/* * 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 "modules/rtp_rtcp/source/rtp_sender.h" #include #include #include #include #include #include "absl/strings/match.h" #include "absl/strings/string_view.h" #include "api/array_view.h" #include "api/rtc_event_log/rtc_event_log.h" #include "logging/rtc_event_log/events/rtc_event_rtp_packet_outgoing.h" #include "modules/rtp_rtcp/include/rtp_cvo.h" #include "modules/rtp_rtcp/source/byte_io.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_to_send.h" #include "modules/rtp_rtcp/source/time_util.h" #include "rtc_base/arraysize.h" #include "rtc_base/checks.h" #include "rtc_base/experiments/field_trial_parser.h" #include "rtc_base/logging.h" #include "rtc_base/numerics/safe_minmax.h" #include "rtc_base/rate_limiter.h" #include "rtc_base/time_utils.h" namespace webrtc { namespace { constexpr size_t kMinAudioPaddingLength = 50; constexpr size_t kRtpHeaderLength = 12; // Min size needed to get payload padding from packet history. constexpr int kMinPayloadPaddingBytes = 50; // Determines how much larger a payload padding packet may be, compared to the // requested padding size. constexpr double kMaxPaddingSizeFactor = 3.0; template constexpr RtpExtensionSize CreateExtensionSize() { return {Extension::kId, Extension::kValueSizeBytes}; } template constexpr RtpExtensionSize CreateMaxExtensionSize() { return {Extension::kId, Extension::kMaxValueSizeBytes}; } // Size info for header extensions that might be used in padding or FEC packets. constexpr RtpExtensionSize kFecOrPaddingExtensionSizes[] = { CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateMaxExtensionSize(), CreateExtensionSize(), }; // Size info for header extensions that might be used in video packets. constexpr RtpExtensionSize kVideoExtensionSizes[] = { CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateMaxExtensionSize(), CreateMaxExtensionSize(), CreateMaxExtensionSize(), {RtpGenericFrameDescriptorExtension00::kId, RtpGenericFrameDescriptorExtension00::kMaxSizeBytes}, }; // Size info for header extensions that might be used in audio packets. constexpr RtpExtensionSize kAudioExtensionSizes[] = { CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateExtensionSize(), CreateMaxExtensionSize(), }; // Non-volatile extensions can be expected on all packets, if registered. // Volatile ones, such as VideoContentTypeExtension which is only set on // key-frames, are removed to simplify overhead calculations at the expense of // some accuracy. bool IsNonVolatile(RTPExtensionType type) { switch (type) { case kRtpExtensionTransmissionTimeOffset: case kRtpExtensionAudioLevel: #if !defined(WEBRTC_MOZILLA_BUILD) case kRtpExtensionCsrcAudioLevel: #endif case kRtpExtensionAbsoluteSendTime: case kRtpExtensionTransportSequenceNumber: case kRtpExtensionTransportSequenceNumber02: case kRtpExtensionRtpStreamId: case kRtpExtensionRepairedRtpStreamId: case kRtpExtensionMid: case kRtpExtensionGenericFrameDescriptor: case kRtpExtensionDependencyDescriptor: return true; case kRtpExtensionInbandComfortNoise: case kRtpExtensionAbsoluteCaptureTime: case kRtpExtensionVideoRotation: case kRtpExtensionPlayoutDelay: case kRtpExtensionVideoContentType: case kRtpExtensionVideoLayersAllocation: case kRtpExtensionVideoTiming: case kRtpExtensionColorSpace: case kRtpExtensionVideoFrameTrackingId: return false; case kRtpExtensionNone: case kRtpExtensionNumberOfExtensions: RTC_DCHECK_NOTREACHED(); return false; #if defined(WEBRTC_MOZILLA_BUILD) case kRtpExtensionCsrcAudioLevel: // TODO: Mozilla implement for CsrcAudioLevel RTC_CHECK(false); return false; #endif } RTC_CHECK_NOTREACHED(); } bool HasBweExtension(const RtpHeaderExtensionMap& extensions_map) { return extensions_map.IsRegistered(kRtpExtensionTransportSequenceNumber) || extensions_map.IsRegistered(kRtpExtensionTransportSequenceNumber02) || extensions_map.IsRegistered(kRtpExtensionAbsoluteSendTime) || extensions_map.IsRegistered(kRtpExtensionTransmissionTimeOffset); } } // namespace RTPSender::RTPSender(const RtpRtcpInterface::Configuration& config, RtpPacketHistory* packet_history, RtpPacketSender* packet_sender) : clock_(config.clock), random_(clock_->TimeInMicroseconds()), audio_configured_(config.audio), ssrc_(config.local_media_ssrc), rtx_ssrc_(config.rtx_send_ssrc), flexfec_ssrc_(config.fec_generator ? config.fec_generator->FecSsrc() : absl::nullopt), packet_history_(packet_history), paced_sender_(packet_sender), sending_media_(true), // Default to sending media. max_packet_size_(IP_PACKET_SIZE - 28), // Default is IP-v4/UDP. rtp_header_extension_map_(config.extmap_allow_mixed), // RTP variables rid_(config.rid), always_send_mid_and_rid_(config.always_send_mid_and_rid), ssrc_has_acked_(false), rtx_ssrc_has_acked_(false), rtx_(kRtxOff), supports_bwe_extension_(false), retransmission_rate_limiter_(config.retransmission_rate_limiter) { // This random initialization is not intended to be cryptographic strong. timestamp_offset_ = random_.Rand(); RTC_DCHECK(paced_sender_); RTC_DCHECK(packet_history_); RTC_DCHECK_LE(rid_.size(), RtpStreamId::kMaxValueSizeBytes); UpdateHeaderSizes(); } RTPSender::~RTPSender() { // TODO(tommi): Use a thread checker to ensure the object is created and // deleted on the same thread. At the moment this isn't possible due to // voe::ChannelOwner in voice engine. To reproduce, run: // voe_auto_test --automated --gtest_filter=*MixManyChannelsForStressOpus // TODO(tommi,holmer): We don't grab locks in the dtor before accessing member // variables but we grab them in all other methods. (what's the design?) // Start documenting what thread we're on in what method so that it's easier // to understand performance attributes and possibly remove locks. } rtc::ArrayView RTPSender::FecExtensionSizes() { return rtc::MakeArrayView(kFecOrPaddingExtensionSizes, arraysize(kFecOrPaddingExtensionSizes)); } rtc::ArrayView RTPSender::VideoExtensionSizes() { return rtc::MakeArrayView(kVideoExtensionSizes, arraysize(kVideoExtensionSizes)); } rtc::ArrayView RTPSender::AudioExtensionSizes() { return rtc::MakeArrayView(kAudioExtensionSizes, arraysize(kAudioExtensionSizes)); } void RTPSender::SetExtmapAllowMixed(bool extmap_allow_mixed) { MutexLock lock(&send_mutex_); rtp_header_extension_map_.SetExtmapAllowMixed(extmap_allow_mixed); } bool RTPSender::RegisterRtpHeaderExtension(absl::string_view uri, int id) { MutexLock lock(&send_mutex_); bool registered = rtp_header_extension_map_.RegisterByUri(id, uri); supports_bwe_extension_ = HasBweExtension(rtp_header_extension_map_); UpdateHeaderSizes(); return registered; } bool RTPSender::IsRtpHeaderExtensionRegistered(RTPExtensionType type) const { MutexLock lock(&send_mutex_); return rtp_header_extension_map_.IsRegistered(type); } void RTPSender::DeregisterRtpHeaderExtension(absl::string_view uri) { MutexLock lock(&send_mutex_); rtp_header_extension_map_.Deregister(uri); supports_bwe_extension_ = HasBweExtension(rtp_header_extension_map_); UpdateHeaderSizes(); } void RTPSender::SetMaxRtpPacketSize(size_t max_packet_size) { RTC_DCHECK_GE(max_packet_size, 100); RTC_DCHECK_LE(max_packet_size, IP_PACKET_SIZE); MutexLock lock(&send_mutex_); max_packet_size_ = max_packet_size; } size_t RTPSender::MaxRtpPacketSize() const { return max_packet_size_; } void RTPSender::SetRtxStatus(int mode) { MutexLock lock(&send_mutex_); if (mode != kRtxOff && (!rtx_ssrc_.has_value() || rtx_payload_type_map_.empty())) { RTC_LOG(LS_ERROR) << "Failed to enable RTX without RTX SSRC or payload types."; return; } rtx_ = mode; } int RTPSender::RtxStatus() const { MutexLock lock(&send_mutex_); return rtx_; } void RTPSender::SetRtxPayloadType(int payload_type, int associated_payload_type) { MutexLock lock(&send_mutex_); RTC_DCHECK_LE(payload_type, 127); RTC_DCHECK_LE(associated_payload_type, 127); if (payload_type < 0) { RTC_LOG(LS_ERROR) << "Invalid RTX payload type: " << payload_type << "."; return; } rtx_payload_type_map_[associated_payload_type] = payload_type; } int32_t RTPSender::ReSendPacket(uint16_t packet_id) { int32_t packet_size = 0; const bool rtx = (RtxStatus() & kRtxRetransmitted) > 0; std::unique_ptr packet = packet_history_->GetPacketAndMarkAsPending( packet_id, [&](const RtpPacketToSend& stored_packet) { // Check if we're overusing retransmission bitrate. // TODO(sprang): Add histograms for nack success or failure // reasons. packet_size = stored_packet.size(); std::unique_ptr retransmit_packet; if (retransmission_rate_limiter_ && !retransmission_rate_limiter_->TryUseRate(packet_size)) { return retransmit_packet; } if (rtx) { retransmit_packet = BuildRtxPacket(stored_packet); } else { retransmit_packet = std::make_unique(stored_packet); } if (retransmit_packet) { retransmit_packet->set_retransmitted_sequence_number( stored_packet.SequenceNumber()); } return retransmit_packet; }); if (packet_size == 0) { // Packet not found or already queued for retransmission, ignore. RTC_DCHECK(!packet); return 0; } if (!packet) { // Packet was found, but lambda helper above chose not to create // `retransmit_packet` out of it. return -1; } packet->set_packet_type(RtpPacketMediaType::kRetransmission); packet->set_fec_protect_packet(false); std::vector> packets; packets.emplace_back(std::move(packet)); paced_sender_->EnqueuePackets(std::move(packets)); return packet_size; } void RTPSender::OnReceivedAckOnSsrc(int64_t extended_highest_sequence_number) { MutexLock lock(&send_mutex_); bool update_required = !ssrc_has_acked_; ssrc_has_acked_ = true; if (update_required) { UpdateHeaderSizes(); } } void RTPSender::OnReceivedAckOnRtxSsrc( int64_t extended_highest_sequence_number) { MutexLock lock(&send_mutex_); bool update_required = !rtx_ssrc_has_acked_; rtx_ssrc_has_acked_ = true; if (update_required) { UpdateHeaderSizes(); } } void RTPSender::OnReceivedNack( const std::vector& nack_sequence_numbers, int64_t avg_rtt) { packet_history_->SetRtt(TimeDelta::Millis(5 + avg_rtt)); for (uint16_t seq_no : nack_sequence_numbers) { const int32_t bytes_sent = ReSendPacket(seq_no); if (bytes_sent < 0) { // Failed to send one Sequence number. Give up the rest in this nack. RTC_LOG(LS_WARNING) << "Failed resending RTP packet " << seq_no << ", Discard rest of packets."; break; } } } bool RTPSender::SupportsPadding() const { MutexLock lock(&send_mutex_); return sending_media_ && supports_bwe_extension_; } bool RTPSender::SupportsRtxPayloadPadding() const { MutexLock lock(&send_mutex_); return sending_media_ && supports_bwe_extension_ && (rtx_ & kRtxRedundantPayloads); } std::vector> RTPSender::GeneratePadding( size_t target_size_bytes, bool media_has_been_sent, bool can_send_padding_on_media_ssrc) { // This method does not actually send packets, it just generates // them and puts them in the pacer queue. Since this should incur // low overhead, keep the lock for the scope of the method in order // to make the code more readable. std::vector> padding_packets; size_t bytes_left = target_size_bytes; if (SupportsRtxPayloadPadding()) { while (bytes_left >= kMinPayloadPaddingBytes) { std::unique_ptr packet = packet_history_->GetPayloadPaddingPacket( [&](const RtpPacketToSend& packet) -> std::unique_ptr { // Limit overshoot, generate <= `kMaxPaddingSizeFactor` * // `target_size_bytes`. const size_t max_overshoot_bytes = static_cast( ((kMaxPaddingSizeFactor - 1.0) * target_size_bytes) + 0.5); if (packet.payload_size() + kRtxHeaderSize > max_overshoot_bytes + bytes_left) { return nullptr; } return BuildRtxPacket(packet); }); if (!packet) { break; } bytes_left -= std::min(bytes_left, packet->payload_size()); packet->set_packet_type(RtpPacketMediaType::kPadding); padding_packets.push_back(std::move(packet)); } } MutexLock lock(&send_mutex_); if (!sending_media_) { return {}; } size_t padding_bytes_in_packet; const size_t max_payload_size = max_packet_size_ - max_padding_fec_packet_header_; if (audio_configured_) { // Allow smaller padding packets for audio. padding_bytes_in_packet = rtc::SafeClamp( bytes_left, kMinAudioPaddingLength, rtc::SafeMin(max_payload_size, kMaxPaddingLength)); } else { // Always send full padding packets. This is accounted for by the // RtpPacketSender, which will make sure we don't send too much padding even // if a single packet is larger than requested. // We do this to avoid frequently sending small packets on higher bitrates. padding_bytes_in_packet = rtc::SafeMin(max_payload_size, kMaxPaddingLength); } while (bytes_left > 0) { auto padding_packet = std::make_unique(&rtp_header_extension_map_); padding_packet->set_packet_type(RtpPacketMediaType::kPadding); padding_packet->SetMarker(false); if (rtx_ == kRtxOff) { if (!can_send_padding_on_media_ssrc) { break; } padding_packet->SetSsrc(ssrc_); } else { // Without abs-send-time or transport sequence number a media packet // must be sent before padding so that the timestamps used for // estimation are correct. if (!media_has_been_sent && !(rtp_header_extension_map_.IsRegistered(AbsoluteSendTime::kId) || rtp_header_extension_map_.IsRegistered( TransportSequenceNumber::kId))) { break; } RTC_DCHECK(rtx_ssrc_); RTC_DCHECK(!rtx_payload_type_map_.empty()); padding_packet->SetSsrc(*rtx_ssrc_); padding_packet->SetPayloadType(rtx_payload_type_map_.begin()->second); } if (rtp_header_extension_map_.IsRegistered(TransportSequenceNumber::kId)) { padding_packet->ReserveExtension(); } if (rtp_header_extension_map_.IsRegistered(TransmissionOffset::kId)) { padding_packet->ReserveExtension(); } if (rtp_header_extension_map_.IsRegistered(AbsoluteSendTime::kId)) { padding_packet->ReserveExtension(); } padding_packet->SetPadding(padding_bytes_in_packet); bytes_left -= std::min(bytes_left, padding_bytes_in_packet); padding_packets.push_back(std::move(padding_packet)); } return padding_packets; } void RTPSender::EnqueuePackets( std::vector> packets) { RTC_DCHECK(!packets.empty()); Timestamp now = clock_->CurrentTime(); for (auto& packet : packets) { RTC_DCHECK(packet); RTC_CHECK(packet->packet_type().has_value()) << "Packet type must be set before sending."; if (packet->capture_time() <= Timestamp::Zero()) { packet->set_capture_time(now); } } paced_sender_->EnqueuePackets(std::move(packets)); } size_t RTPSender::FecOrPaddingPacketMaxRtpHeaderLength() const { MutexLock lock(&send_mutex_); return max_padding_fec_packet_header_; } size_t RTPSender::ExpectedPerPacketOverhead() const { MutexLock lock(&send_mutex_); return max_media_packet_header_; } std::unique_ptr RTPSender::AllocatePacket( rtc::ArrayView csrcs) { MutexLock lock(&send_mutex_); RTC_DCHECK_LE(csrcs.size(), kRtpCsrcSize); if (csrcs.size() > max_num_csrcs_) { max_num_csrcs_ = csrcs.size(); UpdateHeaderSizes(); } auto packet = std::make_unique(&rtp_header_extension_map_, max_packet_size_); packet->SetSsrc(ssrc_); packet->SetCsrcs(csrcs); // Reserve extensions, if registered, RtpSender set in SendToNetwork. packet->ReserveExtension(); packet->ReserveExtension(); packet->ReserveExtension(); // BUNDLE requires that the receiver "bind" the received SSRC to the values // in the MID and/or (R)RID header extensions if present. Therefore, the // sender can reduce overhead by omitting these header extensions once it // knows that the receiver has "bound" the SSRC. // This optimization can be configured by setting // `always_send_mid_and_rid_` appropriately. // // The algorithm here is fairly simple: Always attach a MID and/or RID (if // configured) to the outgoing packets until an RTCP receiver report comes // back for this SSRC. That feedback indicates the receiver must have // received a packet with the SSRC and header extension(s), so the sender // then stops attaching the MID and RID. if (always_send_mid_and_rid_ || !ssrc_has_acked_) { // These are no-ops if the corresponding header extension is not registered. if (!mid_.empty()) { packet->SetExtension(mid_); } if (!rid_.empty()) { packet->SetExtension(rid_); } } return packet; } size_t RTPSender::RtxPacketOverhead() const { MutexLock lock(&send_mutex_); if (rtx_ == kRtxOff) { return 0; } size_t overhead = 0; // Count space for the RTP header extensions that might need to be added to // the RTX packet. if (!always_send_mid_and_rid_ && (!rtx_ssrc_has_acked_ && ssrc_has_acked_)) { // Prefer to reserve extra byte in case two byte header rtp header // extensions are used. static constexpr int kRtpExtensionHeaderSize = 2; // Rtx packets hasn't been acked and would need to have mid and rrsid rtp // header extensions, while media packets no longer needs to include mid and // rsid extensions. if (!mid_.empty()) { overhead += (kRtpExtensionHeaderSize + mid_.size()); } if (!rid_.empty()) { overhead += (kRtpExtensionHeaderSize + rid_.size()); } // RTP header extensions are rounded up to 4 bytes. Depending on already // present extensions adding mid & rrsid may add up to 3 bytes of padding. overhead += 3; } // Add two bytes for the original sequence number in the RTP payload. overhead += kRtxHeaderSize; return overhead; } void RTPSender::SetSendingMediaStatus(bool enabled) { MutexLock lock(&send_mutex_); sending_media_ = enabled; } bool RTPSender::SendingMedia() const { MutexLock lock(&send_mutex_); return sending_media_; } bool RTPSender::IsAudioConfigured() const { return audio_configured_; } void RTPSender::SetTimestampOffset(uint32_t timestamp) { MutexLock lock(&send_mutex_); timestamp_offset_ = timestamp; } uint32_t RTPSender::TimestampOffset() const { MutexLock lock(&send_mutex_); return timestamp_offset_; } void RTPSender::SetMid(absl::string_view mid) { // This is configured via the API. MutexLock lock(&send_mutex_); RTC_DCHECK_LE(mid.length(), RtpMid::kMaxValueSizeBytes); mid_ = std::string(mid); UpdateHeaderSizes(); } static void CopyHeaderAndExtensionsToRtxPacket(const RtpPacketToSend& packet, RtpPacketToSend* rtx_packet) { // Set the relevant fixed packet headers. The following are not set: // * Payload type - it is replaced in rtx packets. // * Sequence number - RTX has a separate sequence numbering. // * SSRC - RTX stream has its own SSRC. rtx_packet->SetMarker(packet.Marker()); rtx_packet->SetTimestamp(packet.Timestamp()); // Set the variable fields in the packet header: // * CSRCs - must be set before header extensions. // * Header extensions - replace Rid header with RepairedRid header. rtx_packet->SetCsrcs(packet.Csrcs()); for (int extension_num = kRtpExtensionNone + 1; extension_num < kRtpExtensionNumberOfExtensions; ++extension_num) { auto extension = static_cast(extension_num); // Stream ID header extensions (MID, RSID) are sent per-SSRC. Since RTX // operates on a different SSRC, the presence and values of these header // extensions should be determined separately and not blindly copied. if (extension == kRtpExtensionMid || extension == kRtpExtensionRtpStreamId) { continue; } // Empty extensions should be supported, so not checking `source.empty()`. if (!packet.HasExtension(extension)) { continue; } rtc::ArrayView source = packet.FindExtension(extension); rtc::ArrayView destination = rtx_packet->AllocateExtension(extension, source.size()); // Could happen if any: // 1. Extension has 0 length. // 2. Extension is not registered in destination. // 3. Allocating extension in destination failed. if (destination.empty() || source.size() != destination.size()) { continue; } std::memcpy(destination.begin(), source.begin(), destination.size()); } } std::unique_ptr RTPSender::BuildRtxPacket( const RtpPacketToSend& packet) { std::unique_ptr rtx_packet; // Add original RTP header. { MutexLock lock(&send_mutex_); if (!sending_media_) return nullptr; RTC_DCHECK(rtx_ssrc_); // Replace payload type. auto kv = rtx_payload_type_map_.find(packet.PayloadType()); if (kv == rtx_payload_type_map_.end()) return nullptr; rtx_packet = std::make_unique(&rtp_header_extension_map_, max_packet_size_); rtx_packet->SetPayloadType(kv->second); // Replace SSRC. rtx_packet->SetSsrc(*rtx_ssrc_); CopyHeaderAndExtensionsToRtxPacket(packet, rtx_packet.get()); // RTX packets are sent on an SSRC different from the main media, so the // decision to attach MID and/or RRID header extensions is completely // separate from that of the main media SSRC. // // Note that RTX packets must used the RepairedRtpStreamId (RRID) header // extension instead of the RtpStreamId (RID) header extension even though // the payload is identical. if (always_send_mid_and_rid_ || !rtx_ssrc_has_acked_) { // These are no-ops if the corresponding header extension is not // registered. if (!mid_.empty()) { rtx_packet->SetExtension(mid_); } if (!rid_.empty()) { rtx_packet->SetExtension(rid_); } } } RTC_DCHECK(rtx_packet); uint8_t* rtx_payload = rtx_packet->AllocatePayload(packet.payload_size() + kRtxHeaderSize); RTC_CHECK(rtx_payload); // Add OSN (original sequence number). ByteWriter::WriteBigEndian(rtx_payload, packet.SequenceNumber()); // Add original payload data. auto payload = packet.payload(); if (!payload.empty()) { memcpy(rtx_payload + kRtxHeaderSize, payload.data(), payload.size()); } // Add original additional data. rtx_packet->set_additional_data(packet.additional_data()); // Copy capture time so e.g. TransmissionOffset is correctly set. rtx_packet->set_capture_time(packet.capture_time()); return rtx_packet; } void RTPSender::SetRtpState(const RtpState& rtp_state) { MutexLock lock(&send_mutex_); timestamp_offset_ = rtp_state.start_timestamp; ssrc_has_acked_ = rtp_state.ssrc_has_acked; UpdateHeaderSizes(); } RtpState RTPSender::GetRtpState() const { MutexLock lock(&send_mutex_); RtpState state; state.start_timestamp = timestamp_offset_; state.ssrc_has_acked = ssrc_has_acked_; return state; } void RTPSender::SetRtxRtpState(const RtpState& rtp_state) { MutexLock lock(&send_mutex_); rtx_ssrc_has_acked_ = rtp_state.ssrc_has_acked; } RtpState RTPSender::GetRtxRtpState() const { MutexLock lock(&send_mutex_); RtpState state; state.start_timestamp = timestamp_offset_; state.ssrc_has_acked = rtx_ssrc_has_acked_; return state; } void RTPSender::UpdateHeaderSizes() { const size_t rtp_header_length = kRtpHeaderLength + sizeof(uint32_t) * max_num_csrcs_; max_padding_fec_packet_header_ = rtp_header_length + RtpHeaderExtensionSize(kFecOrPaddingExtensionSizes, rtp_header_extension_map_); // RtpStreamId, Mid and RepairedRtpStreamId are treated specially in that // we check if they currently are being sent. RepairedRtpStreamId can be // sent instead of RtpStreamID on RTX packets and may share the same space. // When the primary SSRC has already been acked but the RTX SSRC has not // yet been acked, RepairedRtpStreamId needs to be taken into account // separately. const bool send_mid_rid_on_rtx = rtx_ssrc_.has_value() && (always_send_mid_and_rid_ || !rtx_ssrc_has_acked_); const bool send_mid_rid = always_send_mid_and_rid_ || !ssrc_has_acked_; std::vector non_volatile_extensions; for (auto& extension : audio_configured_ ? AudioExtensionSizes() : VideoExtensionSizes()) { if (IsNonVolatile(extension.type)) { switch (extension.type) { case RTPExtensionType::kRtpExtensionMid: if ((send_mid_rid || send_mid_rid_on_rtx) && !mid_.empty()) { non_volatile_extensions.push_back(extension); } break; case RTPExtensionType::kRtpExtensionRtpStreamId: if (send_mid_rid && !rid_.empty()) { non_volatile_extensions.push_back(extension); } break; case RTPExtensionType::kRtpExtensionRepairedRtpStreamId: if (send_mid_rid_on_rtx && !send_mid_rid && !rid_.empty()) { non_volatile_extensions.push_back(extension); } break; default: non_volatile_extensions.push_back(extension); } } } max_media_packet_header_ = rtp_header_length + RtpHeaderExtensionSize(non_volatile_extensions, rtp_header_extension_map_); // Reserve extra bytes if packet might be resent in an rtx packet. if (rtx_ssrc_.has_value()) { max_media_packet_header_ += kRtxHeaderSize; } } } // namespace webrtc