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galene/rtpconn/rtpconn.go
2023-12-09 22:13:24 +01:00

1283 lines
28 KiB
Go

package rtpconn
import (
"errors"
"io"
"log"
"math/bits"
"os"
"sync"
"sync/atomic"
"time"
"github.com/pion/rtcp"
"github.com/pion/sdp/v3"
"github.com/pion/webrtc/v3"
"github.com/jech/galene/codecs"
"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/packetmap"
"github.com/jech/galene/rtptime"
"github.com/jech/galene/unbounded"
)
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
layerInfo uint32
}
type rtpDownTrack struct {
track *webrtc.TrackLocalStaticRTP
sender *webrtc.RTPSender
conn *rtpDownConnection
remote conn.UpTrack
ssrc webrtc.SSRC
packetmap packetmap.Map
maxBitrate *bitrate
maxREMBBitrate *bitrate
rate *estimator.Estimator
stats *receiverStats
atomics *downTrackAtomics
cname atomic.Value
}
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)
}
type layerInfo struct {
// current sid, desired sid, and max sid seen
sid, wantedSid, maxSid uint8
// current tid, desired tid, and max tid seen
tid, wantedTid, maxTid uint8
// if true, stick to sid 0
limitSid bool
}
func (down *rtpDownTrack) getLayerInfo() layerInfo {
info := atomic.LoadUint32(&down.atomics.layerInfo)
return layerInfo{
sid: uint8((info & 0xF)),
wantedSid: uint8((info >> 4) & 0xF),
maxSid: uint8((info >> 8) & 0xF),
limitSid: ((info >> 12) & 1) != 0,
tid: uint8((info >> 16) & 0xF),
wantedTid: uint8((info >> 20) & 0xF),
maxTid: uint8((info >> 24) & 0xF),
}
}
func (down *rtpDownTrack) setLayerInfo(info layerInfo) {
var l uint32
if info.limitSid {
l = 1 << 12
}
atomic.StoreUint32(&down.atomics.layerInfo,
uint32(info.sid&0xF)|
uint32(info.wantedSid&0xF)<<4|
uint32(info.maxSid&0xF)<<8|
l|
uint32(info.tid&0xF)<<16|
uint32(info.wantedTid&0xF)<<20|
uint32(info.maxTid&0xF)<<24,
)
}
const (
negotiationUnneeded = iota
negotiationNeeded
negotiationRestartIce
)
type rtpDownConnection struct {
id string
pc *webrtc.PeerConnection
remote conn.Up
iceCandidates []*webrtc.ICECandidateInit
negotiationNeeded int
requested []string
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, err := c.Group().API()
if err != nil {
return nil, err
}
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,
}
return conn, nil
}
var packetBufPool = sync.Pool{
New: func() interface{} {
return make([]byte, packetcache.BufSize)
},
}
func (down *rtpDownTrack) Write(buf []byte) (int, error) {
codec := down.remote.Codec().MimeType
flags, err := codecs.PacketFlags(codec, buf)
if err != nil {
return 0, err
}
layer := down.getLayerInfo()
if flags.Tid > layer.maxTid || flags.Sid > layer.maxSid {
if flags.Tid > layer.maxTid {
// increase eagerly if this is the first time we
// see a given layer
if layer.tid == layer.maxTid {
layer.wantedTid = flags.Tid
layer.tid = flags.Tid
}
layer.maxTid = flags.Tid
}
if flags.Sid > layer.maxSid {
if layer.sid == layer.maxSid && !layer.limitSid {
layer.wantedSid = flags.Sid
layer.sid = flags.Sid
}
layer.maxSid = flags.Sid
}
down.setLayerInfo(layer)
down.adjustLayer()
layer = down.getLayerInfo()
}
if flags.Start && (layer.tid != layer.wantedTid) {
if flags.Keyframe {
layer.tid = layer.wantedTid
down.setLayerInfo(layer)
} else if layer.wantedTid < layer.tid {
layer.tid = layer.wantedTid
down.setLayerInfo(layer)
} else if flags.TidUpSync && flags.Tid <= layer.wantedTid {
layer.tid = flags.Tid
down.setLayerInfo(layer)
}
}
if flags.Start && (layer.sid != layer.wantedSid) {
if flags.Keyframe {
layer.sid = layer.wantedSid
down.setLayerInfo(layer)
} else {
down.remote.RequestKeyframe()
}
}
if flags.Tid > layer.tid || flags.Sid > layer.sid ||
(flags.Sid < layer.sid && flags.SidNonReference) {
ok := down.packetmap.Drop(flags.Seqno, flags.Pid)
if ok {
return 0, nil
}
}
ok, newseqno, piddelta := down.packetmap.Map(flags.Seqno, flags.Pid)
if !ok {
return 0, nil
}
setMarker := flags.Sid == layer.sid && flags.End && !flags.Marker
if !setMarker && newseqno == flags.Seqno && piddelta == 0 {
return down.write(buf)
}
ibuf2 := packetBufPool.Get()
defer packetBufPool.Put(ibuf2)
buf2 := ibuf2.([]byte)
n := copy(buf2, buf)
err = codecs.RewritePacket(codec, buf2[:n], setMarker, newseqno, piddelta)
if err != nil {
return 0, err
}
return down.write(buf2[:n])
}
func (down *rtpDownTrack) write(buf []byte) (int, error) {
n, err := down.track.Write(buf)
if err == nil {
down.rate.Accumulate(uint32(n))
}
return n, err
}
func (t *rtpDownTrack) GetMaxBitrate() (uint64, int, int) {
now := rtptime.Jiffies()
layer := t.getLayerInfo()
r := t.maxBitrate.Get(now)
if r == ^uint64(0) {
r = 512 * 1024
}
rr := t.maxREMBBitrate.Get(now)
if rr != 0 && rr < r {
r = rr
}
return r, int(layer.sid), int(layer.tid)
}
// adjustLayer checks the allowable bitrate reported for a down track and
// adjusts the layer by one step. It prefers temporal layers, and only
// uses spatial layers as a last resort.
func (t *rtpDownTrack) adjustLayer() {
max, _, _ := t.GetMaxBitrate()
r, _ := t.rate.Estimate()
rate := uint64(r) * 8
if rate < max*7/8 {
// switch up
layer := t.getLayerInfo()
if layer.limitSid && layer.wantedSid != 0 {
layer.wantedSid = 0
t.setLayerInfo(layer)
} else if !layer.limitSid && layer.sid < layer.maxSid {
layer.wantedSid = layer.sid + 1
t.setLayerInfo(layer)
} else if layer.tid < layer.maxTid {
layer.wantedTid = layer.tid + 1
t.setLayerInfo(layer)
}
} else if rate > max*3/2 {
// switch down
layer := t.getLayerInfo()
if layer.tid > 0 {
layer.wantedTid = layer.tid - 1
t.setLayerInfo(layer)
} else if layer.sid > 0 {
if layer.limitSid {
layer.wantedSid = 0
} else {
layer.wantedSid = layer.sid - 1
}
t.setLayerInfo(layer)
}
}
}
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 rtpUpTrack struct {
track *webrtc.TrackRemote
receiver *webrtc.RTPReceiver
conn *rtpUpConnection
rate *estimator.Estimator
cache *packetcache.Cache
jitter *jitter.Estimator
cname atomic.Value
actions *unbounded.Channel[trackAction]
readerDone chan struct{}
mu sync.Mutex
srTime uint64
srNTPTime uint64
srRTPTime uint32
local []conn.DownTrack
bufferedNACKs []uint16
}
type trackActionKind int
const (
trackActionAdd trackActionKind = iota
trackActionDel
trackActionKeyframe
)
type trackAction struct {
action trackActionKind
track conn.DownTrack
}
func (up *rtpUpTrack) action(action trackActionKind, track conn.DownTrack) {
up.actions.Put(trackAction{action, track})
}
func (up *rtpUpTrack) AddLocal(local conn.DownTrack) error {
up.mu.Lock()
for _, t := range up.local {
if t == local {
up.mu.Unlock()
return nil
}
}
if up.srNTPTime != 0 {
local.SetTimeOffset(up.srNTPTime, up.srRTPTime)
}
cname, ok := up.cname.Load().(string)
if ok && cname != "" {
local.SetCname(cname)
}
up.local = append(up.local, local)
up.mu.Unlock()
up.action(trackActionAdd, local)
return nil
}
func (up *rtpUpTrack) RequestKeyframe() error {
up.action(trackActionKeyframe, nil)
return nil
}
func (up *rtpUpTrack) DelLocal(local conn.DownTrack) bool {
up.mu.Lock()
for i, l := range up.local {
if l == local {
up.local = append(up.local[:i], up.local[i+1:]...)
up.mu.Unlock()
up.action(trackActionDel, l)
return true
}
}
up.mu.Unlock()
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) Label() string {
return up.track.RID()
}
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
client group.Client
label string
pc *webrtc.PeerConnection
iceCandidates []*webrtc.ICECandidateInit
mu sync.Mutex
closed bool
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.client.Id(), up.client.Username()
}
func (up *rtpUpConnection) AddLocal(local conn.Down) error {
up.mu.Lock()
defer up.mu.Unlock()
// the connection may have been closed in the meantime, in which
// case we'd never get rid of the down connection
if up.closed {
return os.ErrClosed
}
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
}
api, err := c.Group().API()
if err != nil {
return nil, err
}
pc, err := 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, client: c, label: label, pc: pc}
pc.OnTrack(func(remote *webrtc.TrackRemote, receiver *webrtc.RTPReceiver) {
up.mu.Lock()
track := &rtpUpTrack{
track: remote,
receiver: receiver,
conn: up,
cache: packetcache.New(minPacketCache(remote)),
rate: estimator.New(time.Second),
jitter: jitter.New(remote.Codec().ClockRate),
actions: unbounded.New[trackAction](),
readerDone: make(chan struct{}),
}
up.tracks = append(up.tracks, track)
go readLoop(track)
go rtcpUpListener(track)
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 (track *rtpUpTrack) sendPLI() error {
if !track.hasRtcpFb("nack", "pli") {
return ErrUnsupportedFeedback
}
return sendPLI(track.conn.pc, track.track.SSRC())
}
func sendPLI(pc *webrtc.PeerConnection, ssrc webrtc.SSRC) error {
return pc.WriteRTCP([]rtcp.Packet{
&rtcp.PictureLossIndication{MediaSSRC: uint32(ssrc)},
})
}
func (track *rtpUpTrack) sendNACK(first uint16, bitmap uint16) error {
if !track.hasRtcpFb("nack", "") {
return ErrUnsupportedFeedback
}
err := sendNACKs(track.conn.pc, track.track.SSRC(),
[]rtcp.NackPair{{first, rtcp.PacketBitmap(bitmap)}},
)
if err == nil {
track.cache.Expect(1 + bits.OnesCount16(bitmap))
}
return err
}
func (track *rtpUpTrack) sendNACKs(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(track.conn.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(track *rtpDownTrack, p *rtcp.TransportLayerNack) {
buf := make([]byte, packetcache.BufSize)
for _, nack := range p.Nacks {
nack.Range(func(s uint16) bool {
ok, seqno, _ := track.packetmap.Reverse(s)
if !ok {
return true
}
l := track.remote.GetPacket(seqno, buf, true)
if l == 0 {
return true
}
_, err := track.Write(buf[:l])
if err != nil {
log.Printf("Write: %v", err)
return false
}
return true
})
}
}
func (track *rtpUpTrack) GetPacket(seqno uint16, result []byte, nack bool) uint16 {
n := track.cache.Get(seqno, result)
if n > 0 || !nack {
return n
}
track.mu.Lock()
defer track.mu.Unlock()
doit := len(track.bufferedNACKs) == 0
for _, s := range track.bufferedNACKs {
if s == seqno {
return 0
}
}
track.bufferedNACKs = append(track.bufferedNACKs, seqno)
if doit {
go nackWriter(track)
}
return 0
}
func rtcpUpListener(track *rtpUpTrack) {
buf := make([]byte, 1500)
for {
firstSR := false
n, _, err := track.receiver.ReadSimulcast(buf, track.track.RID())
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 := track.conn.getLocal()
for _, l := range local {
l, ok := l.(*rtpDownConnection)
if ok {
err := sendSR(l)
if err != nil {
log.Printf("sendSR: %v", err)
}
}
}
}
}
}
// saturating addition
func sadd(x, y uint64) uint64 {
s, c := bits.Add64(x, y, 0)
if c != 0 {
return ^uint64(0)
}
return s
}
func maxUpBitrate(t *rtpUpTrack) uint64 {
minrate := ^uint64(0)
maxrate := uint64(group.MinBitrate)
maxsid := 0
maxtid := 0
local := t.getLocal()
for _, down := range local {
r, sid, tid := down.GetMaxBitrate()
if maxsid < sid {
maxsid = sid
}
if maxtid < tid {
maxtid = tid
}
if r < group.MinBitrate {
r = group.MinBitrate
}
if minrate > r {
minrate = r
}
if maxrate < r {
maxrate = r
}
}
// assume that lower spatial layers take up 1/5 of
// the throughput
if maxsid > 0 {
maxrate = sadd(maxrate, maxrate/4)
}
// assume that each layer takes two times less
// throughput than the higher one. Then we've
// got enough slack for a factor of 2^(layers-1).
for i := 0; i < maxtid; i++ {
minrate = sadd(minrate, minrate)
}
if minrate < maxrate {
return minrate
}
return maxrate
}
func sendUpRTCP(up *rtpUpConnection) error {
tracks := up.getTracks()
if len(up.tracks) == 0 {
state := up.pc.ConnectionState()
if state == webrtc.PeerConnectionStateClosed {
return io.ErrClosedPipe
}
return nil
}
now := rtptime.Jiffies()
reports := make([]rtcp.ReceptionReport, 0, len(up.tracks))
for _, t := range tracks {
updateUpTrack(t)
stats := t.cache.GetStats(true)
var totalLost uint32
if stats.TotalExpected > stats.TotalReceived {
totalLost = stats.TotalExpected - stats.TotalReceived
}
var fractionLost uint32
if stats.Expected > stats.Received {
lost := stats.Expected - stats.Received
fractionLost = lost * 256 / stats.Expected
if fractionLost >= 255 {
fractionLost = 255
}
}
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(fractionLost),
TotalLost: totalLost,
LastSequenceNumber: stats.ESeqno,
Jitter: t.jitter.Jitter(),
LastSenderReport: uint32(srNTPTime >> 16),
Delay: uint32(delay),
})
}
packets := []rtcp.Packet{
&rtcp.ReceiverReport{
Reports: reports,
},
}
var ssrcs []uint32
var rate uint64
for _, t := range tracks {
if !t.hasRtcpFb("goog-remb", "") {
continue
}
ssrcs = append(ssrcs, uint32(t.track.SSRC()))
if t.Kind() == webrtc.RTPCodecTypeAudio {
rate = sadd(rate, 100*1024)
} else if t.Label() == "l" {
rate = sadd(rate, group.LowBitrate)
} else {
rate = sadd(rate, maxUpBitrate(t))
}
}
if rate > group.MaxBitrate {
rate = group.MaxBitrate
}
if len(ssrcs) > 0 {
packets = append(packets,
&rtcp.ReceiverEstimatedMaximumBitrate{
Bitrate: float32(rate),
SSRCs: ssrcs,
},
)
}
return up.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: uint32(p),
OctetCount: uint32(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 / 2)
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*3)/4 {
// 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(track *rtpDownTrack) {
lastFirSeqno := uint8(0)
buf := make([]byte, 1500)
for {
n, _, err := track.sender.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
}
adjust := false
jiffies := rtptime.Jiffies()
for _, p := range ps {
switch p := p.(type) {
case *rtcp.PictureLossIndication:
track.remote.RequestKeyframe()
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
}
if seqno != lastFirSeqno {
track.remote.RequestKeyframe()
}
case *rtcp.ReceiverEstimatedMaximumBitrate:
rate := uint64(p.Bitrate + 0.5)
track.maxREMBBitrate.Set(rate, jiffies)
adjust = true
case *rtcp.ReceiverReport:
for _, r := range p.Reports {
if r.SSRC == uint32(track.ssrc) {
handleReport(track, r, jiffies)
adjust = true
}
}
case *rtcp.SenderReport:
for _, r := range p.Reports {
if r.SSRC == uint32(track.ssrc) {
handleReport(track, r, jiffies)
}
}
case *rtcp.TransportLayerNack:
gotNACK(track, p)
}
}
if adjust {
track.adjustLayer()
}
}
}
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)
}