/* * Copyright (c) 2016-present The ZLMediaKit project authors. All Rights Reserved. * * This file is part of ZLMediaKit(https://github.com/ZLMediaKit/ZLMediaKit). * * Use of this source code is governed by MIT-like license that can be found in the * LICENSE file in the root of the source tree. All contributing project authors * may be found in the AUTHORS file in the root of the source tree. */ #include "SrtCaller.h" #include "srt/Ack.hpp" #include "srt/SrtTransport.hpp" #include "Common/config.h" #include "Common/Parser.h" #include using namespace toolkit; using namespace std; using namespace SRT; namespace mediakit { //zlm play format //srt://127.0.0.1:9000?streamid=#!::r=live/test //srt://127.0.0.1:9000?streamid=#!::r=live/test,h=__defaultVhost__ //zlm push format //srt://127.0.0.1:9000?streamid=#!::r=live/test,m=publish //srt://127.0.0.1:9000?streamid=#!::r=live/test,h=__defaultVhost__,m=publish void SrtUrl::parse(const string &strUrl) { //DebugL << "url: " << strUrl; _full_url = strUrl; auto url = strUrl; auto ip = findSubString(url.data(), "://", "?"); splitUrl(ip, _host, _port); auto _params = findSubString(url.data(), "?" , NULL); auto kv = Parser::parseArgs(_params); auto it = kv.find("streamid"); if (it != kv.end()) { auto streamid = it->second; if (!toolkit::start_with(streamid, "#!::")) { return; } _streamid = streamid; } //TraceL << "ip: " << ip; //TraceL << "_host: " << _host; //TraceL << "_port: " << _port; //TraceL << "_params: " << _params; //TraceL << "_streamid: " << _streamid; return; } //////////// SrtCaller ////////////////////////// SrtCaller::SrtCaller(const toolkit::EventPoller::Ptr &poller) { _poller = poller ? std::move(poller) : EventPollerPool::Instance().getPoller(); _start_timestamp = SteadyClock::now(); _socket_id = generateSocketId(); /* _init_seq_number = generateInitSeq(); */ _init_seq_number = 0; _last_pkt_seq = _init_seq_number - 1; _pkt_recv_rate_context = std::make_shared(_start_timestamp); _estimated_link_capacity_context = std::make_shared(_start_timestamp); _estimated_link_capacity_context->setLastSeq(_last_pkt_seq); _send_packet_seq_number = _init_seq_number; } SrtCaller::~SrtCaller(void) { DebugL; } void SrtCaller::onConnect() { //DebugL; auto peer_addr = SockUtil::make_sockaddr(_url._host.c_str(), (_url._port)); _socket = Socket::createSocket(_poller, false); _socket->bindUdpSock(0, SockUtil::is_ipv4(_url._host.data()) ? "0.0.0.0" : "::"); _socket->bindPeerAddr((struct sockaddr *)&peer_addr, 0, true); weak_ptr weak_self = shared_from_this(); _socket->setOnRead([weak_self](const Buffer::Ptr &buf, struct sockaddr *addr, int addr_len) mutable { auto strong_self = weak_self.lock(); if (!strong_self) { return; } strong_self->inputSockData((uint8_t*)buf->data(), buf->size(), addr); }); doHandshake(); } void SrtCaller::onResult(const SockException &ex) { if (!ex) { // 会话建立成功 } else { if (ex.getErrCode() == Err_shutdown) { // 主动shutdown的，不触发回调 return; } if (_socket && _is_handleshake_finished) { sendShutDown(); } _is_handleshake_finished = false; _handleshake_timer.reset(); _keeplive_timer.reset(); _announce_timer.reset(); } return; } void SrtCaller::onHandShakeFinished() { DebugL; _is_handleshake_finished = true; if (_handleshake_timer) { _handleshake_timer.reset(); } _handleshake_req = nullptr; std::weak_ptr weak_self = std::static_pointer_cast(shared_from_this()); _keeplive_timer = std::make_shared(0.2, [weak_self]()->bool{ auto strong_self = weak_self.lock(); if (!strong_self) { return false; } //Keep-alive control packets are sent after a certain timeout from the last time any packet (Control or Data) was sent. //The default timeout for a keep-alive packet to be sent is 1 second. if (strong_self->_send_ticker.elapsedTime() > 1000) { strong_self->sendKeepLivePacket(); } return true; }, getPoller()); return; } void SrtCaller::onSRTData(DataPacket::Ptr pkt) { InfoL; if (!isPlayer()) { WarnL << "this is not a player data ignore"; return; } } void SrtCaller::onSendTSData(const Buffer::Ptr &buffer, bool flush) { // TraceL; // DataPacket::Ptr pkt; size_t payloadSize = getPayloadSize(); size_t size = buffer->size(); char *ptr = buffer->data(); char *end = buffer->data() + size; while (ptr < end && size >= payloadSize) { pkt = std::make_shared(); pkt->f = 0; pkt->packet_seq_number = _send_packet_seq_number & 0x7fffffff; _send_packet_seq_number = (_send_packet_seq_number + 1) & 0x7fffffff; pkt->PP = 3; pkt->O = 0; pkt->KK = 0; pkt->R = 0; pkt->msg_number = _send_msg_number++; pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(SteadyClock::now() - _start_timestamp); sendDataPacket(pkt, ptr, (int)payloadSize, flush); ptr += payloadSize; size -= payloadSize; } if (size > 0 && ptr < end) { pkt = std::make_shared(); pkt->f = 0; pkt->packet_seq_number = _send_packet_seq_number & 0x7fffffff; _send_packet_seq_number = (_send_packet_seq_number + 1) & 0x7fffffff; pkt->PP = 3; pkt->O = 0; pkt->KK = 0; pkt->R = 0; pkt->msg_number = _send_msg_number++; pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(SteadyClock::now() - _start_timestamp); sendDataPacket(pkt, ptr, (int)size, flush); } } void SrtCaller::inputSockData(uint8_t *buf, int len, struct sockaddr *addr) { //TraceL << hexdump((void*)buf, len); using srt_control_handler = void (SrtCaller::*)(uint8_t * buf, int len, struct sockaddr *addr); static std::unordered_map s_control_functions; static onceToken token([]() { s_control_functions.emplace(SRT::ControlPacket::HANDSHAKE, &SrtCaller::handleHandshake); s_control_functions.emplace(SRT::ControlPacket::ACK, &SrtCaller::handleACK); s_control_functions.emplace(SRT::ControlPacket::ACKACK, &SrtCaller::handleACKACK); s_control_functions.emplace(SRT::ControlPacket::NAK, &SrtCaller::handleNAK); s_control_functions.emplace(SRT::ControlPacket::DROPREQ, &SrtCaller::handleDropReq); s_control_functions.emplace(SRT::ControlPacket::KEEPALIVE, &SrtCaller::handleKeeplive); s_control_functions.emplace(SRT::ControlPacket::SHUTDOWN, &SrtCaller::handleShutDown); s_control_functions.emplace(SRT::ControlPacket::PEERERROR, &SrtCaller::handlePeerError); s_control_functions.emplace(SRT::ControlPacket::CONGESTIONWARNING, &SrtCaller::handleCongestionWarning); s_control_functions.emplace(SRT::ControlPacket::USERDEFINEDTYPE, &SrtCaller::handleUserDefinedType); }); _alive_ticker.resetTime(); _now = SteadyClock::now(); // 处理srt数据 if (DataPacket::isDataPacket(buf, len)) { if (_is_handleshake_finished && isPlayer()) { uint32_t socketId = DataPacket::getSocketID(buf, len); if (socketId == _socket_id) { _pkt_recv_rate_context->inputPacket(_now, len + UDP_HDR_SIZE); handleDataPacket(buf, len, addr); checkAndSendAckNak(); } } } else if (ControlPacket::isControlPacket(buf, len)) { uint32_t socketId = ControlPacket::getSocketID(buf, len); uint16_t type = ControlPacket::getControlType(buf, len); auto it = s_control_functions.find(type); if (it == s_control_functions.end()) { WarnL << " not support type ignore: " << ControlPacket::getControlType(buf, len); return; } else { (this->*(it->second))(buf, len, addr); } if (_is_handleshake_finished && isPlayer()){ checkAndSendAckNak(); } } else { // not reach WarnL << "not reach this"; } } void SrtCaller::doHandshake() { _alive_ticker.resetTime(); if (!_alive_timer) { createTimerForCheckAlive(); } if (!getPassphrase().empty()) { _crypto = std::make_shared(getPassphrase()); } sendHandshakeInduction(); return; } void SrtCaller::sendHandshakeInduction() { DebugL; _induction_ts = SteadyClock::now(); SRT::HandshakePacket::Ptr req = std::make_shared(); req->timestamp = DurationCountMicroseconds(_induction_ts - _start_timestamp); req->dst_socket_id = 0; req->version = 4; req->encryption_field = 0; req->extension_field = 0x0002; req->initial_packet_sequence_number = _init_seq_number; req->mtu = _mtu; req->max_flow_window_size = _max_flow_window_size; req->handshake_type = SRT::HandshakePacket::HS_TYPE_INDUCTION; req->srt_socket_id = _socket_id; req->syn_cookie = 0; auto dataSenderAddr = SockUtil::make_sockaddr(_url._host.c_str(), _url._port); req->assignPeerIPBE(&dataSenderAddr); req->storeToData(); _handleshake_req = req; sendControlPacket(req, true); std::weak_ptr weak_self = std::static_pointer_cast(shared_from_this()); _handleshake_timer = std::make_shared(0.2, [weak_self]()->bool{ auto strong_self = weak_self.lock(); if (!strong_self) { return false; } if (strong_self->_is_handleshake_finished) { return false; } strong_self->sendControlPacket(strong_self->_handleshake_req, true); return true; }, getPoller()); return; } void SrtCaller::sendHandshakeConclusion() { DebugL; SRT::HandshakePacket::Ptr req = std::make_shared(); req->timestamp = DurationCountMicroseconds(_now - _start_timestamp); req->dst_socket_id = 0; req->version = 5; req->encryption_field = SRT::HandshakePacket::NO_ENCRYPTION; req->extension_field = HandshakePacket::HS_EXT_FILED_HSREQ | HandshakePacket::HS_EXT_FILED_CONFIG; if (_crypto) { //The default value is 0 (no encryption advertised). //If neither peer advertises encryption, AES-128 is selected by default /* req->encryption_field = SRT::HandshakePacket::AES_128; */ req->extension_field |= HandshakePacket::HS_EXT_FILED_KMREQ; } req->initial_packet_sequence_number = _init_seq_number; req->mtu = _mtu; req->max_flow_window_size = _max_flow_window_size; req->handshake_type = SRT::HandshakePacket::HS_TYPE_CONCLUSION; req->srt_socket_id = _socket_id; req->syn_cookie = _sync_cookie; auto addr = SockUtil::make_sockaddr(_url._host.c_str(), _url._port); req->assignPeerIPBE(&addr); HSExtMessage::Ptr ext = std::make_shared(); ext->extension_type = HSExt::SRT_CMD_HSREQ; ext->srt_version = srtVersion(1, 5, 0); ext->srt_flag = 0xbf; // if set latency, use set value _delay = getLatency(); if (0 == _delay) { //The value of minimum TsbpdDelay is negotiated during the SRT handshake exchange and is equal to 120 milliseconds. //The recommended value of TsbpdDelay is 3-4 times RTT. _delay = DurationCountMicroseconds(_now - _induction_ts) * getLatencyMul() / 1000; if (_delay <= 120) { _delay = 120; } } ext->recv_tsbpd_delay = _delay; ext->send_tsbpd_delay = _delay; req->ext_list.push_back(std::move(ext)); HSExtStreamID::Ptr extStreamId = std::make_shared(); extStreamId->streamid = generateStreamId(); req->ext_list.push_back(std::move(extStreamId)); if (_crypto) { HSExtKeyMaterial::Ptr keyMaterial = _crypto->generateKeyMaterialExt(HSExt::SRT_CMD_KMREQ); req->ext_list.push_back(std::move(keyMaterial)); } req->storeToData(); _handleshake_req = req; sendControlPacket(req); return; } void SrtCaller::sendACKPacket() { uint32_t recv_rate = 0; SRT::ACKPacket::Ptr pkt = std::make_shared(); pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(_now - _start_timestamp); pkt->ack_number = ++_ack_number_count; pkt->last_ack_pkt_seq_number = _recv_buf->getExpectedSeq(); pkt->rtt = _rtt; pkt->rtt_variance = _rtt_variance; pkt->available_buf_size = _recv_buf->getAvailableBufferSize(); pkt->pkt_recv_rate = _pkt_recv_rate_context->getPacketRecvRate(recv_rate); pkt->estimated_link_capacity = _estimated_link_capacity_context->getEstimatedLinkCapacity(); pkt->recv_rate = recv_rate; if(0){ TraceL<pkt_recv_rate<<" pkt/s "<estimated_link_capacity<<" pkt/s (cap) "<available_buf_size<<" available buf"; //TraceL<<_pkt_recv_rate_context->dump(); //TraceL<<"recv estimated:"; //TraceL<< _pkt_recv_rate_context->dump(); //TraceL<<"recv queue:"; //TraceL<<_recv_buf->dump(); } if (pkt->available_buf_size < 2) { pkt->available_buf_size = 2; } pkt->storeToData(); _ack_send_timestamp[pkt->ack_number] = _now; _last_ack_pkt_seq = pkt->last_ack_pkt_seq_number; sendControlPacket(pkt, true); // TraceL<<"send ack "<dump(); // TraceL<<_recv_buf->dump(); return; } void SrtCaller::sendLightACKPacket() { ACKPacket::Ptr pkt = std::make_shared(); pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(_now - _start_timestamp); pkt->ack_number = 0; pkt->last_ack_pkt_seq_number = _recv_buf->getExpectedSeq(); pkt->rtt = 0; pkt->rtt_variance = 0; pkt->available_buf_size = 0; pkt->pkt_recv_rate = 0; pkt->estimated_link_capacity = 0; pkt->recv_rate = 0; pkt->storeToData(); _last_ack_pkt_seq = pkt->last_ack_pkt_seq_number; sendControlPacket(pkt, true); TraceL << "send ack " << pkt->dump(); return; } void SrtCaller::sendNAKPacket(std::list &lost_list) { SRT::NAKPacket::Ptr pkt = std::make_shared(); std::list tmp; auto size = SRT::NAKPacket::getCIFSize(lost_list); size_t paylaod_size = getPayloadSize(); if (size > paylaod_size) { WarnL << "loss report cif size " << size; size_t num = paylaod_size / 8; size_t msgNum = (lost_list.size() + num - 1) / num; decltype(lost_list.begin()) cur, next; for (size_t i = 0; i < msgNum; ++i) { cur = lost_list.begin(); std::advance(cur, i * num); if (i == msgNum - 1) { next = lost_list.end(); } else { next = lost_list.begin(); std::advance(next, (i + 1) * num); } tmp.assign(cur, next); pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(_now - _start_timestamp); pkt->lost_list = tmp; pkt->storeToData(); sendControlPacket(pkt, true); } } else { pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(_now - _start_timestamp); pkt->lost_list = lost_list; pkt->storeToData(); sendControlPacket(pkt, true); } // TraceL<<"send NAK "<dump(); return; } void SrtCaller::sendMsgDropReq(uint32_t first, uint32_t last) { MsgDropReqPacket::Ptr pkt = std::make_shared(); pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(_now - _start_timestamp); pkt->first_pkt_seq_num = first; pkt->last_pkt_seq_num = last; pkt->storeToData(); sendControlPacket(pkt, true); return; } void SrtCaller::sendKeepLivePacket() { auto now = SteadyClock::now(); SRT::KeepLivePacket::Ptr req = std::make_shared(); req->timestamp = SRT::DurationCountMicroseconds(now - _start_timestamp); req->dst_socket_id = _peer_socket_id; req->storeToData(); sendControlPacket(req, true); return; } void SrtCaller::sendShutDown() { auto now = SteadyClock::now(); ShutDownPacket::Ptr pkt = std::make_shared(); pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = SRT::DurationCountMicroseconds(now - _start_timestamp); pkt->storeToData(); sendControlPacket(pkt, true); return; } void SrtCaller::tryAnnounceKeyMaterial() { //TraceL; if (!_crypto) { return; } auto pkt = _crypto->takeAwayAnnouncePacket(); if (!pkt) { return; } auto now = SteadyClock::now(); pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = SRT::DurationCountMicroseconds(now - _start_timestamp); pkt->storeToData(); _announce_req = pkt; sendControlPacket(pkt, true); std::weak_ptr weak_self = std::static_pointer_cast(shared_from_this()); _announce_timer = std::make_shared(0.2, [weak_self]()->bool{ auto strong_self = weak_self.lock(); if (!strong_self) { return false; } if (!strong_self->_announce_req) { return false; } strong_self->sendControlPacket(strong_self->_announce_req, true); return true; }, getPoller()); return; } void SrtCaller::sendControlPacket(SRT::ControlPacket::Ptr pkt, bool flush) { //TraceL; sendPacket(pkt, flush); return; } void SrtCaller::sendDataPacket(SRT::DataPacket::Ptr pkt, char *buf, int len, bool flush) { auto data = buf; auto size = len; BufferLikeString::Ptr payload; if (_crypto) { payload = _crypto->encrypt(pkt, const_cast(buf), len); if (!payload) { WarnL << "encrypt pkt->packet_seq_number: " << pkt->packet_seq_number << ", timestamp: " << "pkt->timestamp " << " fail"; return; } data = payload->data(); size = payload->size(); tryAnnounceKeyMaterial(); } pkt->storeToData((uint8_t *)data, size); sendPacket(pkt, flush); _send_buf->inputPacket(pkt); return; } void SrtCaller::sendPacket(Buffer::Ptr pkt, bool flush) { //TraceL << pkt->size(); auto tmp = _packet_pool.obtain2(); tmp->assign(pkt->data(), pkt->size()); _socket->send(std::move(tmp), nullptr, 0, flush); _send_ticker.resetTime(); return; } void SrtCaller::handleHandshake(uint8_t *buf, int len, struct sockaddr *addr) { //DebugL; SRT::HandshakePacket pkt; if(!pkt.loadFromData(buf, len)){ WarnL<< "is not vaild HandshakePacket"; return; } if (pkt.handshake_type == SRT::HandshakePacket::HS_TYPE_INDUCTION) { handleHandshakeInduction(pkt, addr); } else if (pkt.handshake_type == SRT::HandshakePacket::HS_TYPE_CONCLUSION) { handleHandshakeConclusion(pkt, addr); } else if (pkt.isReject()){ onResult(SockException(Err_other, StrPrinter << "handshake fail, reject resaon: " << pkt.handshake_type << ", " << SRT::getRejectReason((SRT_REJECT_REASON)pkt.handshake_type))); return; } else { WarnL << " not support handshake type = " << pkt.handshake_type; WarnL << pkt.dump(); } _ack_ticker.resetTime(_now); _nak_ticker.resetTime(_now); return; } void SrtCaller::handleHandshakeInduction(SRT::HandshakePacket &pkt, struct sockaddr *addr) { DebugL; if (!_handleshake_req) { WarnL << "must Induction Phase for handleshake"; return; } if (_handleshake_req->handshake_type == HandshakePacket::HS_TYPE_CONCLUSION) { WarnL << "should be Conclusion Phase for handleshake "; return; } else if (_handleshake_req->handshake_type != HandshakePacket::HS_TYPE_INDUCTION) { WarnL <<"not reach this"; return; } // Induction Phase if (pkt.version != 5) { WarnL << "not support handleshake version: " << pkt.version; return; } if (pkt.extension_field != 0x4A17) { WarnL << "not match SRT MAGIC"; return; } if (pkt.dst_socket_id != _handleshake_req->srt_socket_id) { WarnL << "not match _socket_id"; return; } // TODO: encryption_field _sync_cookie = pkt.syn_cookie; _mtu = std::min(pkt.mtu, _mtu); _max_flow_window_size = std::min(pkt.max_flow_window_size, _max_flow_window_size); sendHandshakeConclusion(); return; } void SrtCaller::handleHandshakeConclusion(SRT::HandshakePacket &pkt, struct sockaddr *addr) { DebugL; if (!_handleshake_req) { WarnL << "must Conclusion Phase for handleshake "; return; } if (_handleshake_req->handshake_type == HandshakePacket::HS_TYPE_INDUCTION) { WarnL << "should be Conclusion Phase for handleshake "; return; } else if (_handleshake_req->handshake_type != HandshakePacket::HS_TYPE_CONCLUSION) { WarnL <<"not reach this"; return; } // Conclusion Phase if (pkt.version != 5) { WarnL << "not support handleshake version: " << pkt.version; return; } if (pkt.dst_socket_id != _handleshake_req->srt_socket_id) { WarnL << "not match _socket_id"; return; } // TODO: encryption_field _peer_socket_id = pkt.srt_socket_id; HSExtMessage::Ptr resp; HSExtKeyMaterial::Ptr keyMaterial; for (auto& ext : pkt.ext_list) { if (!resp) { resp = std::dynamic_pointer_cast(ext); } if (!keyMaterial) { keyMaterial = std::dynamic_pointer_cast(ext); } } if (resp) { _delay = std::max(_delay, resp->recv_tsbpd_delay); //DebugL << "flag " << resp->srt_flag; //DebugL << "recv_tsbpd_delay " << resp->recv_tsbpd_delay; //DebugL << "send_tsbpd_delay " << resp->send_tsbpd_delay; } if (keyMaterial && _crypto) { _crypto->loadFromKeyMaterial(keyMaterial); } if (isPlayer()) { //The recommended threshold value is 1.25 times the SRT latency value. _recv_buf = std::make_shared(getPktBufSize(), _init_seq_number, _delay * 1250, resp->srt_flag); } else { //The recommended threshold value is 1.25 times the SRT latency value. //Note that the SRT sender keeps packets for at least 1 second in case the latency is not high enough for a large RTT _send_buf = std::make_shared(getPktBufSize(), std::min((uint32_t)_delay * 1250, 1000000), resp->srt_flag); } onHandShakeFinished(); return; } void SrtCaller::handleACK(uint8_t *buf, int len, struct sockaddr *addr) { // TraceL; //Acknowledgement of Acknowledgement (ACKACK) control packets are sent to acknowledge the reception of a Full ACK if (!_is_handleshake_finished) { return; } ACKPacket ack; if (!ack.loadFromData(buf, len)) { return; } ACKACKPacket::Ptr pkt = std::make_shared(); pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(_now - _start_timestamp); pkt->ack_number = ack.ack_number; pkt->storeToData(); if (_send_buf) { _send_buf->drop(ack.last_ack_pkt_seq_number); } sendControlPacket(pkt, true); // TraceL<<"ack number "<(); pkt->loadFromData(buf, len); if(_ack_send_timestamp.find(pkt->ack_number) != _ack_send_timestamp.end()){ uint32_t rtt = DurationCountMicroseconds(_now - _ack_send_timestamp[pkt->ack_number]); _rtt_variance = (3 * _rtt_variance + abs((long)_rtt - (long)rtt)) / 4; _rtt = (7 * rtt + _rtt) / 8; // TraceL<<" rtt:"<<_rtt<<" rtt variance:"<<_rtt_variance; _ack_send_timestamp.erase(pkt->ack_number); if(_last_recv_ackack_seq_num < pkt->ack_number){ _last_recv_ackack_seq_num = pkt->ack_number; }else{ if((_last_recv_ackack_seq_num-pkt->ack_number)>(MAX_TS>>1)){ _last_recv_ackack_seq_num = pkt->ack_number; } } if(_ack_send_timestamp.size()>1000){ // clear data for(auto it = _ack_send_timestamp.begin(); it != _ack_send_timestamp.end();){ if(DurationCountMicroseconds(_now-it->second)>5e6){ // 超过五秒没有ackack 丢弃 it = _ack_send_timestamp.erase(it); }else{ it++; } } } } return; } void SrtCaller::handleNAK(uint8_t *buf, int len, struct sockaddr *addr) { if (!_is_handleshake_finished) { return; } if (isPlayer()) { //player should not handle nak return; } //TraceL; NAKPacket pkt; pkt.loadFromData(buf, len); bool empty = false; bool flush = false; for (auto& it : pkt.lost_list) { if (pkt.lost_list.back() == it) { flush = true; } empty = true; auto re_list = _send_buf->findPacketBySeq(it.first, it.second - 1); for (auto& pkt : re_list) { pkt->R = 1; pkt->storeToHeader(); sendPacket(pkt, flush); empty = false; } if (empty) { sendMsgDropReq(it.first, it.second - 1); } } return; } void SrtCaller::handleDropReq(uint8_t *buf, int len, struct sockaddr *addr) { if (!_is_handleshake_finished) { return; } if (!isPlayer()) { //pusher should not handle drop req return; } MsgDropReqPacket pkt; pkt.loadFromData(buf, len); std::list list; // TraceL<<"drop "<drop(pkt.first_pkt_seq_num, pkt.last_pkt_seq_num, list); //checkAndSendAckNak(); if (list.empty()) { return; } // uint32_t max_seq = 0; for (auto& data : list) { // max_seq = data->packet_seq_number; if (_last_pkt_seq + 1 != data->packet_seq_number) { TraceL << "pkt lost " << _last_pkt_seq + 1 << "->" << data->packet_seq_number; } _last_pkt_seq = data->packet_seq_number; onSRTData(std::move(data)); } return; } void SrtCaller::handleKeeplive(uint8_t *buf, int len, struct sockaddr *addr) { // TraceL; return; } void SrtCaller::handleShutDown(uint8_t *buf, int len, struct sockaddr *addr) { TraceL; onResult(SockException(Err_other, "peer close connection")); return; } void SrtCaller::handlePeerError(uint8_t *buf, int len, struct sockaddr *addr) { TraceL; return; } void SrtCaller::handleCongestionWarning(uint8_t *buf, int len, struct sockaddr *addr) { TraceL; return; } void SrtCaller::handleUserDefinedType(uint8_t *buf, int len, struct sockaddr *addr) { /* TraceL; */ using srt_userd_defined_handler = void (SrtCaller::*)(uint8_t * buf, int len, struct sockaddr *addr); static std::unordered_map s_userd_defined_functions; static onceToken token([]() { s_userd_defined_functions.emplace(SRT::HSExt::SRT_CMD_KMREQ, &SrtCaller::handleKeyMaterialReqPacket); s_userd_defined_functions.emplace(SRT::HSExt::SRT_CMD_KMRSP, &SrtCaller::handleKeyMaterialRspPacket); }); uint16_t subtype = ControlPacket::getSubType(buf, len); auto it = s_userd_defined_functions.find(subtype); if (it == s_userd_defined_functions.end()) { WarnL << " not support subtype in user defined msg ignore: " << subtype; return; } else { (this->*(it->second))(buf, len, addr); } return; } void SrtCaller::handleKeyMaterialReqPacket(uint8_t *buf, int len, struct sockaddr *addr) { /* TraceL; */ if (!_crypto) { WarnL << " not enable crypto, ignore"; return; } KeyMaterialPacket::Ptr pkt = std::make_shared(); pkt->loadFromData(buf, len); _crypto->loadFromKeyMaterial(pkt); //rsp pkt->sub_type = SRT::HSExt::SRT_CMD_KMRSP; pkt->dst_socket_id = _peer_socket_id; pkt->timestamp = DurationCountMicroseconds(_now - _start_timestamp); pkt->storeToData(); sendControlPacket(pkt, true); return; } void SrtCaller::handleKeyMaterialRspPacket(uint8_t *buf, int len, struct sockaddr *addr) { /* TraceL; */ _announce_req = nullptr; return; } void SrtCaller::handleDataPacket(uint8_t *buf, int len, struct sockaddr *addr) { //TraceL; DataPacket::Ptr pkt = std::make_shared(); pkt->loadFromData(buf, len); if (_crypto) { auto payload = _crypto->decrypt(pkt, pkt->payloadData(), pkt->payloadSize()); if (!payload) { WarnL << "decrypt pkt->packet_seq_number: " << pkt->packet_seq_number << ", timestamp: " << "pkt->timestamp " << " fail"; return; } pkt->reloadPayload((uint8_t*)payload->data(), payload->size()); } _estimated_link_capacity_context->inputPacket(_now, pkt); std::list list; _recv_buf->inputPacket(pkt, list); for (auto& data : list) { if (_last_pkt_seq + 1 != data->packet_seq_number) { TraceL << "pkt lost " << _last_pkt_seq + 1 << "->" << data->packet_seq_number; } _last_pkt_seq = data->packet_seq_number; onSRTData(std::move(data)); } return; } void SrtCaller::checkAndSendAckNak() { //SRT Periodic NAK reports are sent with a period of (RTT + 4 * RTTVar) / 2 (so called NAKInterval), //with a 20 milliseconds floor auto nak_interval = (_rtt + _rtt_variance * 4) / 2; if (nak_interval <= 20 * 1000) { nak_interval = 20 * 1000; } if (_nak_ticker.elapsedTime(_now) > nak_interval) { auto lost = _recv_buf->getLostSeq(); if (!lost.empty()) { sendNAKPacket(lost); } _nak_ticker.resetTime(_now); } //A Full ACK control packet is sent every 10 ms if (_ack_ticker.elapsedTime(_now) > 10 * 1000) { _light_ack_pkt_count = 0; _ack_ticker.resetTime(_now); // send a ack per 10 ms for receiver if(_last_ack_pkt_seq != _recv_buf->getExpectedSeq()){ //TraceL<<"send a ack packet"; sendACKPacket(); } else{ //TraceL<<" ignore repeate ack packet"; } } else { //The recommendation is to send a Light ACK for every 64 packets received. if (_light_ack_pkt_count >= 64) { // for high bitrate stream send light ack // TODO sendLightACKPacket(); TraceL << "send light ack"; } _light_ack_pkt_count = 0; } _light_ack_pkt_count++; return; } void SrtCaller::createTimerForCheckAlive(){ std::weak_ptr weak_self = std::static_pointer_cast(shared_from_this()); auto timeoutSec = getTimeOutSec(); _alive_timer = std::make_shared( timeoutSec /2, [weak_self,timeoutSec]() { auto strong_self = weak_self.lock(); if (!strong_self) { return false; } if (strong_self->_alive_ticker.elapsedTime() > timeoutSec * 1000) { strong_self->onResult(SockException(Err_timeout, "Receive srt socket data timeout")); return false; } return true; }, getPoller()); return; } int SrtCaller::getLatencyMul() { GET_CONFIG(int, latencyMul, SRT::kLatencyMul); if (latencyMul < 0) { WarnL << "config srt " << kLatencyMul << " not vaild"; return 4; } return latencyMul; } int SrtCaller::getPktBufSize() { GET_CONFIG(int, pktBufSize, SRT::kPktBufSize); if (pktBufSize <= 0) { WarnL << "config srt " << kPktBufSize << " not vaild"; return 8912; } return pktBufSize; } float SrtCaller::getTimeOutSec() { GET_CONFIG(uint32_t, timeout, SRT::kTimeOutSec); if (timeout <= 0) { WarnL << "config srt " << kTimeOutSec << " not vaild"; return 5.0f; } return (float)timeout; }; std::string SrtCaller::generateStreamId() { return _url._streamid; }; uint32_t SrtCaller::generateSocketId() { // 生成一个 32 位的随机整数 std::random_device rd; std::mt19937 mt(rd()); std::uniform_int_distribution dist(0, UINT32_MAX); uint32_t id = dist(mt); return id; } int32_t SrtCaller::generateInitSeq() { // 生成一个 32 位的随机整数 std::random_device rd; std::mt19937 mt(rd()); std::uniform_int_distribution dist(0, MAX_SEQ); int32_t id = dist(mt); return id; } size_t SrtCaller::getPayloadSize() { size_t ret = (_mtu - 28 - 16) / 188 * 188; return ret; } size_t SrtCaller::getRecvSpeed() const { return _socket ? _socket->getRecvSpeed() : 0; } size_t SrtCaller::getRecvTotalBytes() const { return _socket ? _socket->getRecvTotalBytes() : 0; } size_t SrtCaller::getSendSpeed() const { return _socket ? _socket->getSendSpeed() : 0; } size_t SrtCaller::getSendTotalBytes() const { return _socket ? _socket->getSendTotalBytes() : 0; } } /* namespace mediakit */