// Copyright (c) 2020 by Juliusz Chroboczek. // This is not open source software. Copy it, and I'll break into your // house and tell your three year-old that Santa doesn't exist. package main import ( "encoding/json" "errors" "io" "log" "math" "math/bits" "os" "strings" "sync" "sync/atomic" "time" "sfu/estimator" "sfu/jitter" "sfu/mono" "sfu/packetcache" "github.com/gorilla/websocket" "github.com/pion/rtcp" "github.com/pion/rtp" "github.com/pion/webrtc/v2" ) var iceConf webrtc.Configuration var iceOnce sync.Once func iceConfiguration() webrtc.Configuration { iceOnce.Do(func() { var iceServers []webrtc.ICEServer file, err := os.Open(iceFilename) if err != nil { log.Printf("Open %v: %v", iceFilename, err) return } defer file.Close() d := json.NewDecoder(file) err = d.Decode(&iceServers) if err != nil { log.Printf("Get ICE configuration: %v", err) return } iceConf = webrtc.Configuration{ ICEServers: iceServers, } }) return iceConf } type protocolError string func (err protocolError) Error() string { return string(err) } type userError string func (err userError) Error() string { return string(err) } func errorToWSCloseMessage(err error) (string, []byte) { var code int var text string switch e := err.(type) { case *websocket.CloseError: code = websocket.CloseNormalClosure case protocolError: code = websocket.CloseProtocolError text = string(e) case userError: code = websocket.CloseNormalClosure text = string(e) default: code = websocket.CloseInternalServerErr } return text, websocket.FormatCloseMessage(code, text) } func isWSNormalError(err error) bool { return websocket.IsCloseError(err, websocket.CloseNormalClosure, websocket.CloseGoingAway) } type rateMap map[string]uint32 func (v *rateMap) UnmarshalJSON(b []byte) error { var m map[string]interface{} err := json.Unmarshal(b, &m) if err != nil { return err } n := make(map[string]uint32, len(m)) for k, w := range m { switch w := w.(type) { case bool: if w { n[k] = ^uint32(0) } else { n[k] = 0 } case float64: if w < 0 || w >= float64(^uint32(0)) { return errors.New("overflow") } n[k] = uint32(w) default: return errors.New("unexpected type in JSON map") } } *v = n return nil } func (v rateMap) MarshalJSON() ([]byte, error) { m := make(map[string]interface{}, len(v)) for k, w := range v { switch w { case 0: m[k] = false case ^uint32(0): m[k] = true default: m[k] = w } } return json.Marshal(m) } type clientMessage struct { Type string `json:"type"` Id string `json:"id,omitempty"` Username string `json:"username,omitempty"` Password string `json:"password,omitempty"` Permissions userPermission `json:"permissions,omitempty"` Group string `json:"group,omitempty"` Value string `json:"value,omitempty"` Me bool `json:"me,omitempty"` Offer *webrtc.SessionDescription `json:"offer,omitempty"` Answer *webrtc.SessionDescription `json:"answer,omitempty"` Candidate *webrtc.ICECandidateInit `json:"candidate,omitempty"` Labels map[string]string `json:"labels,omitempty"` Del bool `json:"del,omitempty"` Request rateMap `json:"request,omitempty"` } type closeMessage struct { data []byte } func startClient(conn *websocket.Conn) (err error) { var m clientMessage err = conn.SetReadDeadline(time.Now().Add(15 * time.Second)) if err != nil { conn.Close() return } err = conn.ReadJSON(&m) if err != nil { conn.Close() return } err = conn.SetReadDeadline(time.Time{}) if err != nil { conn.Close() return } if m.Type != "handshake" { conn.Close() return } c := &client{ id: m.Id, username: m.Username, actionCh: make(chan interface{}, 10), done: make(chan struct{}), } defer close(c.done) c.writeCh = make(chan interface{}, 25) defer func() { if isWSNormalError(err) { err = nil } else { m, e := errorToWSCloseMessage(err) if m != "" { c.write(clientMessage{ Type: "error", Value: m, }) } select { case c.writeCh <- closeMessage{e}: case <-c.writerDone: } } close(c.writeCh) c.writeCh = nil }() c.writerDone = make(chan struct{}) go clientWriter(conn, c.writeCh, c.writerDone) if strings.ContainsRune(m.Username, ' ') { err = userError("don't put spaces in your username") return } g, users, err := addClient(m.Group, c, m.Username, m.Password) if err != nil { return } c.group = g defer delClient(c) for _, u := range users { c.write(clientMessage{ Type: "user", Id: u.id, Username: u.username, }) } clients := g.getClients(nil) u := clientMessage{ Type: "user", Id: c.id, Username: c.username, } for _, c := range clients { c.write(u) } defer func() { clients := g.getClients(c) u := clientMessage{ Type: "user", Id: c.id, Username: c.username, Del: true, } for _, c := range clients { c.write(u) } }() return clientLoop(c, conn) } func getUpConn(c *client, id string) *upConnection { c.mu.Lock() defer c.mu.Unlock() if c.up == nil { return nil } conn := c.up[id] if conn == nil { return nil } return conn } func getUpConns(c *client) []string { c.mu.Lock() defer c.mu.Unlock() up := make([]string, 0, len(c.up)) for id := range c.up { up = append(up, id) } return up } func addUpConn(c *client, id string) (*upConnection, error) { pc, err := groups.api.NewPeerConnection(iceConfiguration()) if err != nil { return nil, err } _, err = pc.AddTransceiverFromKind(webrtc.RTPCodecTypeAudio, webrtc.RtpTransceiverInit{ Direction: webrtc.RTPTransceiverDirectionRecvonly, }, ) if err != nil { pc.Close() return nil, err } _, err = pc.AddTransceiverFromKind(webrtc.RTPCodecTypeVideo, webrtc.RtpTransceiverInit{ Direction: webrtc.RTPTransceiverDirectionRecvonly, }, ) if err != nil { pc.Close() return nil, err } conn := &upConnection{id: id, pc: pc} c.mu.Lock() defer c.mu.Unlock() if c.up == nil { c.up = make(map[string]*upConnection) } if c.up[id] != nil || (c.down != nil && c.down[id] != nil) { conn.pc.Close() return nil, errors.New("Adding duplicate connection") } c.up[id] = conn pc.OnICECandidate(func(candidate *webrtc.ICECandidate) { sendICE(c, id, candidate) }) go rtcpUpSender(c, conn) pc.OnTrack(func(remote *webrtc.Track, receiver *webrtc.RTPReceiver) { c.mu.Lock() u, ok := c.up[id] if !ok { log.Printf("Unknown connection") c.mu.Unlock() return } mid := getUpMid(pc, remote) if mid == "" { log.Printf("Couldn't get track's mid") c.mu.Unlock() return } label, ok := u.labels[mid] if !ok { log.Printf("Couldn't get track's label") isvideo := remote.Kind() == webrtc.RTPCodecTypeVideo if isvideo { label = "video" } else { label = "audio" } } track := &upTrack{ track: remote, label: label, cache: packetcache.New(96), rate: estimator.New(time.Second), jitter: jitter.New(remote.Codec().ClockRate), maxBitrate: ^uint64(0), localCh: make(chan struct{}, 2), writerDone: make(chan struct{}), } u.tracks = append(u.tracks, track) var tracks []*upTrack if u.complete() { tracks = make([]*upTrack, len(u.tracks)) copy(tracks, u.tracks) } if remote.Kind() == webrtc.RTPCodecTypeVideo { atomic.AddUint32(&c.group.videoCount, 1) } c.mu.Unlock() if tracks != nil { clients := c.group.getClients(c) for _, cc := range clients { pushConn(cc, u, tracks, u.label) } } go readLoop(conn, track) go rtcpUpListener(conn, track, receiver) }) return conn, nil } type packetIndex struct { seqno uint16 index uint16 } func readLoop(conn *upConnection, track *upTrack) { isvideo := track.track.Kind() == webrtc.RTPCodecTypeVideo ch := make(chan packetIndex, 32) defer close(ch) go writeLoop(conn, track, ch) buf := make([]byte, packetcache.BufSize) var packet rtp.Packet drop := 0 for { bytes, err := track.track.Read(buf) if err != nil { if err != io.EOF { log.Printf("%v", err) } break } track.rate.Add(uint32(bytes)) err = packet.Unmarshal(buf[:bytes]) if err != nil { log.Printf("%v", err) continue } track.jitter.Accumulate(packet.Timestamp) first, index := track.cache.Store(packet.SequenceNumber, buf[:bytes]) if packet.SequenceNumber-first > 24 { found, first, bitmap := track.cache.BitmapGet() if found { err := conn.sendNACK(track, first, bitmap) if err != nil { log.Printf("%v", err) } } } if drop > 0 { if packet.Marker { // last packet in frame drop = 0 } else { drop-- } continue } select { case ch <- packetIndex{packet.SequenceNumber, index}: default: if isvideo { // the writer is congested. Drop until // the end of the frame. if isvideo && !packet.Marker { drop = 7 } } } } } func writeLoop(conn *upConnection, track *upTrack, ch <-chan packetIndex) { defer close(track.writerDone) buf := make([]byte, packetcache.BufSize) var packet rtp.Packet local := track.getLocal() for { select { case <-track.localCh: local = track.getLocal() case pi, ok := <-ch: if !ok { return } bytes := track.cache.GetAt(pi.seqno, pi.index, buf) if bytes == 0 { continue } err := packet.Unmarshal(buf[:bytes]) if err != nil { log.Printf("%v", err) continue } for _, l := range local { err := l.WriteRTP(&packet) if err != nil { if err != io.ErrClosedPipe { log.Printf("WriteRTP: %v", err) } continue } l.Accumulate(uint32(bytes)) } } } } func rtcpUpListener(conn *upConnection, track *upTrack, r *webrtc.RTPReceiver) { for { ps, err := r.ReadRTCP() if err != nil { if err != io.EOF { log.Printf("ReadRTCP: %v", err) } return } for _, p := range ps { switch p := p.(type) { case *rtcp.SenderReport: atomic.StoreUint32(&track.lastSenderReport, uint32(p.NTPTime>>16)) atomic.StoreUint32(&track.lastSenderReportTime, uint32(mono.Now(0x10000))) case *rtcp.SourceDescription: } } } } func sendRR(c *client, conn *upConnection) error { c.mu.Lock() if len(conn.tracks) == 0 { c.mu.Unlock() return nil } now := uint32(mono.Now(0x10000)) reports := make([]rtcp.ReceptionReport, 0, len(conn.tracks)) for _, t := range conn.tracks { expected, lost, totalLost, eseqno := t.cache.GetStats(true) if expected == 0 { expected = 1 } if lost >= expected { lost = expected - 1 } lastSR := atomic.LoadUint32(&t.lastSenderReport) delay := now - atomic.LoadUint32(&t.lastSenderReportTime) reports = append(reports, rtcp.ReceptionReport{ SSRC: t.track.SSRC(), FractionLost: uint8((lost * 256) / expected), TotalLost: totalLost, LastSequenceNumber: eseqno, Jitter: t.jitter.Jitter(), LastSenderReport: lastSR, Delay: delay, }) } c.mu.Unlock() return conn.pc.WriteRTCP([]rtcp.Packet{ &rtcp.ReceiverReport{ SSRC: 1, Reports: reports, }, }) } func rtcpUpSender(c *client, conn *upConnection) { for { time.Sleep(time.Second) err := sendRR(c, conn) if err != nil { if err == io.EOF || err == io.ErrClosedPipe { return } log.Printf("WriteRTCP: %v", err) } } } func delUpConn(c *client, id string) bool { c.mu.Lock() defer c.mu.Unlock() if c.up == nil { return false } conn := c.up[id] if conn == nil { return false } for _, track := range conn.tracks { if track.track.Kind() == webrtc.RTPCodecTypeVideo { count := atomic.AddUint32(&c.group.videoCount, ^uint32(0)) if count == ^uint32(0) { log.Printf("Negative track count!") atomic.StoreUint32(&c.group.videoCount, 0) } } } local := conn.getLocal() go func() { for _, l := range local { l.Close() } }() conn.pc.Close() delete(c.up, id) return true } func getDownConn(c *client, id string) *downConnection { if c.down == nil { return nil } c.mu.Lock() defer c.mu.Unlock() conn := c.down[id] if conn == nil { return nil } return conn } func getConn(c *client, id string) iceConnection { up := getUpConn(c, id) if up != nil { return up } down := getDownConn(c, id) if down != nil { return down } return nil } func addDownConn(c *client, id string, remote *upConnection) (*downConnection, error) { pc, err := groups.api.NewPeerConnection(iceConfiguration()) if err != nil { return nil, err } pc.OnICECandidate(func(candidate *webrtc.ICECandidate) { sendICE(c, id, candidate) }) pc.OnTrack(func(remote *webrtc.Track, receiver *webrtc.RTPReceiver) { log.Printf("Got track on downstream connection") }) if c.down == nil { c.down = make(map[string]*downConnection) } conn := &downConnection{ id: id, client: c, pc: pc, remote: remote, } c.mu.Lock() defer c.mu.Unlock() if c.down[id] != nil || (c.up != nil && c.up[id] != nil) { conn.pc.Close() return nil, errors.New("Adding duplicate connection") } c.down[id] = conn remote.addLocal(conn) return conn, nil } func delDownConn(c *client, id string) bool { c.mu.Lock() defer c.mu.Unlock() if c.down == nil { return false } conn := c.down[id] if conn == nil { return false } conn.remote.delLocal(conn) for _, track := range conn.tracks { found := track.remote.delLocal(track) if !found { log.Printf("Couldn't find remote track") } } conn.pc.Close() delete(c.down, id) return true } func addDownTrack(c *client, conn *downConnection, remoteTrack *upTrack, remoteConn *upConnection) (*webrtc.RTPSender, error) { local, err := conn.pc.NewTrack( remoteTrack.track.PayloadType(), remoteTrack.track.SSRC(), remoteTrack.track.ID(), remoteTrack.track.Label(), ) if err != nil { return nil, err } s, err := conn.pc.AddTrack(local) if err != nil { return nil, err } track := &downTrack{ track: local, remote: remoteTrack, maxLossBitrate: new(bitrate), maxREMBBitrate: new(bitrate), stats: new(receiverStats), rate: estimator.New(time.Second), } conn.tracks = append(conn.tracks, track) go rtcpDownListener(conn, track, s) return s, nil } func activateDownTrack(conn *downConnection, track *downTrack) { track.remote.addLocal(track) } const ( minLossRate = 9600 initLossRate = 512 * 1000 maxLossRate = 1 << 30 ) func (track *downTrack) updateRate(loss uint8, now uint64) { rate := track.maxLossBitrate.Get(now) if rate > maxLossRate { // no recent feedback, reset rate = initLossRate } if loss < 5 { // if our actual rate is low, then we're not probing the // bottleneck actual := 8 * uint64(track.rate.Estimate()) if actual >= (rate*7)/8 { // loss < 0.02, multiply by 1.05 rate = rate * 269 / 256 if rate > maxLossRate { rate = maxLossRate } } } else if loss > 25 { // loss > 0.1, multiply by (1 - loss/2) rate = rate * (512 - uint64(loss)) / 512 if rate < minLossRate { rate = minLossRate } } // update unconditionally, to set the timestamp track.maxLossBitrate.Set(rate, now) } func rtcpDownListener(conn *downConnection, track *downTrack, s *webrtc.RTPSender) { for { ps, err := s.ReadRTCP() if err != nil { if err != io.EOF { log.Printf("ReadRTCP: %v", err) } return } for _, p := range ps { switch p := p.(type) { case *rtcp.PictureLossIndication: err := conn.remote.sendPLI(track.remote) if err != nil { log.Printf("sendPLI: %v", err) } case *rtcp.ReceiverEstimatedMaximumBitrate: track.maxREMBBitrate.Set( p.Bitrate, mono.Microseconds(), ) case *rtcp.ReceiverReport: for _, r := range p.Reports { if r.SSRC == track.track.SSRC() { now := mono.Microseconds() track.stats.Set( r.FractionLost, r.Jitter, now, ) track.updateRate( r.FractionLost, now, ) } } case *rtcp.TransportLayerNack: maxBitrate := track.GetMaxBitrate( mono.Microseconds(), ) bitrate := track.rate.Estimate() if uint64(bitrate)*7/8 < maxBitrate { sendRecovery(p, track) } } } } } func trackKinds(down *downConnection) (audio bool, video bool) { if down.pc == nil { return } for _, s := range down.pc.GetSenders() { track := s.Track() if track == nil { continue } switch track.Kind() { case webrtc.RTPCodecTypeAudio: audio = true case webrtc.RTPCodecTypeVideo: video = true } } return } func updateUpBitrate(up *upConnection, maxVideoRate uint64) { now := mono.Microseconds() for _, track := range up.tracks { isvideo := track.track.Kind() == webrtc.RTPCodecTypeVideo minrate := uint64(minAudioRate) rate := ^uint64(0) if isvideo { minrate = minVideoRate rate = maxVideoRate if rate < minrate { rate = minrate } } local := track.getLocal() for _, l := range local { bitrate := l.GetMaxBitrate(now) if bitrate == ^uint64(0) { continue } if bitrate <= minrate { rate = minrate break } if rate > bitrate { rate = bitrate } } track.maxBitrate = rate } } func (up *upConnection) sendPLI(track *upTrack) error { if !track.hasRtcpFb("nack", "pli") { return nil } last := atomic.LoadUint64(&track.lastPLI) now := mono.Microseconds() if now >= last && now-last < 200000 { return nil } atomic.StoreUint64(&track.lastPLI, now) return sendPLI(up.pc, track.track.SSRC()) } func sendPLI(pc *webrtc.PeerConnection, ssrc uint32) error { return pc.WriteRTCP([]rtcp.Packet{ &rtcp.PictureLossIndication{MediaSSRC: ssrc}, }) } func sendREMB(pc *webrtc.PeerConnection, ssrc uint32, bitrate uint64) error { return pc.WriteRTCP([]rtcp.Packet{ &rtcp.ReceiverEstimatedMaximumBitrate{ Bitrate: bitrate, SSRCs: []uint32{ssrc}, }, }) } func (up *upConnection) sendNACK(track *upTrack, first uint16, bitmap uint16) error { if !track.hasRtcpFb("nack", "") { return nil } err := sendNACK(up.pc, track.track.SSRC(), first, bitmap) if err == nil { track.cache.Expect(1 + bits.OnesCount16(bitmap)) } return err } func sendNACK(pc *webrtc.PeerConnection, ssrc uint32, first uint16, bitmap uint16) error { packet := rtcp.Packet( &rtcp.TransportLayerNack{ MediaSSRC: ssrc, Nacks: []rtcp.NackPair{ rtcp.NackPair{ first, rtcp.PacketBitmap(bitmap), }, }, }, ) return pc.WriteRTCP([]rtcp.Packet{packet}) } func sendRecovery(p *rtcp.TransportLayerNack, track *downTrack) { var packet rtp.Packet buf := make([]byte, packetcache.BufSize) for _, nack := range p.Nacks { for _, seqno := range nack.PacketList() { l := track.remote.cache.Get(seqno, buf) if l == 0 { continue } err := packet.Unmarshal(buf[:l]) if err != nil { continue } err = track.track.WriteRTP(&packet) if err != nil { log.Printf("WriteRTP: %v", err) continue } track.rate.Add(uint32(l)) } } } func negotiate(c *client, down *downConnection) error { offer, err := down.pc.CreateOffer(nil) if err != nil { return err } err = down.pc.SetLocalDescription(offer) if err != nil { return err } labels := make(map[string]string) for _, t := range down.pc.GetTransceivers() { var track *webrtc.Track if t.Sender() != nil { track = t.Sender().Track() } if track == nil { continue } for _, tr := range down.tracks { if tr.track == track { labels[t.Mid()] = tr.remote.label } } } return c.write(clientMessage{ Type: "offer", Id: down.id, Offer: &offer, Labels: labels, }) } func sendICE(c *client, id string, candidate *webrtc.ICECandidate) error { if candidate == nil { return nil } cand := candidate.ToJSON() return c.write(clientMessage{ Type: "ice", Id: id, Candidate: &cand, }) } func gotOffer(c *client, id string, offer webrtc.SessionDescription, labels map[string]string) error { var err error up, ok := c.up[id] if !ok { up, err = addUpConn(c, id) if err != nil { return err } } if c.username != "" { up.label = c.username } err = up.pc.SetRemoteDescription(offer) if err != nil { return err } answer, err := up.pc.CreateAnswer(nil) if err != nil { return err } err = up.pc.SetLocalDescription(answer) if err != nil { return err } up.labels = labels err = up.flushICECandidates() if err != nil { log.Printf("ICE: %v", err) } return c.write(clientMessage{ Type: "answer", Id: id, Answer: &answer, }) } func gotAnswer(c *client, id string, answer webrtc.SessionDescription) error { down := getDownConn(c, id) if down == nil { return protocolError("unknown id in answer") } err := down.pc.SetRemoteDescription(answer) if err != nil { return err } err = down.flushICECandidates() if err != nil { log.Printf("ICE: %v", err) } for _, t := range down.tracks { activateDownTrack(down, t) } return nil } func gotICE(c *client, candidate *webrtc.ICECandidateInit, id string) error { conn := getConn(c, id) if conn == nil { return errors.New("unknown id in ICE") } return conn.addICECandidate(candidate) } func (c *client) setRequested(requested map[string]uint32) error { if c.down != nil { for id := range c.down { c.write(clientMessage{ Type: "close", Id: id, }) delDownConn(c, id) } } c.requested = requested go func() { clients := c.group.getClients(c) for _, cc := range clients { cc.action(pushConnsAction{c}) } }() return nil } func (c *client) isRequested(label string) bool { return c.requested[label] != 0 } func addDownConnTracks(c *client, remote *upConnection, tracks []*upTrack) (*downConnection, error) { requested := false for _, t := range tracks { if c.isRequested(t.label) { requested = true break } } if !requested { return nil, nil } down, err := addDownConn(c, remote.id, remote) if err != nil { return nil, err } for _, t := range tracks { if !c.isRequested(t.label) { continue } _, err = addDownTrack(c, down, t, remote) if err != nil { delDownConn(c, down.id) return nil, err } } return down, nil } func pushConn(c *client, conn *upConnection, tracks []*upTrack, label string) { c.action(addConnAction{conn, tracks}) if label != "" { c.action(addLabelAction{conn.id, conn.label}) } } func clientLoop(c *client, conn *websocket.Conn) error { read := make(chan interface{}, 1) go clientReader(conn, read, c.done) defer func() { c.setRequested(map[string]uint32{}) if c.up != nil { for id := range c.up { delUpConn(c, id) } } }() c.write(clientMessage{ Type: "permissions", Permissions: c.permissions, }) h := c.group.getChatHistory() for _, m := range h { err := c.write(clientMessage{ Type: "chat", Id: m.id, Username: m.user, Value: m.value, Me: m.me, }) if err != nil { return err } } readTime := time.Now() ticker := time.NewTicker(time.Second) defer ticker.Stop() slowTicker := time.NewTicker(10 * time.Second) defer slowTicker.Stop() for { select { case m, ok := <-read: if !ok { return errors.New("reader died") } switch m := m.(type) { case clientMessage: readTime = time.Now() err := handleClientMessage(c, m) if err != nil { return err } case error: return m } case a := <-c.actionCh: switch a := a.(type) { case addConnAction: down, err := addDownConnTracks( c, a.conn, a.tracks, ) if err != nil { return err } if down != nil { err = negotiate(c, down) if err != nil { log.Printf("Negotiate: %v", err) delDownConn(c, down.id) err = failConnection( c, down.id, "negotiation failed", ) if err != nil { return err } continue } } case delConnAction: found := delDownConn(c, a.id) if found { c.write(clientMessage{ Type: "close", Id: a.id, }) } case addLabelAction: c.write(clientMessage{ Type: "label", Id: a.id, Value: a.label, }) case pushConnsAction: for _, u := range c.up { tracks := make([]*upTrack, len(u.tracks)) copy(tracks, u.tracks) go pushConn(a.c, u, tracks, u.label) } case connectionFailedAction: found := delUpConn(c, a.id) if found { err := failConnection(c, a.id, "ICE said: connection failed") if err != nil { return err } continue } // What should we do if a downstream // connection fails? Renegotiate? case permissionsChangedAction: c.write(clientMessage{ Type: "permissions", Permissions: c.permissions, }) if !c.permissions.Present { ids := getUpConns(c) for _, id := range ids { found := delUpConn(c, id) if found { failConnection( c, id, "permission denied", ) } } } case kickAction: return userError("you have been kicked") default: log.Printf("unexpected action %T", a) return errors.New("unexpected action") } case <-ticker.C: sendRateUpdate(c) case <-slowTicker.C: if time.Since(readTime) > 90*time.Second { return errors.New("client is dead") } if time.Since(readTime) > 60*time.Second { err := c.write(clientMessage{ Type: "ping", }) if err != nil { return err } } } } } func failConnection(c *client, id string, message string) error { if id != "" { err := c.write(clientMessage{ Type: "abort", Id: id, }) if err != nil { return err } } if message != "" { err := c.error(userError(message)) if err != nil { return err } } return nil } func handleClientMessage(c *client, m clientMessage) error { switch m.Type { case "request": err := c.setRequested(m.Request) if err != nil { return err } case "offer": if !c.permissions.Present { c.write(clientMessage{ Type: "abort", Id: m.Id, }) return c.error(userError("not authorised")) } if m.Offer == nil { return protocolError("null offer") } err := gotOffer(c, m.Id, *m.Offer, m.Labels) if err != nil { log.Printf("gotOffer: %v", err) return failConnection(c, m.Id, "negotiation failed") } case "answer": if m.Answer == nil { return protocolError("null answer") } err := gotAnswer(c, m.Id, *m.Answer) if err != nil { return err } case "close": found := delUpConn(c, m.Id) if !found { log.Printf("Deleting unknown up connection %v", m.Id) } case "ice": if m.Candidate == nil { return protocolError("null candidate") } err := gotICE(c, m.Candidate, m.Id) if err != nil { log.Printf("ICE: %v", err) } case "chat": c.group.addToChatHistory(m.Id, m.Username, m.Value, m.Me) clients := c.group.getClients(c) for _, cc := range clients { cc.write(m) } case "clearchat": c.group.clearChatHistory() m := clientMessage{Type: "clearchat"} clients := c.group.getClients(nil) for _, cc := range clients { cc.write(m) } case "op", "unop", "present", "unpresent": if !c.permissions.Op { c.error(userError("not authorised")) return nil } err := setPermission(c.group, m.Id, m.Type) if err != nil { return c.error(err) } case "lock", "unlock": if !c.permissions.Op { c.error(userError("not authorised")) return nil } var locked uint32 if m.Type == "lock" { locked = 1 } atomic.StoreUint32(&c.group.locked, locked) case "kick": if !c.permissions.Op { c.error(userError("not authorised")) return nil } err := kickClient(c.group, m.Id) if err != nil { return c.error(err) } case "pong": // nothing case "ping": c.write(clientMessage{ Type: "pong", }) default: log.Printf("unexpected message: %v", m.Type) return protocolError("unexpected message") } return nil } func sendRateUpdate(c *client) { type remb struct { pc *webrtc.PeerConnection ssrc uint32 bitrate uint64 } rembs := make([]remb, 0) maxVideoRate := ^uint64(0) count := atomic.LoadUint32(&c.group.videoCount) if count >= 3 { maxVideoRate = uint64(2000000 / math.Sqrt(float64(count))) if maxVideoRate < minVideoRate { maxVideoRate = minVideoRate } } c.mu.Lock() for _, u := range c.up { updateUpBitrate(u, maxVideoRate) for _, t := range u.tracks { if !t.hasRtcpFb("goog-remb", "") { continue } bitrate := t.maxBitrate if bitrate == ^uint64(0) { continue } rembs = append(rembs, remb{u.pc, t.track.SSRC(), bitrate}) } } c.mu.Unlock() for _, r := range rembs { err := sendREMB(r.pc, r.ssrc, r.bitrate) if err != nil { log.Printf("sendREMB: %v", err) } } } func clientReader(conn *websocket.Conn, read chan<- interface{}, done <-chan struct{}) { defer close(read) for { var m clientMessage err := conn.ReadJSON(&m) if err != nil { select { case read <- err: return case <-done: return } } select { case read <- m: case <-done: return } } } func clientWriter(conn *websocket.Conn, ch <-chan interface{}, done chan<- struct{}) { defer func() { close(done) conn.Close() }() for { m, ok := <-ch if !ok { break } err := conn.SetWriteDeadline( time.Now().Add(2 * time.Second)) if err != nil { return } switch m := m.(type) { case clientMessage: err := conn.WriteJSON(m) if err != nil { return } case closeMessage: err := conn.WriteMessage(websocket.CloseMessage, m.data) if err != nil { return } default: log.Printf("clientWiter: unexpected message %T", m) return } } }