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galene/rtpconn/rtpconn.go
Juliusz Chroboczek be73380f9f Label streams, not tracks.
We used to label tracks individually, in a view to using the labelling
for simulcast.  Since then, the WebRTC community has converged on a
different strategy, where multiple tracks share a single mid and
are labelled with the rid extension.

We now label whole streams, which is simpler, and use the track's
kind (and, in the future, the rid) to disambiguate.  This changes the
protocol in two ways:

  * in offers, the "labels" dictionary is replaced by a single "label"
    field; and
  * the syntax of the "request" message has changed.
2021-04-29 18:28:16 +02:00

1127 lines
24 KiB
Go

package rtpconn
import (
"errors"
"io"
"log"
"math/bits"
"sync"
"sync/atomic"
"time"
"github.com/pion/rtcp"
"github.com/pion/rtp"
"github.com/pion/sdp/v3"
"github.com/pion/webrtc/v3"
"github.com/jech/galene/conn"
"github.com/jech/galene/estimator"
"github.com/jech/galene/group"
"github.com/jech/galene/ice"
"github.com/jech/galene/jitter"
"github.com/jech/galene/packetcache"
"github.com/jech/galene/rtptime"
)
type bitrate struct {
bitrate uint64
jiffies uint64
}
func (br *bitrate) Set(bitrate uint64, now uint64) {
atomic.StoreUint64(&br.bitrate, bitrate)
atomic.StoreUint64(&br.jiffies, now)
}
func (br *bitrate) Get(now uint64) uint64 {
ts := atomic.LoadUint64(&br.jiffies)
if now < ts || now-ts > receiverReportTimeout {
return ^uint64(0)
}
return atomic.LoadUint64(&br.bitrate)
}
type receiverStats struct {
loss uint32
jitter uint32
jiffies uint64
}
func (s *receiverStats) Set(loss uint8, jitter uint32, now uint64) {
atomic.StoreUint32(&s.loss, uint32(loss))
atomic.StoreUint32(&s.jitter, jitter)
atomic.StoreUint64(&s.jiffies, now)
}
const receiverReportTimeout = 30 * rtptime.JiffiesPerSec
func (s *receiverStats) Get(now uint64) (uint8, uint32) {
ts := atomic.LoadUint64(&s.jiffies)
if now < ts || now > ts+receiverReportTimeout {
return 0, 0
}
return uint8(atomic.LoadUint32(&s.loss)), atomic.LoadUint32(&s.jitter)
}
type iceConnection interface {
addICECandidate(candidate *webrtc.ICECandidateInit) error
flushICECandidates() error
}
type downTrackAtomics struct {
rtt uint64
sr uint64
srNTP uint64
remoteNTP uint64
remoteRTP uint32
}
type rtpDownTrack struct {
track *webrtc.TrackLocalStaticRTP
sender *webrtc.RTPSender
remote conn.UpTrack
ssrc webrtc.SSRC
maxBitrate *bitrate
rate *estimator.Estimator
stats *receiverStats
atomics *downTrackAtomics
cname atomic.Value
}
func (down *rtpDownTrack) WriteRTP(packet *rtp.Packet) error {
return down.track.WriteRTP(packet)
}
func (down *rtpDownTrack) Accumulate(bytes uint32) {
down.rate.Accumulate(bytes)
}
func (down *rtpDownTrack) SetTimeOffset(ntp uint64, rtp uint32) {
atomic.StoreUint64(&down.atomics.remoteNTP, ntp)
atomic.StoreUint32(&down.atomics.remoteRTP, rtp)
}
func (down *rtpDownTrack) getTimeOffset() (uint64, uint32) {
ntp := atomic.LoadUint64(&down.atomics.remoteNTP)
rtp := atomic.LoadUint32(&down.atomics.remoteRTP)
return ntp, rtp
}
func (down *rtpDownTrack) getRTT() uint64 {
return atomic.LoadUint64(&down.atomics.rtt)
}
func (down *rtpDownTrack) setRTT(rtt uint64) {
atomic.StoreUint64(&down.atomics.rtt, rtt)
}
func (down *rtpDownTrack) getSRTime() (uint64, uint64) {
tm := atomic.LoadUint64(&down.atomics.sr)
ntp := atomic.LoadUint64(&down.atomics.srNTP)
return tm, ntp
}
func (down *rtpDownTrack) setSRTime(tm uint64, ntp uint64) {
atomic.StoreUint64(&down.atomics.sr, tm)
atomic.StoreUint64(&down.atomics.srNTP, ntp)
}
func (down *rtpDownTrack) SetCname(cname string) {
down.cname.Store(cname)
}
const (
negotiationUnneeded = iota
negotiationNeeded
negotiationRestartIce
)
type rtpDownConnection struct {
id string
pc *webrtc.PeerConnection
remote conn.Up
maxREMBBitrate *bitrate
iceCandidates []*webrtc.ICECandidateInit
negotiationNeeded int
mu sync.Mutex
tracks []*rtpDownTrack
}
func (down *rtpDownConnection) getTracks() []*rtpDownTrack {
down.mu.Lock()
defer down.mu.Unlock()
tracks := make([]*rtpDownTrack, len(down.tracks))
copy(tracks, down.tracks)
return tracks
}
func newDownConn(c group.Client, id string, remote conn.Up) (*rtpDownConnection, error) {
api := c.Group().API()
pc, err := api.NewPeerConnection(*ice.ICEConfiguration())
if err != nil {
return nil, err
}
pc.OnTrack(func(remote *webrtc.TrackRemote, receiver *webrtc.RTPReceiver) {
log.Printf("Got track on downstream connection")
})
conn := &rtpDownConnection{
id: id,
pc: pc,
remote: remote,
maxREMBBitrate: new(bitrate),
}
return conn, nil
}
func (down *rtpDownConnection) GetMaxBitrate(now uint64) uint64 {
rate := down.maxREMBBitrate.Get(now)
var trackRate uint64
tracks := down.getTracks()
for _, t := range tracks {
r := t.maxBitrate.Get(now)
if r == ^uint64(0) {
if t.track.Kind() == webrtc.RTPCodecTypeAudio {
r = 128 * 1024
} else {
r = 512 * 1024
}
}
trackRate += r
}
if trackRate < rate {
return trackRate
}
return rate
}
func (down *rtpDownConnection) addICECandidate(candidate *webrtc.ICECandidateInit) error {
if down.pc.RemoteDescription() != nil {
return down.pc.AddICECandidate(*candidate)
}
down.iceCandidates = append(down.iceCandidates, candidate)
return nil
}
func flushICECandidates(pc *webrtc.PeerConnection, candidates []*webrtc.ICECandidateInit) error {
if pc.RemoteDescription() == nil {
return errors.New("flushICECandidates called in bad state")
}
var err error
for _, candidate := range candidates {
err2 := pc.AddICECandidate(*candidate)
if err == nil {
err = err2
}
}
return err
}
func (down *rtpDownConnection) flushICECandidates() error {
err := flushICECandidates(down.pc, down.iceCandidates)
down.iceCandidates = nil
return err
}
type upTrackAtomics struct {
lastPLI uint64
lastFIR uint64
firSeqno uint32
}
type rtpUpTrack struct {
track *webrtc.TrackRemote
label string
rate *estimator.Estimator
cache *packetcache.Cache
jitter *jitter.Estimator
atomics *upTrackAtomics
cname atomic.Value
localCh chan localTrackAction
readerDone chan struct{}
mu sync.Mutex
srTime uint64
srNTPTime uint64
srRTPTime uint32
local []conn.DownTrack
bufferedNACKs []uint16
}
type localTrackAction struct {
add bool
track conn.DownTrack
}
func (up *rtpUpTrack) notifyLocal(add bool, track conn.DownTrack) {
select {
case up.localCh <- localTrackAction{add, track}:
case <-up.readerDone:
}
}
func (up *rtpUpTrack) AddLocal(local conn.DownTrack) error {
up.mu.Lock()
defer up.mu.Unlock()
for _, t := range up.local {
if t == local {
return nil
}
}
up.local = append(up.local, local)
// do this asynchronously, to avoid deadlocks when multiple
// clients call this simultaneously.
go up.notifyLocal(true, local)
return nil
}
func (up *rtpUpTrack) DelLocal(local conn.DownTrack) bool {
up.mu.Lock()
defer up.mu.Unlock()
for i, l := range up.local {
if l == local {
up.local = append(up.local[:i], up.local[i+1:]...)
// do this asynchronously, to avoid deadlocking when
// multiple clients call this simultaneously.
go up.notifyLocal(false, l)
return true
}
}
return false
}
func (up *rtpUpTrack) getLocal() []conn.DownTrack {
up.mu.Lock()
defer up.mu.Unlock()
local := make([]conn.DownTrack, len(up.local))
copy(local, up.local)
return local
}
func (up *rtpUpTrack) GetRTP(seqno uint16, result []byte) uint16 {
return up.cache.Get(seqno, result)
}
func (up *rtpUpTrack) Label() string {
return up.label
}
func (up *rtpUpTrack) Kind() webrtc.RTPCodecType {
return up.track.Kind()
}
func (up *rtpUpTrack) Codec() webrtc.RTPCodecCapability {
return up.track.Codec().RTPCodecCapability
}
func (up *rtpUpTrack) hasRtcpFb(tpe, parameter string) bool {
for _, fb := range up.track.Codec().RTCPFeedback {
if fb.Type == tpe && fb.Parameter == parameter {
return true
}
}
return false
}
type rtpUpConnection struct {
id string
label string
userId string
username string
pc *webrtc.PeerConnection
iceCandidates []*webrtc.ICECandidateInit
mu sync.Mutex
pushed bool
replace string
tracks []*rtpUpTrack
local []conn.Down
}
func (up *rtpUpConnection) getTracks() []*rtpUpTrack {
up.mu.Lock()
defer up.mu.Unlock()
tracks := make([]*rtpUpTrack, len(up.tracks))
copy(tracks, up.tracks)
return tracks
}
func (up *rtpUpConnection) getReplace(reset bool) string {
up.mu.Lock()
defer up.mu.Unlock()
replace := up.replace
if reset {
up.replace = ""
}
return replace
}
func (up *rtpUpConnection) Id() string {
return up.id
}
func (up *rtpUpConnection) Label() string {
return up.label
}
func (up *rtpUpConnection) User() (string, string) {
return up.userId, up.username
}
func (up *rtpUpConnection) AddLocal(local conn.Down) error {
up.mu.Lock()
defer up.mu.Unlock()
for _, t := range up.local {
if t == local {
return nil
}
}
up.local = append(up.local, local)
return nil
}
func (up *rtpUpConnection) DelLocal(local conn.Down) bool {
up.mu.Lock()
defer up.mu.Unlock()
for i, l := range up.local {
if l == local {
up.local = append(up.local[:i], up.local[i+1:]...)
return true
}
}
return false
}
func (up *rtpUpConnection) getLocal() []conn.Down {
up.mu.Lock()
defer up.mu.Unlock()
local := make([]conn.Down, len(up.local))
copy(local, up.local)
return local
}
func (up *rtpUpConnection) addICECandidate(candidate *webrtc.ICECandidateInit) error {
if up.pc.RemoteDescription() != nil {
return up.pc.AddICECandidate(*candidate)
}
up.iceCandidates = append(up.iceCandidates, candidate)
return nil
}
func (up *rtpUpConnection) flushICECandidates() error {
err := flushICECandidates(up.pc, up.iceCandidates)
up.iceCandidates = nil
return err
}
// pushConnNow pushes a connection to all of the clients in a group
func pushConnNow(up *rtpUpConnection, g *group.Group, cs []group.Client) {
up.mu.Lock()
up.pushed = true
replace := up.replace
up.replace = ""
tracks := make([]conn.UpTrack, len(up.tracks))
for i, t := range up.tracks {
tracks[i] = t
}
up.mu.Unlock()
for _, c := range cs {
c.PushConn(g, up.id, up, tracks, replace)
}
}
// pushConn schedules a call to pushConnNow
func pushConn(up *rtpUpConnection, g *group.Group, cs []group.Client) {
up.mu.Lock()
up.pushed = false
up.mu.Unlock()
go func(g *group.Group, cs []group.Client) {
time.Sleep(200 * time.Millisecond)
up.mu.Lock()
pushed := up.pushed
up.pushed = true
up.mu.Unlock()
if !pushed {
pushConnNow(up, g, cs)
}
}(g, cs)
}
func newUpConn(c group.Client, id string, label string, offer string) (*rtpUpConnection, error) {
var o sdp.SessionDescription
err := o.Unmarshal([]byte(offer))
if err != nil {
return nil, err
}
pc, err := c.Group().API().NewPeerConnection(*ice.ICEConfiguration())
if err != nil {
return nil, err
}
for _, m := range o.MediaDescriptions {
_, err = pc.AddTransceiverFromKind(
webrtc.NewRTPCodecType(m.MediaName.Media),
webrtc.RtpTransceiverInit{
Direction: webrtc.RTPTransceiverDirectionRecvonly,
},
)
if err != nil {
pc.Close()
return nil, err
}
}
up := &rtpUpConnection{id: id, label: label, pc: pc}
pc.OnTrack(func(remote *webrtc.TrackRemote, receiver *webrtc.RTPReceiver) {
up.mu.Lock()
track := &rtpUpTrack{
track: remote,
cache: packetcache.New(minPacketCache(remote)),
rate: estimator.New(time.Second),
jitter: jitter.New(remote.Codec().ClockRate),
atomics: &upTrackAtomics{},
localCh: make(chan localTrackAction, 2),
readerDone: make(chan struct{}),
}
up.tracks = append(up.tracks, track)
go readLoop(up, track)
go rtcpUpListener(up, track, receiver)
up.mu.Unlock()
pushConn(up, c.Group(), c.Group().GetClients(c))
})
pushConn(up, c.Group(), c.Group().GetClients(c))
go rtcpUpSender(up)
return up, nil
}
var ErrUnsupportedFeedback = errors.New("unsupported feedback type")
var ErrRateLimited = errors.New("rate limited")
func (up *rtpUpConnection) sendPLI(track *rtpUpTrack) error {
if !track.hasRtcpFb("nack", "pli") {
return ErrUnsupportedFeedback
}
last := atomic.LoadUint64(&track.atomics.lastPLI)
now := rtptime.Jiffies()
if now >= last && now-last < rtptime.JiffiesPerSec/2 {
return ErrRateLimited
}
atomic.StoreUint64(&track.atomics.lastPLI, now)
return sendPLI(up.pc, track.track.SSRC())
}
func sendPLI(pc *webrtc.PeerConnection, ssrc webrtc.SSRC) error {
return pc.WriteRTCP([]rtcp.Packet{
&rtcp.PictureLossIndication{MediaSSRC: uint32(ssrc)},
})
}
func (up *rtpUpConnection) sendFIR(track *rtpUpTrack, increment bool) error {
// we need to reliably increment the seqno, even if we are going
// to drop the packet due to rate limiting.
var seqno uint8
if increment {
seqno = uint8(atomic.AddUint32(&track.atomics.firSeqno, 1) & 0xFF)
} else {
seqno = uint8(atomic.LoadUint32(&track.atomics.firSeqno) & 0xFF)
}
if !track.hasRtcpFb("ccm", "fir") {
return ErrUnsupportedFeedback
}
last := atomic.LoadUint64(&track.atomics.lastFIR)
now := rtptime.Jiffies()
if now >= last && now-last < rtptime.JiffiesPerSec/2 {
return ErrRateLimited
}
atomic.StoreUint64(&track.atomics.lastFIR, now)
return sendFIR(up.pc, track.track.SSRC(), seqno)
}
func sendFIR(pc *webrtc.PeerConnection, ssrc webrtc.SSRC, seqno uint8) error {
return pc.WriteRTCP([]rtcp.Packet{
&rtcp.FullIntraRequest{
FIR: []rtcp.FIREntry{
{
SSRC: uint32(ssrc),
SequenceNumber: seqno,
},
},
},
})
}
func (up *rtpUpConnection) sendNACK(track *rtpUpTrack, first uint16, bitmap uint16) error {
if !track.hasRtcpFb("nack", "") {
return ErrUnsupportedFeedback
}
err := sendNACKs(up.pc, track.track.SSRC(),
[]rtcp.NackPair{{first, rtcp.PacketBitmap(bitmap)}},
)
if err == nil {
track.cache.Expect(1 + bits.OnesCount16(bitmap))
}
return err
}
func (up *rtpUpConnection) sendNACKs(track *rtpUpTrack, seqnos []uint16) error {
count := len(seqnos)
if count == 0 {
return nil
}
if !track.hasRtcpFb("nack", "") {
return ErrUnsupportedFeedback
}
var nacks []rtcp.NackPair
for len(seqnos) > 0 {
if len(nacks) >= 240 {
log.Printf("NACK: packet overflow")
break
}
var f, b uint16
f, b, seqnos = packetcache.ToBitmap(seqnos)
nacks = append(nacks, rtcp.NackPair{f, rtcp.PacketBitmap(b)})
}
err := sendNACKs(up.pc, track.track.SSRC(), nacks)
if err == nil {
track.cache.Expect(count)
}
return err
}
func sendNACKs(pc *webrtc.PeerConnection, ssrc webrtc.SSRC, nacks []rtcp.NackPair) error {
packet := rtcp.Packet(
&rtcp.TransportLayerNack{
MediaSSRC: uint32(ssrc),
Nacks: nacks,
},
)
return pc.WriteRTCP([]rtcp.Packet{packet})
}
func gotNACK(conn *rtpDownConnection, track *rtpDownTrack, p *rtcp.TransportLayerNack) {
var unhandled []uint16
var packet rtp.Packet
buf := make([]byte, packetcache.BufSize)
for _, nack := range p.Nacks {
nack.Range(func(seqno uint16) bool {
l := track.remote.GetRTP(seqno, buf)
if l == 0 {
unhandled = append(unhandled, seqno)
return true
}
err := packet.Unmarshal(buf[:l])
if err != nil {
return true
}
err = track.track.WriteRTP(&packet)
if err != nil {
log.Printf("WriteRTP: %v", err)
return false
}
track.rate.Accumulate(uint32(l))
return true
})
}
if len(unhandled) == 0 {
return
}
track.remote.Nack(conn.remote, unhandled)
}
func (track *rtpUpTrack) Nack(conn conn.Up, nacks []uint16) error {
track.mu.Lock()
defer track.mu.Unlock()
doit := len(track.bufferedNACKs) == 0
outer:
for _, nack := range nacks {
for _, seqno := range track.bufferedNACKs {
if seqno == nack {
continue outer
}
}
track.bufferedNACKs = append(track.bufferedNACKs, nack)
}
if doit {
up, ok := conn.(*rtpUpConnection)
if !ok {
log.Printf("Nack: unexpected type %T", conn)
return errors.New("unexpected connection type")
}
go nackWriter(up, track)
}
return nil
}
func rtcpUpListener(conn *rtpUpConnection, track *rtpUpTrack, r *webrtc.RTPReceiver) {
buf := make([]byte, 1500)
for {
firstSR := false
n, _, err := r.Read(buf)
if err != nil {
if err != io.EOF && err != io.ErrClosedPipe {
log.Printf("Read RTCP: %v", err)
}
return
}
ps, err := rtcp.Unmarshal(buf[:n])
if err != nil {
log.Printf("Unmarshal RTCP: %v", err)
continue
}
jiffies := rtptime.Jiffies()
for _, p := range ps {
local := track.getLocal()
switch p := p.(type) {
case *rtcp.SenderReport:
track.mu.Lock()
if track.srTime == 0 {
firstSR = true
}
track.srTime = jiffies
track.srNTPTime = p.NTPTime
track.srRTPTime = p.RTPTime
track.mu.Unlock()
for _, l := range local {
l.SetTimeOffset(p.NTPTime, p.RTPTime)
}
case *rtcp.SourceDescription:
for _, c := range p.Chunks {
if c.Source != uint32(track.track.SSRC()) {
continue
}
for _, i := range c.Items {
if i.Type != rtcp.SDESCNAME {
continue
}
track.cname.Store(i.Text)
for _, l := range local {
l.SetCname(i.Text)
}
}
}
}
}
if firstSR {
// this is the first SR we got for at least one track,
// quickly propagate the time offsets downstream
local := conn.getLocal()
for _, l := range local {
l, ok := l.(*rtpDownConnection)
if ok {
err := sendSR(l)
if err != nil {
log.Printf("sendSR: %v", err)
}
}
}
}
}
}
func sendUpRTCP(conn *rtpUpConnection) error {
tracks := conn.getTracks()
if len(conn.tracks) == 0 {
state := conn.pc.ConnectionState()
if state == webrtc.PeerConnectionStateClosed {
return io.ErrClosedPipe
}
return nil
}
now := rtptime.Jiffies()
reports := make([]rtcp.ReceptionReport, 0, len(conn.tracks))
for _, t := range tracks {
updateUpTrack(t)
expected, lost, totalLost, eseqno := t.cache.GetStats(true)
if expected == 0 {
expected = 1
}
if lost >= expected {
lost = expected - 1
}
t.mu.Lock()
srTime := t.srTime
srNTPTime := t.srNTPTime
t.mu.Unlock()
var delay uint64
if srTime != 0 {
delay = (now - srTime) /
(rtptime.JiffiesPerSec / 0x10000)
}
reports = append(reports, rtcp.ReceptionReport{
SSRC: uint32(t.track.SSRC()),
FractionLost: uint8((lost * 256) / expected),
TotalLost: totalLost,
LastSequenceNumber: eseqno,
Jitter: t.jitter.Jitter(),
LastSenderReport: uint32(srNTPTime >> 16),
Delay: uint32(delay),
})
}
packets := []rtcp.Packet{
&rtcp.ReceiverReport{
Reports: reports,
},
}
rate := ^uint64(0)
local := conn.getLocal()
for _, l := range local {
r := l.GetMaxBitrate(now)
if r < rate {
rate = r
}
}
if rate < group.MinBitrate {
rate = group.MinBitrate
}
var ssrcs []uint32
for _, t := range tracks {
if t.hasRtcpFb("goog-remb", "") {
continue
}
ssrcs = append(ssrcs, uint32(t.track.SSRC()))
}
if len(ssrcs) > 0 {
packets = append(packets,
&rtcp.ReceiverEstimatedMaximumBitrate{
Bitrate: rate,
SSRCs: ssrcs,
},
)
}
return conn.pc.WriteRTCP(packets)
}
func rtcpUpSender(conn *rtpUpConnection) {
for {
time.Sleep(time.Second)
err := sendUpRTCP(conn)
if err != nil {
if err == io.EOF || err == io.ErrClosedPipe {
return
}
log.Printf("sendUpRTCP: %v", err)
}
}
}
func sendSR(conn *rtpDownConnection) error {
tracks := conn.getTracks()
packets := make([]rtcp.Packet, 0, len(tracks))
now := time.Now()
nowNTP := rtptime.TimeToNTP(now)
jiffies := rtptime.TimeToJiffies(now)
for _, t := range tracks {
clockrate := t.track.Codec().ClockRate
var nowRTP uint32
remoteNTP, remoteRTP := t.getTimeOffset()
if remoteNTP != 0 {
srTime := rtptime.NTPToTime(remoteNTP)
d := now.Sub(srTime)
if d > 0 && d < time.Hour {
delay := rtptime.FromDuration(
d, clockrate,
)
nowRTP = remoteRTP + uint32(delay)
}
p, b := t.rate.Totals()
packets = append(packets,
&rtcp.SenderReport{
SSRC: uint32(t.ssrc),
NTPTime: nowNTP,
RTPTime: nowRTP,
PacketCount: p,
OctetCount: b,
})
t.setSRTime(jiffies, nowNTP)
}
cname, ok := t.cname.Load().(string)
if ok && cname != "" {
item := rtcp.SourceDescriptionItem{
Type: rtcp.SDESCNAME,
Text: cname,
}
packets = append(packets,
&rtcp.SourceDescription{
Chunks: []rtcp.SourceDescriptionChunk{
{
Source: uint32(t.ssrc),
Items: []rtcp.SourceDescriptionItem{item},
},
},
},
)
}
}
if len(packets) == 0 {
state := conn.pc.ConnectionState()
if state == webrtc.PeerConnectionStateClosed {
return io.ErrClosedPipe
}
return nil
}
return conn.pc.WriteRTCP(packets)
}
func rtcpDownSender(conn *rtpDownConnection) {
for {
time.Sleep(time.Second)
err := sendSR(conn)
if err != nil {
if err == io.EOF || err == io.ErrClosedPipe {
return
}
log.Printf("sendSR: %v", err)
}
}
}
const (
minLossRate = 9600
initLossRate = 512 * 1000
maxLossRate = 1 << 30
)
func (track *rtpDownTrack) updateRate(loss uint8, now uint64) {
rate := track.maxBitrate.Get(now)
if rate < minLossRate || rate > maxLossRate {
// no recent feedback, reset
rate = initLossRate
}
if loss < 5 {
// if our actual rate is low, then we're not probing the
// bottleneck
r, _ := track.rate.Estimate()
actual := 8 * uint64(r)
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.maxBitrate.Set(rate, now)
}
func rtcpDownListener(conn *rtpDownConnection, track *rtpDownTrack, s *webrtc.RTPSender) {
var gotFir bool
lastFirSeqno := uint8(0)
buf := make([]byte, 1500)
for {
n, _, err := s.Read(buf)
if err != nil {
if err != io.EOF && err != io.ErrClosedPipe {
log.Printf("Read RTCP: %v", err)
}
return
}
ps, err := rtcp.Unmarshal(buf[:n])
if err != nil {
log.Printf("Unmarshal RTCP: %v", err)
continue
}
jiffies := rtptime.Jiffies()
for _, p := range ps {
switch p := p.(type) {
case *rtcp.PictureLossIndication:
remote, ok := conn.remote.(*rtpUpConnection)
if !ok {
continue
}
rt, ok := track.remote.(*rtpUpTrack)
if !ok {
continue
}
err := remote.sendPLI(rt)
if err != nil && err != ErrRateLimited {
log.Printf("sendPLI: %v", err)
}
case *rtcp.FullIntraRequest:
found := false
var seqno uint8
for _, entry := range p.FIR {
if entry.SSRC == uint32(track.ssrc) {
found = true
seqno = entry.SequenceNumber
break
}
}
if !found {
log.Printf("Misdirected FIR")
continue
}
increment := true
if gotFir {
increment = seqno != lastFirSeqno
}
gotFir = true
lastFirSeqno = seqno
remote, ok := conn.remote.(*rtpUpConnection)
if !ok {
continue
}
rt, ok := track.remote.(*rtpUpTrack)
if !ok {
continue
}
err := remote.sendFIR(rt, increment)
if err == ErrUnsupportedFeedback {
err := remote.sendPLI(rt)
if err != nil && err != ErrRateLimited {
log.Printf("sendPLI: %v", err)
}
} else if err != nil && err != ErrRateLimited {
log.Printf("sendFIR: %v", err)
}
case *rtcp.ReceiverEstimatedMaximumBitrate:
conn.maxREMBBitrate.Set(p.Bitrate, jiffies)
case *rtcp.ReceiverReport:
for _, r := range p.Reports {
if r.SSRC == uint32(track.ssrc) {
handleReport(track, r, jiffies)
}
}
case *rtcp.SenderReport:
for _, r := range p.Reports {
if r.SSRC == uint32(track.ssrc) {
handleReport(track, r, jiffies)
}
}
case *rtcp.TransportLayerNack:
gotNACK(conn, track, p)
}
}
}
}
func handleReport(track *rtpDownTrack, report rtcp.ReceptionReport, jiffies uint64) {
track.stats.Set(report.FractionLost, report.Jitter, jiffies)
track.updateRate(report.FractionLost, jiffies)
if report.LastSenderReport != 0 {
jiffies := rtptime.Jiffies()
srTime, srNTPTime := track.getSRTime()
if jiffies < srTime || jiffies-srTime > 8*rtptime.JiffiesPerSec {
return
}
if report.LastSenderReport == uint32(srNTPTime>>16) {
delay := uint64(report.Delay) *
(rtptime.JiffiesPerSec / 0x10000)
if delay > jiffies-srTime {
return
}
rtt := (jiffies - srTime) - delay
oldrtt := track.getRTT()
newrtt := rtt
if oldrtt > 0 {
newrtt = (3*oldrtt + rtt) / 4
}
track.setRTT(newrtt)
}
}
}
func minPacketCache(track *webrtc.TrackRemote) int {
if track.Kind() == webrtc.RTPCodecTypeVideo {
return 128
}
return 24
}
func updateUpTrack(track *rtpUpTrack) {
now := rtptime.Jiffies()
clockrate := track.track.Codec().ClockRate
local := track.getLocal()
var maxrto uint64
for _, l := range local {
ll, ok := l.(*rtpDownTrack)
if ok {
_, j := ll.stats.Get(now)
jitter := uint64(j) *
(rtptime.JiffiesPerSec / uint64(clockrate))
rtt := ll.getRTT()
rto := rtt + 4*jitter
if rto > maxrto {
maxrto = rto
}
}
}
_, r := track.rate.Estimate()
packets := int((uint64(r) * maxrto * 4) / rtptime.JiffiesPerSec)
min := minPacketCache(track.track)
if packets < min {
packets = min
}
if packets > 1024 {
packets = 1024
}
track.cache.ResizeCond(packets)
}