/* * 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 "webrtc/video_engine/vie_receiver.h" #include #include "webrtc/modules/remote_bitrate_estimator/include/remote_bitrate_estimator.h" #include "webrtc/modules/rtp_rtcp/interface/fec_receiver.h" #include "webrtc/modules/rtp_rtcp/interface/receive_statistics.h" #include "webrtc/modules/rtp_rtcp/interface/remote_ntp_time_estimator.h" #include "webrtc/modules/rtp_rtcp/interface/rtp_header_parser.h" #include "webrtc/modules/rtp_rtcp/interface/rtp_payload_registry.h" #include "webrtc/modules/rtp_rtcp/interface/rtp_receiver.h" #include "webrtc/modules/rtp_rtcp/interface/rtp_rtcp.h" #include "webrtc/modules/utility/interface/rtp_dump.h" #include "webrtc/modules/video_coding/main/interface/video_coding.h" #include "webrtc/system_wrappers/interface/critical_section_wrapper.h" #include "webrtc/system_wrappers/interface/logging.h" #include "webrtc/system_wrappers/interface/tick_util.h" #include "webrtc/system_wrappers/interface/timestamp_extrapolator.h" #include "webrtc/system_wrappers/interface/trace.h" namespace webrtc { ViEReceiver::ViEReceiver(const int32_t channel_id, VideoCodingModule* module_vcm, RemoteBitrateEstimator* remote_bitrate_estimator, RtpFeedback* rtp_feedback) : receive_cs_(CriticalSectionWrapper::CreateCriticalSection()), rtp_header_parser_(RtpHeaderParser::Create()), rtp_payload_registry_(new RTPPayloadRegistry( RTPPayloadStrategy::CreateStrategy(false))), rtp_receiver_(RtpReceiver::CreateVideoReceiver( channel_id, Clock::GetRealTimeClock(), this, rtp_feedback, rtp_payload_registry_.get())), rtp_receive_statistics_(ReceiveStatistics::Create( Clock::GetRealTimeClock())), fec_receiver_(FecReceiver::Create(this)), rtp_rtcp_(NULL), vcm_(module_vcm), remote_bitrate_estimator_(remote_bitrate_estimator), ntp_estimator_(new RemoteNtpTimeEstimator(Clock::GetRealTimeClock())), rtp_dump_(NULL), receiving_(false), restored_packet_in_use_(false), receiving_ast_enabled_(false) { assert(remote_bitrate_estimator); } ViEReceiver::~ViEReceiver() { if (rtp_dump_) { rtp_dump_->Stop(); RtpDump::DestroyRtpDump(rtp_dump_); rtp_dump_ = NULL; } } bool ViEReceiver::SetReceiveCodec(const VideoCodec& video_codec) { int8_t old_pltype = -1; if (rtp_payload_registry_->ReceivePayloadType(video_codec.plName, kVideoPayloadTypeFrequency, 0, video_codec.maxBitrate, &old_pltype) != -1) { rtp_payload_registry_->DeRegisterReceivePayload(old_pltype); } return RegisterPayload(video_codec); } bool ViEReceiver::RegisterPayload(const VideoCodec& video_codec) { return rtp_receiver_->RegisterReceivePayload(video_codec.plName, video_codec.plType, kVideoPayloadTypeFrequency, 0, video_codec.maxBitrate) == 0; } void ViEReceiver::SetNackStatus(bool enable, int max_nack_reordering_threshold) { if (!enable) { // Reset the threshold back to the lower default threshold when NACK is // disabled since we no longer will be receiving retransmissions. max_nack_reordering_threshold = kDefaultMaxReorderingThreshold; } rtp_receive_statistics_->SetMaxReorderingThreshold( max_nack_reordering_threshold); rtp_receiver_->SetNACKStatus(enable ? kNackRtcp : kNackOff); } void ViEReceiver::SetRtxPayloadType(int payload_type) { rtp_payload_registry_->SetRtxPayloadType(payload_type); } void ViEReceiver::SetRtxSsrc(uint32_t ssrc) { rtp_payload_registry_->SetRtxSsrc(ssrc); } uint32_t ViEReceiver::GetRemoteSsrc() const { return rtp_receiver_->SSRC(); } int ViEReceiver::GetCsrcs(uint32_t* csrcs) const { return rtp_receiver_->CSRCs(csrcs); } void ViEReceiver::SetRtpRtcpModule(RtpRtcp* module) { rtp_rtcp_ = module; } RtpReceiver* ViEReceiver::GetRtpReceiver() const { return rtp_receiver_.get(); } void ViEReceiver::RegisterSimulcastRtpRtcpModules( const std::list& rtp_modules) { CriticalSectionScoped cs(receive_cs_.get()); rtp_rtcp_simulcast_.clear(); if (!rtp_modules.empty()) { rtp_rtcp_simulcast_.insert(rtp_rtcp_simulcast_.begin(), rtp_modules.begin(), rtp_modules.end()); } } bool ViEReceiver::SetReceiveTimestampOffsetStatus(bool enable, int id) { if (enable) { return rtp_header_parser_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, id); } else { return rtp_header_parser_->DeregisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset); } } bool ViEReceiver::SetReceiveAbsoluteSendTimeStatus(bool enable, int id) { if (enable) { if (rtp_header_parser_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, id)) { receiving_ast_enabled_ = true; return true; } else { return false; } } else { receiving_ast_enabled_ = false; return rtp_header_parser_->DeregisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime); } } int ViEReceiver::ReceivedRTPPacket(const void* rtp_packet, int rtp_packet_length, const PacketTime& packet_time) { return InsertRTPPacket(static_cast(rtp_packet), rtp_packet_length, packet_time); } int ViEReceiver::ReceivedRTCPPacket(const void* rtcp_packet, int rtcp_packet_length) { return InsertRTCPPacket(static_cast(rtcp_packet), rtcp_packet_length); } int32_t ViEReceiver::OnReceivedPayloadData( const uint8_t* payload_data, const uint16_t payload_size, const WebRtcRTPHeader* rtp_header) { WebRtcRTPHeader rtp_header_with_ntp = *rtp_header; rtp_header_with_ntp.ntp_time_ms = ntp_estimator_->Estimate(rtp_header->header.timestamp); if (vcm_->IncomingPacket(payload_data, payload_size, rtp_header_with_ntp) != 0) { // Check this... return -1; } return 0; } bool ViEReceiver::OnRecoveredPacket(const uint8_t* rtp_packet, int rtp_packet_length) { RTPHeader header; if (!rtp_header_parser_->Parse(rtp_packet, rtp_packet_length, &header)) { return false; } header.payload_type_frequency = kVideoPayloadTypeFrequency; bool in_order = IsPacketInOrder(header); return ReceivePacket(rtp_packet, rtp_packet_length, header, in_order); } void ViEReceiver::ReceivedBWEPacket( int64_t arrival_time_ms, int payload_size, const RTPHeader& header) { // Only forward if the incoming packet *and* the channel are both configured // to receive absolute sender time. RTP time stamps may have different rates // for audio and video and shouldn't be mixed. if (header.extension.hasAbsoluteSendTime && receiving_ast_enabled_) { remote_bitrate_estimator_->IncomingPacket(arrival_time_ms, payload_size, header); } } int ViEReceiver::InsertRTPPacket(const uint8_t* rtp_packet, int rtp_packet_length, const PacketTime& packet_time) { { CriticalSectionScoped cs(receive_cs_.get()); if (!receiving_) { return -1; } if (rtp_dump_) { rtp_dump_->DumpPacket(rtp_packet, static_cast(rtp_packet_length)); } } RTPHeader header; if (!rtp_header_parser_->Parse(rtp_packet, rtp_packet_length, &header)) { return -1; } int payload_length = rtp_packet_length - header.headerLength; int64_t arrival_time_ms; if (packet_time.timestamp != -1) arrival_time_ms = (packet_time.timestamp + 500) / 1000; else arrival_time_ms = TickTime::MillisecondTimestamp(); remote_bitrate_estimator_->IncomingPacket(arrival_time_ms, payload_length, header); header.payload_type_frequency = kVideoPayloadTypeFrequency; bool in_order = IsPacketInOrder(header); rtp_payload_registry_->SetIncomingPayloadType(header); int ret = ReceivePacket(rtp_packet, rtp_packet_length, header, in_order) ? 0 : -1; // Update receive statistics after ReceivePacket. // Receive statistics will be reset if the payload type changes (make sure // that the first packet is included in the stats). rtp_receive_statistics_->IncomingPacket( header, rtp_packet_length, IsPacketRetransmitted(header, in_order)); return ret; } bool ViEReceiver::ReceivePacket(const uint8_t* packet, int packet_length, const RTPHeader& header, bool in_order) { if (rtp_payload_registry_->IsEncapsulated(header)) { return ParseAndHandleEncapsulatingHeader(packet, packet_length, header); } const uint8_t* payload = packet + header.headerLength; int payload_length = packet_length - header.headerLength; assert(payload_length >= 0); PayloadUnion payload_specific; if (!rtp_payload_registry_->GetPayloadSpecifics(header.payloadType, &payload_specific)) { return false; } return rtp_receiver_->IncomingRtpPacket(header, payload, payload_length, payload_specific, in_order); } bool ViEReceiver::ParseAndHandleEncapsulatingHeader(const uint8_t* packet, int packet_length, const RTPHeader& header) { if (rtp_payload_registry_->IsRed(header)) { int8_t ulpfec_pt = rtp_payload_registry_->ulpfec_payload_type(); if (packet[header.headerLength] == ulpfec_pt) rtp_receive_statistics_->FecPacketReceived(header.ssrc); if (fec_receiver_->AddReceivedRedPacket( header, packet, packet_length, ulpfec_pt) != 0) { return false; } return fec_receiver_->ProcessReceivedFec() == 0; } else if (rtp_payload_registry_->IsRtx(header)) { if (header.headerLength + header.paddingLength == packet_length) { // This is an empty packet and should be silently dropped before trying to // parse the RTX header. return true; } // Remove the RTX header and parse the original RTP header. if (packet_length < header.headerLength) return false; if (packet_length > static_cast(sizeof(restored_packet_))) return false; CriticalSectionScoped cs(receive_cs_.get()); if (restored_packet_in_use_) { LOG(LS_WARNING) << "Multiple RTX headers detected, dropping packet."; return false; } uint8_t* restored_packet_ptr = restored_packet_; if (!rtp_payload_registry_->RestoreOriginalPacket( &restored_packet_ptr, packet, &packet_length, rtp_receiver_->SSRC(), header)) { LOG(LS_WARNING) << "Incoming RTX packet: Invalid RTP header"; return false; } restored_packet_in_use_ = true; bool ret = OnRecoveredPacket(restored_packet_ptr, packet_length); restored_packet_in_use_ = false; return ret; } return false; } int ViEReceiver::InsertRTCPPacket(const uint8_t* rtcp_packet, int rtcp_packet_length) { { CriticalSectionScoped cs(receive_cs_.get()); if (!receiving_) { return -1; } if (rtp_dump_) { rtp_dump_->DumpPacket( rtcp_packet, static_cast(rtcp_packet_length)); } std::list::iterator it = rtp_rtcp_simulcast_.begin(); while (it != rtp_rtcp_simulcast_.end()) { RtpRtcp* rtp_rtcp = *it++; rtp_rtcp->IncomingRtcpPacket(rtcp_packet, rtcp_packet_length); } } assert(rtp_rtcp_); // Should be set by owner at construction time. int ret = rtp_rtcp_->IncomingRtcpPacket(rtcp_packet, rtcp_packet_length); if (ret != 0) { return ret; } ntp_estimator_->UpdateRtcpTimestamp(rtp_receiver_->SSRC(), rtp_rtcp_); return 0; } void ViEReceiver::StartReceive() { CriticalSectionScoped cs(receive_cs_.get()); receiving_ = true; } void ViEReceiver::StopReceive() { CriticalSectionScoped cs(receive_cs_.get()); receiving_ = false; } int ViEReceiver::StartRTPDump(const char file_nameUTF8[1024]) { CriticalSectionScoped cs(receive_cs_.get()); if (rtp_dump_) { // Restart it if it already exists and is started rtp_dump_->Stop(); } else { rtp_dump_ = RtpDump::CreateRtpDump(); if (rtp_dump_ == NULL) { return -1; } } if (rtp_dump_->Start(file_nameUTF8) != 0) { RtpDump::DestroyRtpDump(rtp_dump_); rtp_dump_ = NULL; return -1; } return 0; } int ViEReceiver::StopRTPDump() { CriticalSectionScoped cs(receive_cs_.get()); if (rtp_dump_) { if (rtp_dump_->IsActive()) { rtp_dump_->Stop(); } RtpDump::DestroyRtpDump(rtp_dump_); rtp_dump_ = NULL; } else { return -1; } return 0; } void ViEReceiver::GetReceiveBandwidthEstimatorStats( ReceiveBandwidthEstimatorStats* output) const { remote_bitrate_estimator_->GetStats(output); } ReceiveStatistics* ViEReceiver::GetReceiveStatistics() const { return rtp_receive_statistics_.get(); } bool ViEReceiver::IsPacketInOrder(const RTPHeader& header) const { StreamStatistician* statistician = rtp_receive_statistics_->GetStatistician(header.ssrc); if (!statistician) return false; return statistician->IsPacketInOrder(header.sequenceNumber); } bool ViEReceiver::IsPacketRetransmitted(const RTPHeader& header, bool in_order) const { // Retransmissions are handled separately if RTX is enabled. if (rtp_payload_registry_->RtxEnabled()) return false; StreamStatistician* statistician = rtp_receive_statistics_->GetStatistician(header.ssrc); if (!statistician) return false; // Check if this is a retransmission. uint16_t min_rtt = 0; rtp_rtcp_->RTT(rtp_receiver_->SSRC(), NULL, NULL, &min_rtt, NULL); return !in_order && statistician->IsRetransmitOfOldPacket(header, min_rtt); } } // namespace webrtc