package buffer import ( "encoding/binary" "io" "strings" "sync" "sync/atomic" "time" "github.com/gammazero/deque" "github.com/go-logr/logr" "github.com/pion/rtcp" "github.com/pion/rtp" "github.com/pion/sdp/v3" "github.com/pion/webrtc/v3" ) const ( ReportDelta = 1e9 ) // Logger is an implementation of logr.Logger. If is not provided - will be turned off. var Logger = logr.Discard() type pendingPackets struct { arrivalTime int64 packet []byte } type ExtPacket struct { Head bool Arrival int64 Packet rtp.Packet Payload interface{} KeyFrame bool // audio level for voice, l&0x80 == 0 means audio level not present AudioLevel uint8 RawPacket []byte } // Buffer contains all packets type Buffer struct { sync.Mutex bucket *Bucket nacker *NackQueue videoPool *sync.Pool audioPool *sync.Pool codecType webrtc.RTPCodecType extPackets deque.Deque pPackets []pendingPackets closeOnce sync.Once mediaSSRC uint32 clockRate uint32 maxBitrate int64 lastReport int64 twccExt uint8 audioExt uint8 bound bool closed atomicBool mime string // supported feedbacks remb bool nack bool twcc bool audioLevel bool minPacketProbe int lastPacketRead int bitrate atomic.Value bitrateHelper [4]int64 lastSRNTPTime uint64 lastSRRTPTime uint32 lastSRRecv int64 // Represents wall clock of the most recent sender report arrival baseSN uint16 lastRtcpPacketTime int64 // Time the last RTCP packet was received. lastRtcpSrTime int64 // Time the last RTCP SR was received. Required for DLSR computation. lastTransit uint32 seqHdlr SeqWrapHandler stats Stats latestTimestamp uint32 // latest received RTP timestamp on packet latestTimestampTime int64 // Time of the latest timestamp (in nanos since unix epoch) lastFractionLostToReport uint8 // Last fractionlost from subscribers, should report to publisher; Audio only // callbacks onClose func() onAudioLevel func(level uint8, durationMs uint32) feedbackCB func([]rtcp.Packet) feedbackTWCC func(sn uint16, timeNS int64, marker bool) // logger logger logr.Logger } type Stats struct { LastExpected uint32 LastReceived uint32 LostRate float32 PacketCount uint32 // Number of packets received from this source. Jitter float64 // An estimate of the statistical variance of the RTP data packet inter-arrival time. TotalByte uint64 } // BufferOptions provides configuration options for the buffer type Options struct { MaxBitRate uint64 } // NewBuffer constructs a new Buffer func NewBuffer(ssrc uint32, vp, ap *sync.Pool, logger logr.Logger) *Buffer { b := &Buffer{ mediaSSRC: ssrc, videoPool: vp, audioPool: ap, logger: logger, } b.bitrate.Store(make([]int64, len(b.bitrateHelper))) b.extPackets.SetMinCapacity(7) return b } func (b *Buffer) Bind(params webrtc.RTPParameters, codec webrtc.RTPCodecCapability, o Options) { b.Lock() defer b.Unlock() b.clockRate = codec.ClockRate b.maxBitrate = int64(o.MaxBitRate) b.mime = strings.ToLower(codec.MimeType) switch { case strings.HasPrefix(b.mime, "audio/"): b.codecType = webrtc.RTPCodecTypeAudio b.bucket = NewBucket(b.audioPool.Get().(*[]byte)) case strings.HasPrefix(b.mime, "video/"): b.codecType = webrtc.RTPCodecTypeVideo b.bucket = NewBucket(b.videoPool.Get().(*[]byte)) default: b.codecType = webrtc.RTPCodecType(0) } for _, ext := range params.HeaderExtensions { if ext.URI == sdp.TransportCCURI { b.twccExt = uint8(ext.ID) break } } if b.codecType == webrtc.RTPCodecTypeVideo { for _, fb := range codec.RTCPFeedback { switch fb.Type { case webrtc.TypeRTCPFBGoogREMB: b.logger.V(1).Info("Setting feedback", "type", "webrtc.TypeRTCPFBGoogREMB") b.remb = true case webrtc.TypeRTCPFBTransportCC: b.logger.V(1).Info("Setting feedback", "type", webrtc.TypeRTCPFBTransportCC) b.twcc = true case webrtc.TypeRTCPFBNACK: b.logger.V(1).Info("Setting feedback", "type", webrtc.TypeRTCPFBNACK) b.nacker = NewNACKQueue() b.nack = true } } } else if b.codecType == webrtc.RTPCodecTypeAudio { for _, h := range params.HeaderExtensions { if h.URI == sdp.AudioLevelURI { b.audioLevel = true b.audioExt = uint8(h.ID) } } } for _, pp := range b.pPackets { b.calc(pp.packet, pp.arrivalTime) } b.pPackets = nil b.bound = true b.logger.V(1).Info("NewBuffer", "MaxBitRate", o.MaxBitRate) } // Write adds an RTP Packet, out of order, new packet may be arrived later func (b *Buffer) Write(pkt []byte) (n int, err error) { b.Lock() defer b.Unlock() if b.closed.get() { err = io.EOF return } if !b.bound { packet := make([]byte, len(pkt)) copy(packet, pkt) b.pPackets = append(b.pPackets, pendingPackets{ packet: packet, arrivalTime: time.Now().UnixNano(), }) return } b.calc(pkt, time.Now().UnixNano()) return } func (b *Buffer) Read(buff []byte) (n int, err error) { for { if b.closed.get() { err = io.EOF return } b.Lock() if b.pPackets != nil && len(b.pPackets) > b.lastPacketRead { if len(buff) < len(b.pPackets[b.lastPacketRead].packet) { err = ErrBufferTooSmall b.Unlock() return } n = len(b.pPackets[b.lastPacketRead].packet) copy(buff, b.pPackets[b.lastPacketRead].packet) b.lastPacketRead++ b.Unlock() return } b.Unlock() time.Sleep(25 * time.Millisecond) } } func (b *Buffer) ReadExtended() (*ExtPacket, error) { for { if b.closed.get() { return nil, io.EOF } b.Lock() if b.extPackets.Len() > 0 { extPkt := b.extPackets.PopFront().(*ExtPacket) b.Unlock() return extPkt, nil } b.Unlock() time.Sleep(10 * time.Millisecond) } } func (b *Buffer) Close() error { b.Lock() defer b.Unlock() b.closeOnce.Do(func() { if b.bucket != nil && b.codecType == webrtc.RTPCodecTypeVideo { b.videoPool.Put(b.bucket.src) } if b.bucket != nil && b.codecType == webrtc.RTPCodecTypeAudio { b.audioPool.Put(b.bucket.src) } b.closed.set(true) b.onClose() }) return nil } func (b *Buffer) OnClose(fn func()) { b.onClose = fn } func (b *Buffer) calc(pkt []byte, arrivalTime int64) { sn := binary.BigEndian.Uint16(pkt[2:4]) var headPkt bool if b.stats.PacketCount == 0 { b.baseSN = sn b.lastReport = arrivalTime b.seqHdlr.UpdateMaxSeq(uint32(sn)) headPkt = true } else { extSN, isNewer := b.seqHdlr.Unwrap(sn) if b.nack { if isNewer { for i := b.seqHdlr.MaxSeqNo() + 1; i < extSN; i++ { b.nacker.Push(i) } } else { b.nacker.Remove(extSN) } } if isNewer { b.seqHdlr.UpdateMaxSeq(extSN) } headPkt = isNewer } var p rtp.Packet pb, err := b.bucket.AddPacket(pkt, sn, headPkt) if err != nil { if err == ErrRTXPacket { return } return } if err = p.Unmarshal(pb); err != nil { return } // submit to TWCC even if it is a padding only packet. Clients use padding only packets as probes // for bandwidth estimation if b.twcc { if ext := p.GetExtension(b.twccExt); len(ext) > 1 { b.feedbackTWCC(binary.BigEndian.Uint16(ext[0:2]), arrivalTime, p.Marker) } } b.stats.TotalByte += uint64(len(pkt)) b.stats.PacketCount++ ep := ExtPacket{ Head: headPkt, Packet: p, Arrival: arrivalTime, RawPacket: pb, } if len(p.Payload) == 0 { // padding only packet, nothing else to do b.extPackets.PushBack(&ep) return } temporalLayer := int32(0) switch b.mime { case "video/vp8": vp8Packet := VP8{} if err := vp8Packet.Unmarshal(p.Payload); err != nil { return } ep.Payload = vp8Packet ep.KeyFrame = vp8Packet.IsKeyFrame temporalLayer = int32(vp8Packet.TID) case "video/h264": ep.KeyFrame = IsH264Keyframe(p.Payload) } if b.minPacketProbe < 25 { // LK-TODO-START // This should check for proper wrap around. // Probably remove this probe section of code as // the only place this baseSN is used at is where // RTCP receiver reports are generated. If there // are some out-of-order packets right at the start // the stat is going to be off by a bit. Not a big deal. // LK-TODO-END if sn < b.baseSN { b.baseSN = sn } b.minPacketProbe++ } b.extPackets.PushBack(&ep) // if first time update or the timestamp is later (factoring timestamp wrap around) latestTimestamp := atomic.LoadUint32(&b.latestTimestamp) latestTimestampTimeInNanosSinceEpoch := atomic.LoadInt64(&b.latestTimestampTime) if (latestTimestampTimeInNanosSinceEpoch == 0) || IsLaterTimestamp(p.Timestamp, latestTimestamp) { atomic.StoreUint32(&b.latestTimestamp, p.Timestamp) atomic.StoreInt64(&b.latestTimestampTime, arrivalTime) } arrival := uint32(arrivalTime / 1e6 * int64(b.clockRate/1e3)) transit := arrival - p.Timestamp if b.lastTransit != 0 { d := int32(transit - b.lastTransit) if d < 0 { d = -d } b.stats.Jitter += (float64(d) - b.stats.Jitter) / 16 } b.lastTransit = transit if b.audioLevel { if e := p.GetExtension(b.audioExt); e != nil && b.onAudioLevel != nil { ext := rtp.AudioLevelExtension{} if err := ext.Unmarshal(e); err == nil { ep.AudioLevel = e[0] | 0x80 // highest bit to indicate audio level present duration := (int64(p.Timestamp) - int64(latestTimestamp)) * 1e3 / int64(b.clockRate) if duration > 0 { b.onAudioLevel(ext.Level, uint32(duration)) } } } } if b.nacker != nil { if r := b.buildNACKPacket(); r != nil { b.feedbackCB(r) } } b.bitrateHelper[temporalLayer] += int64(len(pkt)) diff := arrivalTime - b.lastReport if diff >= ReportDelta { // // As this happens in the data path, if there are no packets received // in an interval, the bitrate will be stuck with the old value. // GetBitrate() method in sfu.Receiver uses the availableLayers // set by stream tracker to report 0 bitrate if a layer is not available. // bitrates, ok := b.bitrate.Load().([]int64) if !ok { bitrates = make([]int64, len(b.bitrateHelper)) } for i := 0; i < len(b.bitrateHelper); i++ { br := (8 * b.bitrateHelper[i] * int64(ReportDelta)) / diff bitrates[i] = br b.bitrateHelper[i] = 0 } b.bitrate.Store(bitrates) b.feedbackCB(b.getRTCP()) b.lastReport = arrivalTime } } func (b *Buffer) buildNACKPacket() []rtcp.Packet { if nacks, askKeyframe := b.nacker.Pairs(b.seqHdlr.MaxSeqNo()); len(nacks) > 0 || askKeyframe { var pkts []rtcp.Packet if len(nacks) > 0 { pkts = []rtcp.Packet{&rtcp.TransportLayerNack{ MediaSSRC: b.mediaSSRC, Nacks: nacks, }} } if askKeyframe { pkts = append(pkts, &rtcp.PictureLossIndication{ MediaSSRC: b.mediaSSRC, }) } return pkts } return nil } func (b *Buffer) buildREMBPacket() *rtcp.ReceiverEstimatedMaximumBitrate { br := b.Bitrate() if b.stats.LostRate < 0.02 { br = int64(float64(br)*1.09) + 2000 } if b.stats.LostRate > .1 { br = int64(float64(br) * float64(1-0.5*b.stats.LostRate)) } if br > b.maxBitrate { br = b.maxBitrate } if br < 100000 { br = 100000 } b.stats.TotalByte = 0 return &rtcp.ReceiverEstimatedMaximumBitrate{ Bitrate: float32(br), SSRCs: []uint32{b.mediaSSRC}, } } func (b *Buffer) buildReceptionReport() rtcp.ReceptionReport { extMaxSeq := b.seqHdlr.MaxSeqNo() expected := extMaxSeq - uint32(b.baseSN) + 1 lost := uint32(0) if b.stats.PacketCount < expected && b.stats.PacketCount != 0 { lost = expected - b.stats.PacketCount } expectedInterval := expected - b.stats.LastExpected b.stats.LastExpected = expected receivedInterval := b.stats.PacketCount - b.stats.LastReceived b.stats.LastReceived = b.stats.PacketCount lostInterval := expectedInterval - receivedInterval b.stats.LostRate = float32(lostInterval) / float32(expectedInterval) var fracLost uint8 if expectedInterval != 0 && lostInterval > 0 { fracLost = uint8((lostInterval << 8) / expectedInterval) } if b.lastFractionLostToReport > fracLost { // If fraction lost from subscriber is bigger than sfu received, use it. fracLost = b.lastFractionLostToReport } var dlsr uint32 if b.lastSRRecv != 0 { delayMS := uint32((time.Now().UnixNano() - b.lastSRRecv) / 1e6) dlsr = (delayMS / 1e3) << 16 dlsr |= (delayMS % 1e3) * 65536 / 1000 } rr := rtcp.ReceptionReport{ SSRC: b.mediaSSRC, FractionLost: fracLost, TotalLost: lost, LastSequenceNumber: extMaxSeq, Jitter: uint32(b.stats.Jitter), LastSenderReport: uint32(b.lastSRNTPTime >> 16), Delay: dlsr, } return rr } func (b *Buffer) SetSenderReportData(rtpTime uint32, ntpTime uint64) { b.Lock() b.lastSRRTPTime = rtpTime b.lastSRNTPTime = ntpTime b.lastSRRecv = time.Now().UnixNano() b.Unlock() } func (b *Buffer) SetLastFractionLostReport(lost uint8) { b.lastFractionLostToReport = lost } func (b *Buffer) getRTCP() []rtcp.Packet { var pkts []rtcp.Packet pkts = append(pkts, &rtcp.ReceiverReport{ Reports: []rtcp.ReceptionReport{b.buildReceptionReport()}, }) if b.remb && !b.twcc { pkts = append(pkts, b.buildREMBPacket()) } return pkts } func (b *Buffer) GetPacket(buff []byte, sn uint16) (int, error) { b.Lock() defer b.Unlock() if b.closed.get() { return 0, io.EOF } return b.bucket.GetPacket(buff, sn) } // Bitrate returns the current publisher stream bitrate. func (b *Buffer) Bitrate() int64 { bitrates, ok := b.bitrate.Load().([]int64) bitrate := int64(0) if ok { for _, b := range bitrates { bitrate += b } } return bitrate } // BitrateTemporalCumulative returns the current publisher stream bitrate temporal layer accumulated with lower temporal layers. func (b *Buffer) BitrateTemporalCumulative() []int64 { bitrates, ok := b.bitrate.Load().([]int64) if !ok { return make([]int64, len(b.bitrateHelper)) } // copy and process brs := make([]int64, len(bitrates)) copy(brs, bitrates) for i := len(brs) - 1; i >= 1; i-- { if brs[i] != 0 { for j := i - 1; j >= 0; j-- { brs[i] += brs[j] } } } return brs } func (b *Buffer) OnTransportWideCC(fn func(sn uint16, timeNS int64, marker bool)) { b.feedbackTWCC = fn } func (b *Buffer) OnFeedback(fn func(fb []rtcp.Packet)) { b.feedbackCB = fn } func (b *Buffer) OnAudioLevel(fn func(level uint8, durationMs uint32)) { b.onAudioLevel = fn } // GetMediaSSRC returns the associated SSRC of the RTP stream func (b *Buffer) GetMediaSSRC() uint32 { return b.mediaSSRC } // GetClockRate returns the RTP clock rate func (b *Buffer) GetClockRate() uint32 { return b.clockRate } // GetSenderReportData returns the rtp, ntp and nanos of the last sender report func (b *Buffer) GetSenderReportData() (rtpTime uint32, ntpTime uint64, lastReceivedTimeInNanosSinceEpoch int64) { rtpTime = atomic.LoadUint32(&b.lastSRRTPTime) ntpTime = atomic.LoadUint64(&b.lastSRNTPTime) lastReceivedTimeInNanosSinceEpoch = atomic.LoadInt64(&b.lastSRRecv) return rtpTime, ntpTime, lastReceivedTimeInNanosSinceEpoch } // GetStats returns the raw statistics about a particular buffer state func (b *Buffer) GetStats() (stats Stats) { b.Lock() stats = b.stats b.Unlock() return } // GetLatestTimestamp returns the latest RTP timestamp factoring in potential RTP timestamp wrap-around func (b *Buffer) GetLatestTimestamp() (latestTimestamp uint32, latestTimestampTimeInNanosSinceEpoch int64) { latestTimestamp = atomic.LoadUint32(&b.latestTimestamp) latestTimestampTimeInNanosSinceEpoch = atomic.LoadInt64(&b.latestTimestampTime) return latestTimestamp, latestTimestampTimeInNanosSinceEpoch } // IsTimestampWrapAround returns true if wrap around happens from timestamp1 to timestamp2 func IsTimestampWrapAround(timestamp1 uint32, timestamp2 uint32) bool { return timestamp2 < timestamp1 && timestamp1 > 0xf0000000 && timestamp2 < 0x0fffffff } // IsLaterTimestamp returns true if timestamp1 is later in time than timestamp2 factoring in timestamp wrap-around func IsLaterTimestamp(timestamp1 uint32, timestamp2 uint32) bool { if timestamp1 > timestamp2 { if IsTimestampWrapAround(timestamp1, timestamp2) { return false } return true } if IsTimestampWrapAround(timestamp2, timestamp1) { return true } return false } func IsNewerUint16(val1, val2 uint16) bool { return val1 != val2 && val1-val2 < 0x8000 } type SeqWrapHandler struct { maxSeqNo uint32 } func (s *SeqWrapHandler) Cycles() uint32 { return s.maxSeqNo & 0xffff0000 } func (s *SeqWrapHandler) MaxSeqNo() uint32 { return s.maxSeqNo } // unwrap seq and update the maxSeqNo. return unwrapped value, and whether seq is newer func (s *SeqWrapHandler) Unwrap(seq uint16) (uint32, bool) { maxSeqNo := uint16(s.maxSeqNo) delta := int32(seq) - int32(maxSeqNo) newer := IsNewerUint16(seq, maxSeqNo) if newer { if delta < 0 { // seq is newer, but less than maxSeqNo, wrap around delta += 0x10000 } } else { // older value if delta > 0 && (int32(s.maxSeqNo)+delta-0x10000) >= 0 { // wrap backwards, should not less than 0 in this case: // at start time, received seq 1, set s.maxSeqNo =1 , // then an out of order seq 65534 coming, we can't unwrap // the seq to -2 delta -= 0x10000 } } unwrapped := uint32(int32(s.maxSeqNo) + delta) return unwrapped, newer } func (s *SeqWrapHandler) UpdateMaxSeq(extSeq uint32) { s.maxSeqNo = extSeq }