate_pair_stats->bytes_sent = static_cast(info.sent_total_bytes); candidate_pair_stats->bytes_received = static_cast(info.recv_total_bytes); candidate_pair_stats->total_round_trip_time = static_cast(info.total_round_trip_time_ms) / rtc::kNumMillisecsPerSec; if (info.current_round_trip_time_ms) { candidate_pair_stats->current_round_trip_time = static_cast(*info.current_round_trip_time_ms) / rtc::kNumMillisecsPerSec; } if (info.best_connection) { // The bandwidth estimations we have are for the selected candidate // pair ("info.best_connection"). RTC_DCHECK_GE(call_stats.send_bandwidth_bps, 0); RTC_DCHECK_GE(call_stats.recv_bandwidth_bps, 0); if (call_stats.send_bandwidth_bps > 0) { candidate_pair_stats->available_outgoing_bitrate = static_cast(call_stats.send_bandwidth_bps); } if (call_stats.recv_bandwidth_bps > 0) { candidate_pair_stats->available_incoming_bitrate = static_cast(call_stats.recv_bandwidth_bps); } } candidate_pair_stats->requests_received = static_cast(info.recv_ping_requests); candidate_pair_stats->requests_sent = static_cast( info.sent_ping_requests_before_first_response); candidate_pair_stats->responses_received = static_cast(info.recv_ping_responses); candidate_pair_stats->responses_sent = static_cast(info.sent_ping_responses); RTC_DCHECK_GE(info.sent_ping_requests_total, info.sent_ping_requests_before_first_response); candidate_pair_stats->consent_requests_sent = static_cast( info.sent_ping_requests_total - info.sent_ping_requests_before_first_response); report->AddStats(std::move(candidate_pair_stats)); } } } } void RTCStatsCollector::ProduceMediaStreamStats_s( int64_t timestamp_us, RTCStatsReport* report) const { RTC_DCHECK(signaling_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; std::map> track_ids; for (const auto& stats : transceiver_stats_infos_) { for (const auto& sender : stats.transceiver->senders()) { std::string track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment( kSender, sender->internal()->AttachmentId()); for (auto& stream_id : sender->stream_ids()) { track_ids[stream_id].push_back(track_id); } } for (const auto& receiver : stats.transceiver->receivers()) { std::string track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment( kReceiver, receiver->internal()->AttachmentId()); for (auto& stream : receiver->streams()) { track_ids[stream->id()].push_back(track_id); } } } // Build stats for each stream ID known. for (auto& it : track_ids) { std::unique_ptr stream_stats( new RTCMediaStreamStats("RTCMediaStream_" + it.first, timestamp_us)); stream_stats->stream_identifier = it.first; stream_stats->track_ids = it.second; report->AddStats(std::move(stream_stats)); } } void RTCStatsCollector::ProduceMediaStreamTrackStats_s( int64_t timestamp_us, RTCStatsReport* report) const { RTC_DCHECK(signaling_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const RtpTransceiverStatsInfo& stats : transceiver_stats_infos_) { std::vector> senders; for (const auto& sender : stats.transceiver->senders()) { senders.push_back(sender->internal()); } ProduceSenderMediaTrackStats(timestamp_us, *stats.track_media_info_map, senders, report); std::vector> receivers; for (const auto& receiver : stats.transceiver->receivers()) { receivers.push_back(receiver->internal()); } ProduceReceiverMediaTrackStats(timestamp_us, *stats.track_media_info_map, receivers, report); } } void RTCStatsCollector::ProduceMediaSourceStats_s( int64_t timestamp_us, RTCStatsReport* report) const { RTC_DCHECK(signaling_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const RtpTransceiverStatsInfo& transceiver_stats_info : transceiver_stats_infos_) { const auto& track_media_info_map = transceiver_stats_info.track_media_info_map; for (const auto& sender : transceiver_stats_info.transceiver->senders()) { const auto& sender_internal = sender->internal(); const auto& track = sender_internal->track(); if (!track) continue; // TODO(https://crbug.com/webrtc/10771): The same track could be attached // to multiple senders which should result in multiple senders referencing // the same media-source stats. When all media source related metrics are // moved to the track's source (e.g. input frame rate is moved from // cricket::VideoSenderInfo to VideoTrackSourceInterface::Stats and audio // levels are moved to the corresponding audio track/source object), don't // create separate media source stats objects on a per-attachment basis. std::unique_ptr media_source_stats; if (track->kind() == MediaStreamTrackInterface::kAudioKind) { auto audio_source_stats = std::make_unique( RTCMediaSourceStatsIDFromKindAndAttachment( cricket::MEDIA_TYPE_AUDIO, sender_internal->AttachmentId()), timestamp_us); // TODO(https://crbug.com/webrtc/10771): We shouldn't need to have an // SSRC assigned (there shouldn't need to exist a send-stream, created // by an O/A exchange) in order to read audio media-source stats. // TODO(https://crbug.com/webrtc/8694): SSRC 0 shouldn't be a magic // value indicating no SSRC. if (sender_internal->ssrc() != 0) { auto* voice_sender_info = track_media_info_map->GetVoiceSenderInfoBySsrc( sender_internal->ssrc()); if (voice_sender_info) { audio_source_stats->audio_level = DoubleAudioLevelFromIntAudioLevel( voice_sender_info->audio_level); audio_source_stats->total_audio_energy = voice_sender_info->total_input_energy; audio_source_stats->total_samples_duration = voice_sender_info->total_input_duration; } } media_source_stats = std::move(audio_source_stats); } else { RTC_DCHECK_EQ(MediaStreamTrackInterface::kVideoKind, track->kind()); auto video_source_stats = std::make_unique( RTCMediaSourceStatsIDFromKindAndAttachment( cricket::MEDIA_TYPE_VIDEO, sender_internal->AttachmentId()), timestamp_us); auto* video_track = static_cast(track.get()); auto* video_source = video_track->GetSource(); VideoTrackSourceInterface::Stats source_stats; if (video_source && video_source->GetStats(&source_stats)) { video_source_stats->width = source_stats.input_width; video_source_stats->height = source_stats.input_height; } // TODO(https://crbug.com/webrtc/10771): We shouldn't need to have an // SSRC assigned (there shouldn't need to exist a send-stream, created // by an O/A exchange) in order to get framesPerSecond. // TODO(https://crbug.com/webrtc/8694): SSRC 0 shouldn't be a magic // value indicating no SSRC. if (sender_internal->ssrc() != 0) { auto* video_sender_info = track_media_info_map->GetVideoSenderInfoBySsrc( sender_internal->ssrc()); if (video_sender_info) { video_source_stats->frames_per_second = video_sender_info->framerate_input; } } media_source_stats = std::move(video_source_stats); } media_source_stats->track_identifier = track->id(); media_source_stats->kind = track->kind(); report->AddStats(std::move(media_source_stats)); } } } void RTCStatsCollector::ProducePeerConnectionStats_s( int64_t timestamp_us, RTCStatsReport* report) const { RTC_DCHECK(signaling_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; std::unique_ptr stats( new RTCPeerConnectionStats("RTCPeerConnection", timestamp_us)); stats->data_channels_opened = internal_record_.data_channels_opened; stats->data_channels_closed = internal_record_.data_channels_closed; report->AddStats(std::move(stats)); } void RTCStatsCollector::ProduceRTPStreamStats_n( int64_t timestamp_us, const std::vector& transceiver_stats_infos, RTCStatsReport* report) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const RtpTransceiverStatsInfo& stats : transceiver_stats_infos) { if (stats.media_type == cricket::MEDIA_TYPE_AUDIO) { ProduceAudioRTPStreamStats_n(timestamp_us, stats, report); } else if (stats.media_type == cricket::MEDIA_TYPE_VIDEO) { ProduceVideoRTPStreamStats_n(timestamp_us, stats, report); } else { RTC_NOTREACHED(); } } } void RTCStatsCollector::ProduceAudioRTPStreamStats_n( int64_t timestamp_us, const RtpTransceiverStatsInfo& stats, RTCStatsReport* report) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; if (!stats.mid || !stats.transport_name) { return; } RTC_DCHECK(stats.track_media_info_map); const TrackMediaInfoMap& track_media_info_map = *stats.track_media_info_map; RTC_DCHECK(track_media_info_map.voice_media_info()); std::string mid = *stats.mid; std::string transport_id = RTCTransportStatsIDFromTransportChannel( *stats.transport_name, cricket::ICE_CANDIDATE_COMPONENT_RTP); // Inbound for (const cricket::VoiceReceiverInfo& voice_receiver_info : track_media_info_map.voice_media_info()->receivers) { if (!voice_receiver_info.connected()) continue; auto inbound_audio = std::make_unique( RTCInboundRTPStreamStatsIDFromSSRC(true, voice_receiver_info.ssrc()), timestamp_us); SetInboundRTPStreamStatsFromVoiceReceiverInfo(mid, voice_receiver_info, inbound_audio.get()); // TODO(hta): This lookup should look for the sender, not the track. rtc::scoped_refptr audio_track = track_media_info_map.GetAudioTrack(voice_receiver_info); if (audio_track) { inbound_audio->track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment( kReceiver, track_media_info_map.GetAttachmentIdByTrack(audio_track).value()); } inbound_audio->transport_id = transport_id; report->AddStats(std::move(inbound_audio)); } // Outbound std::map audio_outbound_rtps; for (const cricket::VoiceSenderInfo& voice_sender_info : track_media_info_map.voice_media_info()->senders) { if (!voice_sender_info.connected()) continue; auto outbound_audio = std::make_unique( RTCOutboundRTPStreamStatsIDFromSSRC(true, voice_sender_info.ssrc()), timestamp_us); SetOutboundRTPStreamStatsFromVoiceSenderInfo(mid, voice_sender_info, outbound_audio.get()); rtc::scoped_refptr audio_track = track_media_info_map.GetAudioTrack(voice_sender_info); if (audio_track) { int attachment_id = track_media_info_map.GetAttachmentIdByTrack(audio_track).value(); outbound_audio->track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment(kSender, attachment_id); outbound_audio->media_source_id = RTCMediaSourceStatsIDFromKindAndAttachment(cricket::MEDIA_TYPE_AUDIO, attachment_id); } outbound_audio->transport_id = transport_id; audio_outbound_rtps.insert( std::make_pair(outbound_audio->id(), outbound_audio.get())); report->AddStats(std::move(outbound_audio)); } // Remote-inbound // These are Report Block-based, information sent from the remote endpoint, // providing metrics about our Outbound streams. We take advantage of the fact // that RTCOutboundRtpStreamStats, RTCCodecStats and RTCTransport have already // been added to the report. for (const cricket::VoiceSenderInfo& voice_sender_info : track_media_info_map.voice_media_info()->senders) { for (const auto& report_block_data : voice_sender_info.report_block_datas) { report->AddStats(ProduceRemoteInboundRtpStreamStatsFromReportBlockData( report_block_data, cricket::MEDIA_TYPE_AUDIO, audio_outbound_rtps, *report)); } } } void RTCStatsCollector::ProduceVideoRTPStreamStats_n( int64_t timestamp_us, const RtpTransceiverStatsInfo& stats, RTCStatsReport* report) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; if (!stats.mid || !stats.transport_name) { return; } RTC_DCHECK(stats.track_media_info_map); const TrackMediaInfoMap& track_media_info_map = *stats.track_media_info_map; RTC_DCHECK(track_media_info_map.video_media_info()); std::string mid = *stats.mid; std::string transport_id = RTCTransportStatsIDFromTransportChannel( *stats.transport_name, cricket::ICE_CANDIDATE_COMPONENT_RTP); // Inbound for (const cricket::VideoReceiverInfo& video_receiver_info : track_media_info_map.video_media_info()->receivers) { if (!video_receiver_info.connected()) continue; auto inbound_video = std::make_unique( RTCInboundRTPStreamStatsIDFromSSRC(false, video_receiver_info.ssrc()), timestamp_us); SetInboundRTPStreamStatsFromVideoReceiverInfo(mid, video_receiver_info, inbound_video.get()); rtc::scoped_refptr video_track = track_media_info_map.GetVideoTrack(video_receiver_info); if (video_track) { inbound_video->track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment( kReceiver, track_media_info_map.GetAttachmentIdByTrack(video_track).value()); } inbound_video->transport_id = transport_id; report->AddStats(std::move(inbound_video)); } // Outbound std::map video_outbound_rtps; for (const cricket::VideoSenderInfo& video_sender_info : track_media_info_map.video_media_info()->senders) { if (!video_sender_info.connected()) continue; auto outbound_video = std::make_unique( RTCOutboundRTPStreamStatsIDFromSSRC(false, video_sender_info.ssrc()), timestamp_us); SetOutboundRTPStreamStatsFromVideoSenderInfo(mid, video_sender_info, outbound_video.get()); rtc::scoped_refptr video_track = track_media_info_map.GetVideoTrack(video_sender_info); if (video_track) { int attachment_id = track_media_info_map.GetAttachmentIdByTrack(video_track).value(); outbound_video->track_id = RTCMediaStreamTrackStatsIDFromDirectionAndAttachment(kSender, attachment_id); outbound_video->media_source_id = RTCMediaSourceStatsIDFromKindAndAttachment(cricket::MEDIA_TYPE_VIDEO, attachment_id); } outbound_video->transport_id = transport_id; video_outbound_rtps.insert( std::make_pair(outbound_video->id(), outbound_video.get())); report->AddStats(std::move(outbound_video)); } // Remote-inbound // These are Report Block-based, information sent from the remote endpoint, // providing metrics about our Outbound streams. We take advantage of the fact // that RTCOutboundRtpStreamStats, RTCCodecStats and RTCTransport have already // been added to the report. for (const cricket::VideoSenderInfo& video_sender_info : track_media_info_map.video_media_info()->senders) { for (const auto& report_block_data : video_sender_info.report_block_datas) { report->AddStats(ProduceRemoteInboundRtpStreamStatsFromReportBlockData( report_block_data, cricket::MEDIA_TYPE_VIDEO, video_outbound_rtps, *report)); } } } void RTCStatsCollector::ProduceTransportStats_n( int64_t timestamp_us, const std::map& transport_stats_by_name, const std::map& transport_cert_stats, RTCStatsReport* report) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const auto& entry : transport_stats_by_name) { const std::string& transport_name = entry.first; const cricket::TransportStats& transport_stats = entry.second; // Get reference to RTCP channel, if it exists. std::string rtcp_transport_stats_id; for (const cricket::TransportChannelStats& channel_stats : transport_stats.channel_stats) { if (channel_stats.component == cricket::ICE_CANDIDATE_COMPONENT_RTCP) { rtcp_transport_stats_id = RTCTransportStatsIDFromTransportChannel( transport_name, channel_stats.component); break; } } // Get reference to local and remote certificates of this transport, if they // exist. const auto& certificate_stats_it = transport_cert_stats.find(transport_name); RTC_DCHECK(certificate_stats_it != transport_cert_stats.cend()); std::string local_certificate_id; if (certificate_stats_it->second.local) { local_certificate_id = RTCCertificateIDFromFingerprint( certificate_stats_it->second.local->fingerprint); } std::string remote_certificate_id; if (certificate_stats_it->second.remote) { remote_certificate_id = RTCCertificateIDFromFingerprint( certificate_stats_it->second.remote->fingerprint); } // There is one transport stats for each channel. for (const cricket::TransportChannelStats& channel_stats : transport_stats.channel_stats) { std::unique_ptr transport_stats( new RTCTransportStats(RTCTransportStatsIDFromTransportChannel( transport_name, channel_stats.component), timestamp_us)); transport_stats->bytes_sent = 0; transport_stats->packets_sent = 0; transport_stats->bytes_received = 0; transport_stats->packets_received = 0; transport_stats->dtls_state = DtlsTransportStateToRTCDtlsTransportState(channel_stats.dtls_state); transport_stats->selected_candidate_pair_changes = channel_stats.ice_transport_stats.selected_candidate_pair_changes; for (const cricket::ConnectionInfo& info : channel_stats.ice_transport_stats.connection_infos) { *transport_stats->bytes_sent += info.sent_total_bytes; *transport_stats->packets_sent += info.sent_total_packets - info.sent_discarded_packets; *transport_stats->bytes_received += info.recv_total_bytes; *transport_stats->packets_received += info.packets_received; if (info.best_connection) { transport_stats->selected_candidate_pair_id = RTCIceCandidatePairStatsIDFromConnectionInfo(info); } } if (channel_stats.component != cricket::ICE_CANDIDATE_COMPONENT_RTCP && !rtcp_transport_stats_id.empty()) { transport_stats->rtcp_transport_stats_id = rtcp_transport_stats_id; } if (!local_certificate_id.empty()) transport_stats->local_certificate_id = local_certificate_id; if (!remote_certificate_id.empty()) transport_stats->remote_certificate_id = remote_certificate_id; // Crypto information if (channel_stats.ssl_version_bytes) { char bytes[5]; snprintf(bytes, sizeof(bytes), "%04X", channel_stats.ssl_version_bytes); transport_stats->tls_version = bytes; } if (channel_stats.ssl_cipher_suite != rtc::TLS_NULL_WITH_NULL_NULL && rtc::SSLStreamAdapter::SslCipherSuiteToName( channel_stats.ssl_cipher_suite) .length()) { transport_stats->dtls_cipher = rtc::SSLStreamAdapter::SslCipherSuiteToName( channel_stats.ssl_cipher_suite); } if (channel_stats.srtp_crypto_suite != rtc::SRTP_INVALID_CRYPTO_SUITE && rtc::SrtpCryptoSuiteToName(channel_stats.srtp_crypto_suite) .length()) { transport_stats->srtp_cipher = rtc::SrtpCryptoSuiteToName(channel_stats.srtp_crypto_suite); } report->AddStats(std::move(transport_stats)); } } } std::map RTCStatsCollector::PrepareTransportCertificateStats_n( const std::map& transport_stats_by_name) const { RTC_DCHECK(network_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; std::map transport_cert_stats; for (const auto& entry : transport_stats_by_name) { const std::string& transport_name = entry.first; CertificateStatsPair certificate_stats_pair; rtc::scoped_refptr local_certificate; if (pc_->GetLocalCertificate(transport_name, &local_certificate)) { certificate_stats_pair.local = local_certificate->GetSSLCertificateChain().GetStats(); } std::unique_ptr remote_cert_chain = pc_->GetRemoteSSLCertChain(transport_name); if (remote_cert_chain) { certificate_stats_pair.remote = remote_cert_chain->GetStats(); } transport_cert_stats.insert( std::make_pair(transport_name, std::move(certificate_stats_pair))); } return transport_cert_stats; } void RTCStatsCollector::PrepareTransceiverStatsInfosAndCallStats_s_w() { RTC_DCHECK(signaling_thread_->IsCurrent()); transceiver_stats_infos_.clear(); // These are used to invoke GetStats for all the media channels together in // one worker thread hop. std::map> voice_stats; std::map> video_stats; { rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const auto& transceiver : pc_->GetTransceiversInternal()) { cricket::MediaType media_type = transceiver->media_type(); // Prepare stats entry. The TrackMediaInfoMap will be filled in after the // stats have been fetched on the worker thread. transceiver_stats_infos_.emplace_back(); RtpTransceiverStatsInfo& stats = transceiver_stats_infos_.back(); stats.transceiver = transceiver->internal(); stats.media_type = media_type; cricket::ChannelInterface* channel = transceiver->internal()->channel(); if (!channel) { // The remaining fields require a BaseChannel. continue; } stats.mid = channel->content_name(); stats.transport_name = channel->transport_name(); if (media_type == cricket::MEDIA_TYPE_AUDIO) { auto* voice_channel = static_cast(channel); RTC_DCHECK(voice_stats.find(voice_channel->media_channel()) == voice_stats.end()); voice_stats[voice_channel->media_channel()] = std::make_unique(); } else if (media_type == cricket::MEDIA_TYPE_VIDEO) { auto* video_channel = static_cast(channel); RTC_DCHECK(video_stats.find(video_channel->media_channel()) == video_stats.end()); video_stats[video_channel->media_channel()] = std::make_unique(); } else { RTC_NOTREACHED(); } } } // We jump to the worker thread and call GetStats() on each media channel as // well as GetCallStats(). At the same time we construct the // TrackMediaInfoMaps, which also needs info from the worker thread. This // minimizes the number of thread jumps. worker_thread_->Invoke(RTC_FROM_HERE, [&] { rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; for (const auto& entry : voice_stats) { if (!entry.first->GetStats(entry.second.get(), /*get_and_clear_legacy_stats=*/false)) { RTC_LOG(LS_WARNING) << "Failed to get voice stats."; } } for (const auto& entry : video_stats) { if (!entry.first->GetStats(entry.second.get())) { RTC_LOG(LS_WARNING) << "Failed to get video stats."; } } // Create the TrackMediaInfoMap for each transceiver stats object. for (auto& stats : transceiver_stats_infos_) { auto transceiver = stats.transceiver; std::unique_ptr voice_media_info; std::unique_ptr video_media_info; if (transceiver->channel()) { cricket::MediaType media_type = transceiver->media_type(); if (media_type == cricket::MEDIA_TYPE_AUDIO) { auto* voice_channel = static_cast(transceiver->channel()); RTC_DCHECK(voice_stats[voice_channel->media_channel()]); voice_media_info = std::move(voice_stats[voice_channel->media_channel()]); } else if (media_type == cricket::MEDIA_TYPE_VIDEO) { auto* video_channel = static_cast(transceiver->channel()); RTC_DCHECK(video_stats[video_channel->media_channel()]); video_media_info = std::move(video_stats[video_channel->media_channel()]); } } std::vector> senders; for (const auto& sender : transceiver->senders()) { senders.push_back(sender->internal()); } std::vector> receivers; for (const auto& receiver : transceiver->receivers()) { receivers.push_back(receiver->internal()); } stats.track_media_info_map = std::make_unique( std::move(voice_media_info), std::move(video_media_info), senders, receivers); } call_stats_ = pc_->GetCallStats(); }); } std::set RTCStatsCollector::PrepareTransportNames_s() const { RTC_DCHECK(signaling_thread_->IsCurrent()); rtc::Thread::ScopedDisallowBlockingCalls no_blocking_calls; std::set transport_names; for (const auto& transceiver : pc_->GetTransceiversInternal()) { if (transceiver->internal()->channel()) { transport_names.insert( transceiver->internal()->channel()->transport_name()); } } if (pc_->rtp_data_channel()) { transport_names.insert(pc_->rtp_data_channel()->transport_name()); } if (pc_->sctp_transport_name()) { transport_names.insert(*pc_->sctp_transport_name()); } return transport_names; } void RTCStatsCollector::OnRtpDataChannelCreated(RtpDataChannel* channel) { channel->SignalOpened.connect(this, &RTCStatsCollector::OnDataChannelOpened); channel->SignalClosed.connect(this, &RTCStatsCollector::OnDataChannelClosed); } void RTCStatsCollector::OnSctpDataChannelCreated(SctpDataChannel* channel) { channel->SignalOpened.connect(this, &RTCStatsCollector::OnDataChannelOpened); channel->SignalClosed.connect(this, &RTCStatsCollector::OnDataChannelClosed); } void RTCStatsCollector::OnDataChannelOpened(DataChannelInterface* channel) { RTC_DCHECK(signaling_thread_->IsCurrent()); bool result = internal_record_.opened_data_channels .insert(reinterpret_cast(channel)) .second; ++internal_record_.data_channels_opened; RTC_DCHECK(result); } void RTCStatsCollector::OnDataChannelClosed(DataChannelInterface* channel) { RTC_DCHECK(signaling_thread_->IsCurrent()); // Only channels that have been fully opened (and have increased the // |data_channels_opened_| counter) increase the closed counter. if (internal_record_.opened_data_channels.erase( reinterpret_cast(channel))) { ++internal_record_.data_channels_closed; } } const char* CandidateTypeToRTCIceCandidateTypeForTesting( const std::string& type) { return CandidateTypeToRTCIceCandidateType(type); } const char* DataStateToRTCDataChannelStateForTesting( DataChannelInterface::DataState state) { return DataStateToRTCDataChannelState(state); } } // namespace webrtc