WebRTC 时延计算优化

Tạo vào: 21 tháng 11, 2024

Trả lời bằng OpenAI 01 Mini bởi OpenAI01

Câu hỏi

class VideoInitiatorFragment : Fragment() {

companion object {
fun newInstance(
room: String,
stunUrl: String,
turnUrl: String,
turnUsername: String,
turnPassword: String,
signalingServerUrl: String
): VideoInitiatorFragment {
val fragment = VideoInitiatorFragment()
val args = Bundle().apply {
putString("room", room)
putString("stunUrl", stunUrl)
putString("turnUrl", turnUrl)
putString("turnUsername", turnUsername)
putString("turnPassword", turnPassword)
putString("signalingServerUrl", signalingServerUrl)
}
fragment.arguments = args
return fragment
}
}

// Class member variables remain unchanged
private lateinit var socket: Socket
private var localPeer: PeerConnection? = null
private var localView: SurfaceViewRenderer? = null
private var localEglBase: EglBase? = null
private val pendingIceCandidates = mutableListOf<IceCandidate>()
private var currentRoom: String? = null
private lateinit var signalingServerUrl: String
private lateinit var stunUrl: String
private lateinit var turnUrl: String
private lateinit var turnUsername: String
private lateinit var turnPassword: String

private val TAG: String = "WebRTC-Initiator"

// State variables for RTT and OWD
private val rttState = mutableLongStateOf(0L)
private val rttHistory = mutableStateListOf<Long>()
private val owdState = mutableLongStateOf(0L)
private val owdHistory = mutableStateListOf<Long>()
private var clockOffset: Long = 0L

private var statsJob: Job? = null

override fun onCreate(savedInstanceState: Bundle?) {
super.onCreate(savedInstanceState)

// Retrieve data from arguments
currentRoom = arguments?.getString("room") ?: "default-room"
signalingServerUrl = arguments?.getString("signalingServerUrl") ?: "https://wstszx.us.kg"
stunUrl = arguments?.getString("stunUrl") ?: "stun:stun.wstszx.us.kg:3478"
turnUrl = arguments?.getString("turnUrl") ?: "turn:turn.wstszx.us.kg:5349"
turnUsername = arguments?.getString("turnUsername") ?: "wstszx"
turnPassword = arguments?.getString("turnPassword") ?: "930379"

Log.d(
TAG,
"onCreate: Role = Initiator, Room = $currentRoom, Signaling Server = $signalingServerUrl, STUN URL = $stunUrl, TURN URL = $turnUrl"
)
}

private val requestPermissionsLauncher =
registerForActivityResult(ActivityResultContracts.RequestMultiplePermissions()) { permissions ->
permissions.entries.forEach { (permission, isGranted) ->
if (isGranted) {
Toast.makeText(requireContext(), "$permission 权限已授予", Toast.LENGTH_SHORT).show()
} else {
Toast.makeText(requireContext(), "$permission 权限被拒绝", Toast.LENGTH_SHORT).show()
}
}
onPermissionsChecked()
}

override fun onCreateView(
inflater: android.view.LayoutInflater,
container: android.view.ViewGroup?,
savedInstanceState: Bundle?
): android.view.View {
return ComposeView(requireContext()).apply {
setContent {
WebRTCComposeLayout()
}
}
}

@Composable
fun WebRTCComposeLayout() {
val context = LocalContext.current
lateinit var peerConnectionFactory: PeerConnectionFactory
var localVideoTrack: VideoTrack? by remember { mutableStateOf(null) }

Surface(color = Color.Black) {
Column(modifier = Modifier.fillMaxSize()) {

// Local video view
AndroidView(
factory = {
localView = SurfaceViewRenderer(it).apply {
setZOrderMediaOverlay(false)
}
localView!!
},
modifier = Modifier
.weight(1f)
.fillMaxWidth(),
update = {
if (localEglBase == null) {
localEglBase = EglBase.create()
it.init(localEglBase!!.eglBaseContext, null)
it.setMirror(false)
}
}
)

Spacer(modifier = Modifier.height(8.dp))

// 并排显示 OWD 和 RTT
Row(
modifier = Modifier
.fillMaxWidth()
.padding(horizontal = 16.dp),
horizontalArrangement = Arrangement.SpaceEvenly
) {
// 单向时延 (OWD) 列
Column(modifier = Modifier.weight(1f)) {
Text(
text = "单向时延 (OWD)",
color = Color.Cyan,
style = MaterialTheme.typography.titleMedium,
modifier = Modifier.padding(bottom = 4.dp)
)
Text(
text = "最新: ${owdState.longValue} ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 2.dp)
)
Text(
text = "最大: ${owdHistory.maxOrNull() ?: 0} ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 2.dp)
)
Text(
text = "最小: ${owdHistory.minOrNull() ?: 0} ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 2.dp)
)
val averageOwd = if (owdHistory.isNotEmpty()) owdHistory.average().toLong() else 0L
Text(
text = "平均: $averageOwd ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium
)
}

Spacer(modifier = Modifier.width(16.dp))

// 往返时延 (RTT) 列
Column(modifier = Modifier.weight(1f)) {
Text(
text = "往返时延 (RTT)",
color = Color.Cyan,
style = MaterialTheme.typography.titleMedium,
modifier = Modifier.padding(bottom = 4.dp)
)
Text(
text = "最新: ${rttState.longValue} ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 2.dp)
)
Text(
text = "最大: ${rttHistory.maxOrNull() ?: 0} ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 2.dp)
)
Text(
text = "最小: ${rttHistory.minOrNull() ?: 0} ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 2.dp)
)
val averageRtt = if (rttHistory.isNotEmpty()) rttHistory.average().toLong() else 0L
Text(
text = "平均: $averageRtt ms",
color = Color.White,
style = MaterialTheme.typography.bodyMedium
)
}
}

}

LaunchedEffect(Unit) {
val options = PeerConnectionFactory.InitializationOptions.builder(context)
.createInitializationOptions()
PeerConnectionFactory.initialize(options)

val encoderFactory = DefaultVideoEncoderFactory(
localEglBase!!.eglBaseContext, true, true
)

val decoderFactory = DefaultVideoDecoderFactory(localEglBase!!.eglBaseContext)

peerConnectionFactory = PeerConnectionFactory.builder()
.setVideoEncoderFactory(encoderFactory)
.setVideoDecoderFactory(decoderFactory)
.createPeerConnectionFactory()

initLocalVideo(context, localView, peerConnectionFactory, localEglBase!!) {
localVideoTrack = it
}

createPeerConnection(
context,
peerConnectionFactory,
localVideoTrack
) {
localPeer = it
startStatsCollection() // Start collecting statistics
}

initializeSocketIO()

requestPermissionsIfNeeded()
startTimeSync()
}
}
}

private fun startTimeSync(intervalMs: Long = 5000L) {
viewLifecycleOwner.lifecycleScope.launch {
while (isActive) {
delay(intervalMs) // Sync every 5 seconds
requestTimeSync()
}
}
}

private fun startStatsCollection() {
statsJob = viewLifecycleOwner.lifecycleScope.launch {
while (isActive) {
delay(1000) // Collect stats every second
localPeer?.getStats { report ->
parseStatsReport(report)
} ?: Log.e(TAG, "Failed to get stats: localPeer is null.")
}
}
}

private fun parseStatsReport(report: RTCStatsReport) {
Log.d(TAG, "RTCStatsReport: ${report.statsMap}")
for (stats in report.statsMap.values) {
Log.d(TAG, "Stats type: ${stats.type}")
if (stats.type == "transport") {
Log.d(TAG, "Transport Stats found: $stats")
val currentRtt = (stats.members["currentRoundTripTime"] as? Number)?.toDouble()?.times(1000)?.toLong()
if (currentRtt != null && currentRtt > 0) {
viewLifecycleOwner.lifecycleScope.launch {
// Update RTT state
rttState.longValue = currentRtt

// Update RTT history
rttHistory.add(currentRtt)
if (rttHistory.size > 60) {
rttHistory.removeAt(0)
}

// Calculate max, min, and average RTT
val maxRtt = rttHistory.maxOrNull() ?: 0L
val minRtt = rttHistory.minOrNull() ?: 0L
val averageRtt = if (rttHistory.isNotEmpty()) {
rttHistory.average().toLong()
} else {
0L
}

Log.d(TAG, "RTT - Latest: $currentRtt ms, Max: $maxRtt ms, Min: $minRtt ms, Average: $averageRtt ms")
}
}
}
}
}

private fun initializeSocketIO() {
val protocol = if (signalingServerUrl.startsWith("https")) "https" else "http"
val socketUrl = signalingServerUrl

val options = IO.Options().apply {
transports = arrayOf("websocket")
secure = protocol == "https"
path = "/socket.io/"
}

try {
socket = IO.socket(socketUrl, options)

socket.on(Socket.EVENT_CONNECT) {
Log.d(TAG, "Socket connected")
socket.emit("join", currentRoom)
Log.d(TAG, "Joined room: $currentRoom")
}

socket.on(Socket.EVENT_CONNECT_ERROR) { args ->
if (args.isNotEmpty()) {
val error = args[0]
Log.e(TAG, "Socket connection error: $error")
}
}

socket.on(Socket.EVENT_DISCONNECT) { args ->
if (args.isNotEmpty()) {
val reason = args[0]
Log.d(TAG, "Socket disconnected: $reason")
}
}

socket.on("signal") { args ->
Log.d(TAG, "Received signaling: ${args[0]}")
if (args.isNotEmpty() && args[0] is JSONObject) {
val data = args[0] as JSONObject
handleSignalingData(data)
}
}

socket.connect()
Log.d(TAG, "Connecting to Socket: $socketUrl...")
} catch (e: Exception) {
Log.e(TAG, "Error connecting to Socket: ${e.message}")
}
}

private fun requestPermissionsIfNeeded() {
val permissions = arrayOf(
Manifest.permission.CAMERA,
Manifest.permission.RECORD_AUDIO,
Manifest.permission.INTERNET,
Manifest.permission.ACCESS_NETWORK_STATE
)

val permissionsToRequest = permissions.filter {
ContextCompat.checkSelfPermission(requireContext(), it) != PackageManager.PERMISSION_GRANTED
}

if (permissionsToRequest.isNotEmpty()) {
requestPermissionsLauncher.launch(permissionsToRequest.toTypedArray())
} else {
onPermissionsChecked()
}
}

private fun onPermissionsChecked() {
Toast.makeText(requireContext(), "所有必要权限已被授予", Toast.LENGTH_SHORT).show()
}

private fun initLocalVideo(
context: Context,
localView: SurfaceViewRenderer?,
peerConnectionFactory: PeerConnectionFactory,
eglBase: EglBase,
onLocalVideoTrack: (VideoTrack) -> Unit
) {
val videoCapturer = createCameraCapturer(context)
val surfaceTextureHelper = SurfaceTextureHelper.create("CaptureThread", eglBase.eglBaseContext)
val videoSource = peerConnectionFactory.createVideoSource(videoCapturer.isScreencast)
videoCapturer.initialize(surfaceTextureHelper, context, videoSource.capturerObserver)

videoCapturer.startCapture(1920, 1080, 60)

val localVideoTrack = peerConnectionFactory.createVideoTrack("video_track", videoSource)
localVideoTrack.addSink(localView)

val audioSource = peerConnectionFactory.createAudioSource(MediaConstraints())
val localAudioTrack = peerConnectionFactory.createAudioTrack("audio_track", audioSource)

// Add audio and video tracks to local stream
val mediaStream = peerConnectionFactory.createLocalMediaStream("local_stream")
mediaStream.addTrack(localAudioTrack)
mediaStream.addTrack(localVideoTrack)

onLocalVideoTrack(localVideoTrack)
}

private fun createCameraCapturer(context: Context): CameraVideoCapturer {
val camera2Enumerator = Camera2Enumerator(context)
val deviceNames = camera2Enumerator.deviceNames

// Prefer back-facing camera
for (deviceName in deviceNames) {
if (camera2Enumerator.isBackFacing(deviceName)) {
val capturer = camera2Enumerator.createCapturer(deviceName, null)
if (capturer != null) {
return capturer
}
}
}

// Fallback to front-facing camera
for (deviceName in deviceNames) {
if (camera2Enumerator.isFrontFacing(deviceName)) {
val capturer = camera2Enumerator.createCapturer(deviceName, null)
if (capturer != null) {
return capturer
}
}
}

// Fallback to first available camera
return camera2Enumerator.createCapturer(deviceNames[0], null)
?: throw IllegalStateException("Unable to create camera capturer")
}

private fun createPeerConnection(
context: Context,
peerConnectionFactory: PeerConnectionFactory,
localVideoTrack: VideoTrack?,
onLocalPeerCreated: (PeerConnection) -> Unit
) {
val iceServers = listOf(
PeerConnection.IceServer.builder(stunUrl).createIceServer(),
PeerConnection.IceServer.builder(turnUrl)
.setUsername(turnUsername)
.setPassword(turnPassword)
.createIceServer()
)

val rtcConfig = PeerConnection.RTCConfiguration(iceServers).apply {
bundlePolicy = PeerConnection.BundlePolicy.MAXBUNDLE
rtcpMuxPolicy = PeerConnection.RtcpMuxPolicy.REQUIRE
tcpCandidatePolicy = PeerConnection.TcpCandidatePolicy.ENABLED
continualGatheringPolicy = PeerConnection.ContinualGatheringPolicy.GATHER_CONTINUALLY
sdpSemantics = PeerConnection.SdpSemantics.UNIFIED_PLAN
}

localPeer = peerConnectionFactory.createPeerConnection(rtcConfig, object : PeerConnection.Observer {
override fun onIceCandidate(iceCandidate: IceCandidate?) {
iceCandidate?.let {
Log.d(TAG, "ICE candidate: $it")
val signalData = JSONObject().apply {
put("type", "ice")
put("candidate", JSONObject().apply {
put("sdpMid", it.sdpMid)
put("sdpMLineIndex", it.sdpMLineIndex)
put("candidate", it.sdp)
})
put("room", currentRoom)
}
socket.emit("signal", signalData)
}
}

override fun onIceCandidatesRemoved(candidates: Array<out IceCandidate>?) {
Log.d(TAG, "ICE candidates removed")
}

override fun onSignalingChange(newState: PeerConnection.SignalingState?) {
Log.d(TAG, "Signaling state changed to: $newState")
}

override fun onIceConnectionChange(newState: PeerConnection.IceConnectionState?) {
Log.d(TAG, "ICE connection state changed to: $newState")
}

override fun onIceConnectionReceivingChange(receiving: Boolean) {
Log.d(TAG, "ICE connection receiving change: $receiving")
}

override fun onIceGatheringChange(newState: PeerConnection.IceGatheringState?) {
Log.d(TAG, "ICE gathering state changed to: $newState")
}

override fun onAddStream(stream: MediaStream?) {
Log.d(TAG, "Stream added")
}

override fun onRemoveStream(stream: MediaStream?) {
Log.d(TAG, "Stream removed")
}

override fun onDataChannel(dataChannel: DataChannel?) {
Log.d(TAG, "Data channel created")
}

override fun onRenegotiationNeeded() {
Log.d(TAG, "Renegotiation needed")
}

override fun onAddTrack(receiver: RtpReceiver?, streams: Array<out MediaStream>?) {
Log.d(TAG, "Track added")
}

override fun onTrack(transceiver: RtpTransceiver?) {
Log.d(TAG, "onTrack called")
}

override fun onConnectionChange(newState: PeerConnection.PeerConnectionState?) {
Log.d(TAG, "Connection state changed to: $newState")
}
})

localVideoTrack?.let {
localPeer?.addTrack(it, listOf("local_stream"))
}
val audioSource = peerConnectionFactory.createAudioSource(MediaConstraints())
val localAudioTrack = peerConnectionFactory.createAudioTrack("audio_track", audioSource)
localPeer?.addTrack(localAudioTrack, listOf("local_stream"))

onLocalPeerCreated(localPeer!!)
}

private fun createAnswer(peerConnection: PeerConnection, onAnswerCreated: (String) -> Unit) {
Log.d(TAG, "Creating answer...")
val constraints = MediaConstraints().apply {
mandatory.add(MediaConstraints.KeyValuePair("OfferToReceiveAudio", "true"))
mandatory.add(MediaConstraints.KeyValuePair("OfferToReceiveVideo", "true"))
}

peerConnection.createAnswer(object : SdpObserver {
override fun onCreateSuccess(sessionDescription: SessionDescription?) {
sessionDescription?.let { sdp ->
peerConnection.setLocalDescription(object : SdpObserver {
override fun onSetSuccess() {
Log.d(TAG, "SetLocalDescription onSetSuccess")
onAnswerCreated(sdp.description)
}

override fun onSetFailure(error: String?) {
Log.e(TAG, "SetLocalDescription onSetFailure: $error")
}

override fun onCreateSuccess(p0: SessionDescription?) {}
override fun onCreateFailure(p0: String?) {}
}, sdp)
}
}

override fun onSetSuccess() {
Log.d(TAG, "createAnswer onSetSuccess")
}

override fun onCreateFailure(error: String?) {
Log.e(TAG, "createAnswer onCreateFailure: $error")
}

override fun onSetFailure(error: String?) {}
}, constraints)
}

private fun handleSignalingData(data: JSONObject) {
Log.d(TAG, "Handling signaling data: $data")
when (data.getString("type")) {
"offer" -> {
Log.d(TAG, "Received offer")
val sdp = SessionDescription(
SessionDescription.Type.OFFER,
data.getJSONObject("sdp").getString("sdp")
)
localPeer?.setRemoteDescription(object : SdpObserver {
override fun onSetSuccess() {
Log.d(TAG, "Set remote description (offer) success")
createAnswer(localPeer!!) { answer ->
val signalData = JSONObject().apply {
put("type", "answer")
put("sdp", JSONObject().put("sdp", answer))
put("room", currentRoom)
}

socket.emit("signal", signalData)

pendingIceCandidates.forEach { candidate ->
localPeer?.addIceCandidate(candidate)
}
pendingIceCandidates.clear()
}
}

override fun onSetFailure(error: String?) {
Log.e(TAG, "Set remote description (offer) error: $error")
}

override fun onCreateSuccess(p0: SessionDescription?) {}
override fun onCreateFailure(p0: String?) {}
}, sdp)
}

"answer" -> {
Log.d(TAG, "Received answer")
val sdp = SessionDescription(
SessionDescription.Type.ANSWER,
data.getJSONObject("sdp").getString("sdp")
)
localPeer?.setRemoteDescription(object : SdpObserver {
override fun onSetSuccess() {
pendingIceCandidates.forEach { candidate ->
localPeer?.addIceCandidate(candidate)
}
pendingIceCandidates.clear()
Log.d(TAG, "Set remote description (answer) success")
}

override fun onSetFailure(error: String?) {
Log.e(TAG, "Set remote description error: $error")
}

override fun onCreateSuccess(p0: SessionDescription?) {}
override fun onCreateFailure(p0: String?) {}
}, sdp)
}

"ice" -> {
Log.d(TAG, "Received ICE candidate")
val candidateData = data.getJSONObject("candidate")
val candidate = IceCandidate(
candidateData.getString("sdpMid"),
candidateData.getInt("sdpMLineIndex"),
candidateData.getString("candidate")
)

if (localPeer?.remoteDescription != null) {
localPeer?.addIceCandidate(candidate)
} else {
pendingIceCandidates.add(candidate)
}
}

"time_sync_response" -> {
Log.d(TAG, "Received time_sync_response")
val t1 = data.getLong("t1")
val t2 = data.getLong("t2")
val t3 = data.getLong("t3")
val t4 = System.currentTimeMillis()

// 计算 RTT 和时钟偏移量
val rtt = t4 - t1 - (t3 - t2)
clockOffset = ((t2 - t1) + (t3 - t4)) / 2

Log.d(TAG, "时间同步: RTT=$rtt ms, 时钟偏移量= $clockOffset ms")

// 计算单向时延 OWD
val owd = (t2 - t1) - clockOffset
if (owd >= 0) {
viewLifecycleOwner.lifecycleScope.launch {
// 更新 RTT 状态
rttState.longValue = rtt

// 更新 RTT 历史记录
rttHistory.add(rtt)
if (rttHistory.size > 60) {
rttHistory.removeAt(0)
}

// 计算 RTT 的最大、最小和平均值
val maxRtt = rttHistory.maxOrNull() ?: 0L
val minRtt = rttHistory.minOrNull() ?: 0L
val averageRtt = if (rttHistory.isNotEmpty()) {
rttHistory.average().toLong()
} else {
0L
}

// 更新 OWD 状态
owdState.longValue = owd

// 更新 OWD 历史记录
owdHistory.add(owd)
if (owdHistory.size > 60) {
owdHistory.removeAt(0)
}

// 计算 OWD 的最大、最小和平均值
val maxOwd = owdHistory.maxOrNull() ?: 0L
val minOwd = owdHistory.minOrNull() ?: 0L
val averageOwd = if (owdHistory.isNotEmpty()) {
owdHistory.average().toLong()
} else {
0L
}

Log.d(TAG, "RTT - 最新: $rtt ms, 最大: $maxRtt ms, 最小: $minRtt ms, 平均: $averageRtt ms")
Log.d(TAG, "单向时延 (OWD) - 最新: $owd ms, 最大: $maxOwd ms, 最小: $minOwd ms, 平均: $averageOwd ms")
}
} else {
Log.e(TAG, "计算出的OWD为负数，可能时钟同步有误。")
}
}

else -> {
Log.e(TAG, "Unknown signaling type: ${data.getString("type")}")
}
}
}

private fun requestTimeSync() {
val t1 = System.currentTimeMillis()
val syncRequest = JSONObject().apply {
put("type", "time_sync_request")
put("room", currentRoom)
put("t1", t1)
}
socket.emit("signal", syncRequest)
Log.d(TAG, "Sent time sync request at t1: $t1")
}

override fun onDestroyView() {
super.onDestroyView()
statsJob?.cancel()
socket.disconnect()
localPeer?.dispose()
localView?.release()
localEglBase?.release()
}
}

class VideoReceiverFragment : Fragment() {

companion object {
fun newInstance(
room: String,
stunUrl: String,
turnUrl: String,
turnUsername: String,
turnPassword: String,
signalingServerUrl: String
): VideoReceiverFragment {
val fragment = VideoReceiverFragment()
val args = Bundle().apply {
putString("room", room)
putString("stunUrl", stunUrl)
putString("turnUrl", turnUrl)
putString("turnUsername", turnUsername)
putString("turnPassword", turnPassword)
putString("signalingServerUrl", signalingServerUrl)
}
fragment.arguments = args
return fragment
}
}

private lateinit var socket: Socket
private var localPeer: PeerConnection? = null
private var remoteView: SurfaceViewRenderer? = null
private var remoteEglBase: EglBase? = null
private val pendingIceCandidates = mutableListOf<IceCandidate>()
private var currentRoom: String? = null
private lateinit var signalingServerUrl: String
private lateinit var stunUrl: String
private lateinit var turnUrl: String
private lateinit var turnUsername: String
private lateinit var turnPassword: String
private val TAG: String = "WebRTC-Receiver"

private val frameRateState = mutableDoubleStateOf(0.0)
private val bitrateState = mutableLongStateOf(0L)
private val stutteringState = mutableStateOf(false)

private val frameRateLowState = mutableStateOf(false)
private val packetLossHighState = mutableStateOf(false)
private val packetLossState = mutableDoubleStateOf(0.0)

private val frameRateHistory = mutableStateListOf<Float>()
private val bitrateHistory = mutableStateListOf<Long>()
private var timeSyncJob: Job? = null

private var prevFramesDecoded = 0.0
private var prevBytesReceived = 0.0
private var prevFramesReceived = 0.0
private var prevFramesDropped = 0.0
private var prevTimestamp = 0.0

private var statsJob: Job? = null

override fun onCreate(savedInstanceState: Bundle?) {
super.onCreate(savedInstanceState)

// Retrieve data from arguments
currentRoom = arguments?.getString("room") ?: "default-room"
signalingServerUrl = arguments?.getString("signalingServerUrl") ?: "https://wstszx.us.kg"
stunUrl = arguments?.getString("stunUrl") ?: "stun:stun.wstszx.us.kg:3478"
turnUrl = arguments?.getString("turnUrl") ?: "turn:turn.wstszx.us.kg:5349"
turnUsername = arguments?.getString("turnUsername") ?: "wstszx"
turnPassword = arguments?.getString("turnPassword") ?: "930379"

Log.d(
TAG,
"onCreate: Role = Client, Room = $currentRoom, Signaling Server = $signalingServerUrl, STUN URL = $stunUrl, TURN URL = $turnUrl"
)
}

private val requestPermissionsLauncher =
registerForActivityResult(ActivityResultContracts.RequestMultiplePermissions()) { permissions ->
permissions.entries.forEach { (permission, isGranted) ->
if (isGranted) {
Toast.makeText(requireContext(), "$permission 权限已授予", Toast.LENGTH_SHORT).show()
} else {
Toast.makeText(requireContext(), "$permission 权限被拒绝", Toast.LENGTH_SHORT).show()
}
}
onPermissionsChecked()
}

override fun onCreateView(
inflater: android.view.LayoutInflater,
container: android.view.ViewGroup?,
savedInstanceState: Bundle?
): android.view.View {
return ComposeView(requireContext()).apply {
setContent {
WebRTCComposeLayout()
}
}
}

@Composable
fun WebRTCComposeLayout() {
val context = LocalContext.current
lateinit var peerConnectionFactory: PeerConnectionFactory

Surface(color = Color.Black) {
Column(modifier = Modifier.fillMaxSize()) {

// Remote video view
AndroidView(
factory = {
remoteView = SurfaceViewRenderer(it).apply {
setZOrderMediaOverlay(false)
}
remoteView!!
},
modifier = Modifier
.weight(1f)
.fillMaxWidth(),
update = {
if (remoteEglBase?.eglBaseContext == null) {
remoteEglBase = EglBase.create()
it.init(remoteEglBase!!.eglBaseContext, null)
it.setMirror(false)
}
}
)

Spacer(modifier = Modifier.height(8.dp))

Column(
modifier = Modifier
.fillMaxWidth()
.padding(horizontal = 8.dp)
) {
// Frame Rate Text in Chinese
Text(
text = "帧率: ${frameRateState.doubleValue.roundToInt()} fps",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 4.dp)
)
Log.d(
TAG,
"UI - Frame Rate: ${frameRateState.doubleValue} fps, Bitrate: ${bitrateState.longValue / 1000} kbps"
)

// Line Chart for Frame Rate
LineChart(
data = frameRateHistory,
modifier = Modifier
.height(200.dp)
.fillMaxWidth()
.padding(vertical = 8.dp),
lineColor = Color.Green,
backgroundColor = Color.Black,
yAxisLabel = "帧率 (fps)",
xAxisLabel = "时间 (秒)"
)
}

// Spacer between charts
Spacer(modifier = Modifier.height(8.dp))

// Bitrate Section
Column(
modifier = Modifier
.fillMaxWidth()
.padding(horizontal = 16.dp)
) {
// Bitrate Text in Chinese
Text(
text = "码率: ${bitrateState.longValue / 1000} kbps",
color = Color.White,
style = MaterialTheme.typography.bodyMedium,
modifier = Modifier.padding(bottom = 4.dp)
)

// Line Chart for Bitrate
LineChart(
data = bitrateHistory.map { it / 1000f },
modifier = Modifier
.height(200.dp)
.fillMaxWidth()
.padding(vertical = 8.dp),
lineColor = Color.Blue,
backgroundColor = Color.Black,
yAxisLabel = "码率 (kbps)",
xAxisLabel = "时间 (秒)"
)
}

// Spacer between metrics and stuttering indicator
Spacer(modifier = Modifier.height(16.dp))

// Stuttering Indicator
Row(
modifier = Modifier
.fillMaxWidth()
.padding(horizontal = 16.dp),
verticalAlignment = Alignment.CenterVertically
) {
if (stutteringState.value) {
Icon(
imageVector = Icons.Default.Warning,
contentDescription = "卡顿警告",
tint = Color.Red,
modifier = Modifier.size(24.dp)
)
Spacer(modifier = Modifier.width(8.dp))
Column {
Text(
text = "视频播放出现卡顿",
color = Color.Red,
style = MaterialTheme.typography.bodyMedium
)
// Additional information about which metrics are abnormal
if (frameRateLowState.value) {
Text(
text = "帧率过低: ${frameRateState.doubleValue.roundToInt()} fps",
color = Color.Red,
style = MaterialTheme.typography.bodySmall
)
}
if (packetLossHighState.value) {
Text(
text = "包丢失率过高: ${packetLossState.doubleValue.roundToInt()}%",
color = Color.Red,
style = MaterialTheme.typography.bodySmall
)
}
}
} else {
Icon(
imageVector = Icons.Default.CheckCircle,
contentDescription = "正常",
tint = Color.Green,
modifier = Modifier.size(24.dp)
)
Spacer(modifier = Modifier.width(8.dp))
Text(
text = "视频播放正常",
color = Color.Green,
style = MaterialTheme.typography.bodyMedium
)
}
}
}

LaunchedEffect(Unit) {
val options = PeerConnectionFactory.InitializationOptions.builder(context)
.createInitializationOptions()
PeerConnectionFactory.initialize(options)

val encoderFactory = DefaultVideoEncoderFactory(
EglBase.create().eglBaseContext, true, true
)

val decoderFactory = DefaultVideoDecoderFactory(remoteEglBase!!.eglBaseContext)

peerConnectionFactory = PeerConnectionFactory.builder()
.setVideoEncoderFactory(encoderFactory)
.setVideoDecoderFactory(decoderFactory)
.createPeerConnectionFactory()

createPeerConnection(
context,
peerConnectionFactory,
remoteView!!
) {
localPeer = it
}

initializeSocketIO()

requestPermissionsIfNeeded()
}
}
}

/**
* Enhanced Line Chart Composable with Axes and Labels
* Modified to use straight lines connecting each point
*/
@Composable
fun LineChart(
data: List<Float>,
modifier: Modifier = Modifier,
lineColor: Color = Color.Green,
backgroundColor: Color = Color.Black,
yAxisLabel: String = "",
xAxisLabel: String = "",
minYValue: Float? = null,
maxYValue: Float? = null
) {
Canvas(modifier = modifier.background(backgroundColor)) {
val padding = 40.dp.toPx() // Padding for axes and labels

if (data.isEmpty()) return@Canvas

val maxY = maxYValue ?: data.maxOrNull() ?: 1f
val minY = minYValue ?: data.minOrNull() ?: 0f
val yRange = maxY - minY
val pointCount = data.size
val spacing = (size.width - padding * 2) / (pointCount - 1).coerceAtLeast(1)

val points = data.mapIndexed { index, value ->
val x = padding + index * spacing
val y = if (yRange == 0f) size.height / 2 else (size.height - padding) - ((value - minY) / yRange) * (size.height - padding * 2)
Offset(x, y)
}

// Draw axes
drawLine(
color = Color.White,
start = Offset(padding, padding),
end = Offset(padding, size.height - padding),
strokeWidth = 2f
)
drawLine(
color = Color.White,
start = Offset(padding, size.height - padding),
end = Offset(size.width - padding, size.height - padding),
strokeWidth = 2f
)

// Draw y-axis labels
val yLabelCount = 5
val yStep = yRange / (yLabelCount - 1)
for (i in 0 until yLabelCount) {
val yValue = minY + i * yStep
val yPos = (size.height - padding) - ((yValue - minY) / yRange) * (size.height - padding * 2)

drawContext.canvas.nativeCanvas.apply {
val label = yValue.roundToInt().toString()
val textPaint = android.graphics.Paint().apply {
color = android.graphics.Color.WHITE
textSize = 24f
textAlign = android.graphics.Paint.Align.RIGHT
}
drawText(
label,
padding - 8f,
yPos + textPaint.textSize / 2,
textPaint
)
}
}

// Draw x-axis labels
val xLabelCount = 5
val xStep = (pointCount - 1).coerceAtLeast(1) / (xLabelCount - 1).coerceAtLeast(1)
for (i in 0 until xLabelCount) {
val index = i * xStep
val xPos = padding + index * spacing

drawContext.canvas.nativeCanvas.apply {
val label = index.toString()
val textPaint = android.graphics.Paint().apply {
color = android.graphics.Color.WHITE
textSize = 24f
textAlign = android.graphics.Paint.Align.CENTER
}
drawText(
label,
xPos,
size.height - padding + textPaint.textSize + 4f,
textPaint
)
}
}

// Optionally, draw axis labels
// Y-Axis Label
if (yAxisLabel.isNotEmpty()) {
drawContext.canvas.nativeCanvas.apply {
val textPaint = android.graphics.Paint().apply {
color = android.graphics.Color.WHITE
textSize = 24f
textAlign = android.graphics.Paint.Align.CENTER
isAntiAlias = true
}
// Rotate for vertical text
save()
rotate(-90f, padding / 2, size.height / 2)
drawText(
yAxisLabel,
padding / 2,
size.height / 2,
textPaint
)
restore()
}
}

// X-Axis Label
if (xAxisLabel.isNotEmpty()) {
drawContext.canvas.nativeCanvas.apply {
val textPaint = android.graphics.Paint().apply {
color = android.graphics.Color.WHITE
textSize = 24f
textAlign = android.graphics.Paint.Align.CENTER
isAntiAlias = true
}
drawText(
xAxisLabel,
size.width / 2,
size.height - padding / 2,
textPaint
)
}
}

// Draw the straight lines connecting points
if (points.size >= 2) {
for (i in 0 until points.size - 1) {
drawLine(
color = lineColor,
start = points[i],
end = points[i + 1],
strokeWidth = 4f,
cap = StrokeCap.Round
)
}
}

// Optionally, draw points
points.forEach { point ->
drawCircle(
color = lineColor,
radius = 4f,
center = point
)
}
}
}

private fun initializeSocketIO() {
val protocol = if (signalingServerUrl.startsWith("https")) "https" else "http"
val socketUrl = signalingServerUrl

val options = IO.Options().apply {
transports = arrayOf("websocket")
secure = protocol == "https"
path = "/socket.io/"
}

try {
socket = IO.socket(socketUrl, options)

socket.on(Socket.EVENT_CONNECT) {
Log.d(TAG, "Socket connected")
socket.emit("join", currentRoom)
Log.d(TAG, "Joined room: $currentRoom")
initiateCall()
}

socket.on(Socket.EVENT_CONNECT_ERROR) { args ->
if (args.isNotEmpty()) {
val error = args[0]
Log.e(TAG, "Socket connection error: $error")
}
}

socket.on(Socket.EVENT_DISCONNECT) { args ->
if (args.isNotEmpty()) {
val reason = args[0]
Log.d(TAG, "Socket disconnected: $reason")
}
}

socket.on("signal") { args ->
Log.d(TAG, "Received signaling: ${args[0]}")
if (args.isNotEmpty() && args[0] is JSONObject) {
val data = args[0] as JSONObject
handleSignalingData(data)
}
}

socket.connect()
Log.d(TAG, "Connecting to Socket: $socketUrl...")
} catch (e: Exception) {
Log.e(TAG, "Error connecting to Socket: ${e.message}")
}
}

private fun requestPermissionsIfNeeded() {
val permissions = arrayOf(
Manifest.permission.CAMERA,
Manifest.permission.RECORD_AUDIO,
Manifest.permission.INTERNET,
Manifest.permission.ACCESS_NETWORK_STATE
)

val permissionsToRequest = permissions.filter {
ContextCompat.checkSelfPermission(requireContext(), it) != PackageManager.PERMISSION_GRANTED
}

if (permissionsToRequest.isNotEmpty()) {
requestPermissionsLauncher.launch(permissionsToRequest.toTypedArray())
} else {
onPermissionsChecked()
}
}

private fun onPermissionsChecked() {
Toast.makeText(requireContext(), "所有必要的权限已授予", Toast.LENGTH_SHORT).show()
}

private fun createPeerConnection(
context: Context,
peerConnectionFactory: PeerConnectionFactory,
remoteView: SurfaceViewRenderer,
onLocalPeerCreated: (PeerConnection) -> Unit
) {
val iceServers = listOf(
PeerConnection.IceServer.builder(stunUrl).createIceServer(),
PeerConnection.IceServer.builder(turnUrl)
.setUsername(turnUsername)
.setPassword(turnPassword)
.createIceServer()
)

val rtcConfig = PeerConnection.RTCConfiguration(iceServers).apply {
bundlePolicy = PeerConnection.BundlePolicy.MAXBUNDLE
rtcpMuxPolicy = PeerConnection.RtcpMuxPolicy.REQUIRE
tcpCandidatePolicy = PeerConnection.TcpCandidatePolicy.ENABLED
continualGatheringPolicy = PeerConnection.ContinualGatheringPolicy.GATHER_CONTINUALLY
sdpSemantics = PeerConnection.SdpSemantics.UNIFIED_PLAN
}

localPeer = peerConnectionFactory.createPeerConnection(rtcConfig, object : PeerConnection.Observer {
override fun onIceCandidate(iceCandidate: IceCandidate?) {
iceCandidate?.let {
Log.d(TAG, "ICE candidate: $it")
val signalData = JSONObject().apply {
put("type", "ice")
put("candidate", JSONObject().apply {
put("sdpMid", it.sdpMid)
put("sdpMLineIndex", it.sdpMLineIndex)
put("candidate", it.sdp)
})
put("room", currentRoom)
}
socket.emit("signal", signalData)
}
}

override fun onIceCandidatesRemoved(candidates: Array<out IceCandidate>?) {
Log.d(TAG, "ICE candidates removed")
}

override fun onSignalingChange(newState: PeerConnection.SignalingState?) {
Log.d(TAG, "Signaling state changed to: $newState")
}

override fun onIceConnectionChange(newState: PeerConnection.IceConnectionState?) {
Log.d(TAG, "ICE connection state changed to: $newState")
}

override fun onIceConnectionReceivingChange(receiving: Boolean) {
Log.d(TAG, "ICE connection receiving change: $receiving")
}

override fun onIceGatheringChange(newState: PeerConnection.IceGatheringState?) {
Log.d(TAG, "ICE gathering state changed to: $newState")
}

override fun onAddStream(stream: MediaStream?) {
Log.d(TAG, "Stream added")
}

override fun onRemoveStream(stream: MediaStream?) {
Log.d(TAG, "Stream removed")
}

override fun onDataChannel(dataChannel: DataChannel?) {
Log.d(TAG, "Data channel created")
}

override fun onRenegotiationNeeded() {
Log.d(TAG, "Renegotiation needed")
}

override fun onAddTrack(receiver: RtpReceiver?, streams: Array<out MediaStream>?) {
Log.d(TAG, "Track added")
receiver?.track()?.let { track ->
if (track is VideoTrack) {
track.addSink(remoteView)
}
}
}

override fun onTrack(transceiver: RtpTransceiver?) {
Log.d(TAG, "onTrack called")
transceiver?.receiver?.track()?.let { track ->
if (track is VideoTrack) {
track.addSink(remoteView)
}
}
}

override fun onConnectionChange(newState: PeerConnection.PeerConnectionState?) {
Log.d(TAG, "Connection state changed to: $newState")
}
})

onLocalPeerCreated(localPeer!!)

startStatsCollection()
}

private fun initiateCall() {
Log.d(TAG, "Initiating call...")
val constraints = MediaConstraints().apply {
mandatory.add(MediaConstraints.KeyValuePair("OfferToReceiveAudio", "true"))
mandatory.add(MediaConstraints.KeyValuePair("OfferToReceiveVideo", "true"))
}

localPeer?.createOffer(object : SdpObserver {
override fun onCreateSuccess(sessionDescription: SessionDescription?) {
sessionDescription?.let { sdp ->
localPeer?.setLocalDescription(object : SdpObserver {
override fun onSetSuccess() {
val signalData = JSONObject().apply {
put("type", "offer")
put("sdp", JSONObject().put("sdp", sdp.description))
put("room", currentRoom)
}
socket.emit("signal", signalData)
}

override fun onSetFailure(error: String?) {
Log.e(TAG, "Set local description error: $error")
}

override fun onCreateSuccess(p0: SessionDescription?) {}
override fun onCreateFailure(p0: String?) {}
}, sdp)
}
}

override fun onSetSuccess() {}
override fun onCreateFailure(error: String?) {
Log.e(TAG, "Create offer error: $error")
}

override fun onSetFailure(error: String?) {}
}, constraints)
}

private fun handleSignalingData(data: JSONObject) {
Log.d(TAG, "Handling signaling data: $data")
when (data.getString("type")) {

"answer" -> {
Log.d(TAG, "Received answer")
val sdp = SessionDescription(
SessionDescription.Type.ANSWER,
data.getJSONObject("sdp").getString("sdp")
)

localPeer?.setRemoteDescription(object : SdpObserver {
override fun onSetSuccess() {
pendingIceCandidates.forEach { candidate ->
localPeer?.addIceCandidate(candidate)
}

pendingIceCandidates.clear()

Log.d(TAG, "Set remote description (answer) success")
}

override fun onSetFailure(error: String?) {
Log.e(TAG, "Set remote description error: $error")
}

override fun onCreateSuccess(p0: SessionDescription?) {}
override fun onCreateFailure(p0: String?) {}
}, sdp)
}

"ice" -> {
Log.d(TAG, "Received ICE candidate")
val candidateData = data.getJSONObject("candidate")
val candidate = IceCandidate(
candidateData.getString("sdpMid"),
candidateData.getInt("sdpMLineIndex"),
candidateData.getString("candidate")
)

if (localPeer?.remoteDescription != null) {
localPeer?.addIceCandidate(candidate)
} else {
pendingIceCandidates.add(candidate)
}
}

"time_sync_request" -> {
val t1 = data.getLong("t1")
val t2 = System.currentTimeMillis()
val t3 = System.currentTimeMillis()
val syncResponse = JSONObject().apply {
put("type", "time_sync_response")
put("t1", t1)
put("t2", t2)
put("t3", t3)
put("room", currentRoom)
}
socket.emit("signal", syncResponse)
Log.d(TAG, "回复 time_sync_request: t1=$t1, t2=$t2, t3=$t3")
}
else -> {
Log.e(TAG, "Unknown signaling type: ${data.getString("type")}")
}
}
}

private fun startStatsCollection() {
Log.d(TAG, "Starting stats collection...")
statsJob = viewLifecycleOwner.lifecycleScope.launch {
while (isActive) {
delay(1000) // Collect stats every second
Log.d(TAG, "Collecting stats...")
localPeer?.getStats { report ->
Log.d(TAG, "Stats report obtained.")
parseStatsReport(report)
} ?: Log.e(TAG, "Failed to get stats: localPeer is null.")
}
}
}

private fun parseStatsReport(report: RTCStatsReport) {
Log.d(TAG, "Received RTCStatsReport: $report")
for (stats in report.statsMap.values) {
if (stats.type == "inbound-rtp") {
val kind = stats.members["kind"] as? String
if (kind == "video") {
val framesDecoded = (stats.members["framesDecoded"] as? Number)?.toDouble() ?: 0.0
val framesReceived = (stats.members["framesReceived"] as? Number)?.toDouble() ?: 0.0
val framesDropped = (stats.members["framesDropped"] as? Number)?.toDouble() ?: 0.0
val bytesReceived = (stats.members["bytesReceived"] as? Number)?.toDouble() ?: 0.0
val packetsLost = (stats.members["packetsLost"] as? Number)?.toDouble() ?: 0.0
val packetsReceived = (stats.members["packetsReceived"] as? Number)?.toDouble() ?: 1.0 // Avoid division by zero
val packetLossFraction = packetsLost / (packetsLost + packetsReceived)
val timestamp = stats.timestampUs / 1_000_000.0 // Convert to seconds

Log.d(
TAG,
"Stats - Frames Decoded: $framesDecoded, Frames Received: $framesReceived, Frames Dropped: $framesDropped, Bytes Received: $bytesReceived, Packet Loss Fraction: $packetLossFraction, Timestamp: $timestamp"
)

if (prevTimestamp != 0.0) {
val timeElapsed = timestamp - prevTimestamp
val framesDelta = framesDecoded - prevFramesDecoded
val bytesDelta = bytesReceived - prevBytesReceived
val framesReceivedDelta = framesReceived - prevFramesReceived
val framesDroppedDelta = framesDropped - prevFramesDropped

val frameRate = if (timeElapsed > 0) framesDelta / timeElapsed else 0.0
val bitrate = if (timeElapsed > 0) (bytesDelta * 8) / timeElapsed else 0.0 // bits per second
val packetLoss = packetLossFraction * 100 // Convert to percentage

Log.d(TAG, "Calculated Frame Rate: $frameRate fps, Bitrate: $bitrate bps, Packet Loss: $packetLoss%")

// Determine stuttering based on thresholds
val isStuttering = frameRate < 24 || packetLoss > 5.0 // Thresholds can be adjusted

// Update states
viewLifecycleOwner.lifecycleScope.launch {
frameRateState.doubleValue = frameRate
bitrateState.longValue = bitrate.toLong()
// Update stuttering state
stutteringState.value = isStuttering
// Update specific stuttering causes
frameRateLowState.value = frameRate < 24
packetLossHighState.value = packetLoss > 5.0
packetLossState.doubleValue = packetLoss

// Update history
frameRateHistory.add(frameRate.toFloat())
if (frameRateHistory.size > 60) {
frameRateHistory.removeAt(0)
}

bitrateHistory.add(bitrate.toLong())
if (bitrateHistory.size > 60) {
bitrateHistory.removeAt(0)
}

Log.d(
TAG,
"Updated Frame Rate: ${frameRateState.doubleValue} fps, Bitrate: ${bitrateState.longValue / 1000} kbps, Stuttering: $isStuttering"
)
}
}

// Update previous values
prevFramesDecoded = framesDecoded
prevBytesReceived = bytesReceived
prevFramesReceived = framesReceived
prevFramesDropped = framesDropped
prevTimestamp = timestamp
}
}
}
}

override fun onDestroyView() {
super.onDestroyView()
statsJob?.cancel()
socket.disconnect()
localPeer?.dispose()
remoteView?.release()
remoteEglBase?.release()
timeSyncJob?.cancel()
}
}

目前的时延计算方式并不合理？因为t3和t2的差值为0，这不是真实环境中会发生的，因为webrtc通过中转的方式进行视频通信的时候，不可能为0，是否有更合理的方式来计算时延，用中文回答

Suy nghĩ

审查时延计算

正在分析 VideoInitiatorFragment 的代码，观察 t3 和 t2 的差异变为零，怀疑时延计算有误。

处理时间同步请求

在VideoInitiatorFragment中，首次发送时间同步请求时记录t1。接收到请求后，VideoReceiverFragment计算t1、t2和t3，发送time_sync_response。

探讨时间同步

我在探讨普通的NTP-like时钟同步时， t1、t2、t3、t4分别代表客户端请求发送时间、服务器接收请求时间、服务器发送响应时间和客户端接收响应时间。

寻找低延迟解决方案

我在探讨不同的延迟测量方法，包括使用WebRTC统计数据、实施ping-pong机制、嵌入媒体帧时间戳，以及利用现有信号服务器的时间同步请求。

考虑数据传输

代码的计算方法不起作用，因为 t3 - t2 为零。这是因为 RTT 是从 t1 到 t4 的时间差，OWD 是 RTT / 2。理论上，这可以减少计算错误。

反思计算方法

我在思考如何改进时钟偏移的计算方法，以确保t3和t2之间有足够的时间差。这样，数据传输的准确性会更好。

延迟计算

Trả lời

您当前的时延计算方式由于 t3 和 t2 之间的差值为零，导致计算结果不准确。这主要是因为在接收方处理时间同步请求时，t3 被立即设置为当前时间，与 t2 几乎同时，因此 t3 - t2 接近于零。这种情况下，无法准确反映实际的网络传输延迟和处理时间。

要更合理地计算时延，可以考虑以下几种改进方法：

1. 引入处理延迟

在接收方处理时间同步请求时，添加一定的延迟，以确保 t3 - t2 能反映实际的处理时间和网络延迟。这样可以避免 t3 - t2 过于接近于零。

"time_sync_request" -> {
    val t1 = data.getLong("t1")
    val t2 = System.currentTimeMillis()
    delay(100) // 添加100毫秒的延迟
    val t3 = System.currentTimeMillis()
    val syncResponse = JSONObject().apply {
        put("type", "time_sync_response")
        put("t1", t1)
        put("t2", t2)
        put("t3", t3)
        put("room", currentRoom)
    }
    socket.emit("signal", syncResponse)
    Log.d(TAG, "回复 time_sync_request: t1=$t1, t2=$t2, t3=$t3")
}

2. 多次测量取平均值

进行多次时间同步测量，取平均值以减少偶然误差的影响。这种方法可以提高时延计算的准确性。

private fun startTimeSync(intervalMs: Long = 5000L, attempts: Int = 5) {
    viewLifecycleOwner.lifecycleScope.launch {
        repeat(attempts) {
            delay(intervalMs)
            requestTimeSync()
        }
    }
}

private fun handleSignalingData(data: JSONObject) {
    // ... 现有代码 ...
    "time_sync_response" -> {
        // 现有处理逻辑
        // 可以在这里累积多次测量结果，并计算平均值
    }
    // ... 现有代码 ...
}

3. 利用 WebRTC 自带的统计信息

WebRTC 提供了 ICE 连接状态和往返时间（RTT）的统计信息，您可以直接利用这些信息来计算时延，而无需自行实现时间同步。

在 parseStatsReport 方法中，您已经获取了 currentRoundTripTime，可以直接使用它作为 RTT，并将单向时延（OWD）估算为 RTT 的一半。

private fun parseStatsReport(report: RTCStatsReport) {
    for (stats in report.statsMap.values) {
        if (stats.type == "transport") {
            val currentRtt = (stats.members["currentRoundTripTime"] as? Number)?.toDouble()?.times(1000)?.toLong()
            if (currentRtt != null && currentRtt > 0) {
                viewLifecycleOwner.lifecycleScope.launch {
                    rttState.longValue = currentRtt
                    owdState.longValue = currentRtt / 2
                    // 更新 RTT 和 OWD 历史记录
                }
            }
        }
    }
}

4. 利用数据通道进行 Ping-Pong 测试

如果您已经建立了数据通道，可以在数据通道上发送 Ping 消息，并测量从发送到接收的时间来计算 RTT。这种方法可以更准确地反映实际的网络延迟。

private fun setupDataChannel(peerConnection: PeerConnection) {
    val dataChannelInit = DataChannel.Init()
    val dataChannel = peerConnection.createDataChannel("ping-pong", dataChannelInit)
    
    dataChannel.registerObserver(object : DataChannel.Observer {
        override fun onMessage(buffer: DataChannel.Buffer) {
            // 接收到 Pong 响应，计算 RTT
            val t4 = System.currentTimeMillis()
            val rtt = t4 - sentTime
            viewLifecycleOwner.lifecycleScope.launch {
                rttState.longValue = rtt
                owdState.longValue = rtt / 2
                // 更新历史记录
            }
        }

        override fun onBufferedAmountChange(amount: Long) {}
        override fun onStateChange() {}
    })
}

private var sentTime: Long = 0

private fun sendPing(dataChannel: DataChannel) {
    sentTime = System.currentTimeMillis()
    val buffer = DataChannel.Buffer(ByteBuffer.wrap("ping".toByteArray()), false)
    dataChannel.send(buffer)
}

5. 结合多种方法

您还可以结合上述多种方法，进一步提高时延计算的准确性。例如，结合 WebRTC 的统计信息和数据通道的 Ping-Pong 测试，可以更全面地了解网络状况和时延。

总结

当前的时延计算方式由于 t3 - t2 接近于零，无法准确反映实际的网络延迟。通过引入处理延迟、进行多次测量取平均值、利用 WebRTC 自带的统计信息以及使用数据通道进行 Ping-Pong 测试，可以显著提高时延计算的准确性和可靠性。选择合适的方法或结合多种方法，将有助于您更合理地计算和监控时延。

Câu hỏi

我希望推荐给我最合理的方式来解决这个问题

Suy nghĩ

分析问题

用户提到目前延迟计算方式存在缺陷，特别是t2和t3差值为0的问题。呼吁寻找更合适的计算方法。

选择最佳方案
考虑WebRTC内建的RTT统计数据或数据通道进行更准确的测量，同时也可以使用类似NTP的多次测量。

Trả lời

针对您当前的时延计算问题，最合理且高效的解决方案是 利用 WebRTC 提供的内置统计信息（getStats）来获取往返时延（RTT）。这种方法不仅简便，而且能够提供准确的网络延迟数据，避免了手动时间同步可能带来的误差和复杂性。

推荐方案：使用 WebRTC 的 `getStats` 获取 RTT

1. 为什么选择 WebRTC 的 `getStats`？

准确性高：WebRTC 内部已经优化了统计信息的收集，能够提供精确的 RTT 数据。
实现简便：无需额外的时间同步机制或数据通道的 Ping-Pong 测试，减少了代码复杂性。
实时性好：getStats 可以定期调用，实时监控网络状况和时延变化。

2. 如何实现

您可以通过调用 PeerConnection 的 getStats 方法，解析 RTCStatsReport 中的 transport 类型的统计信息，获取 currentRoundTripTime（当前往返时延）。以下是具体的实现步骤：

步骤一：修改 `parseStatsReport` 方法

在 VideoInitiatorFragment 和 VideoReceiverFragment 中，确保在 parseStatsReport 方法中解析 transport 类型的统计信息，并提取 currentRoundTripTime。

private fun parseStatsReport(report: RTCStatsReport) {
    Log.d(TAG, "RTCStatsReport: ${report.statsMap}")
    for (stats in report.statsMap.values) {
        if (stats.type == "transport") {
            val currentRtt = (stats.members["currentRoundTripTime"] as? Number)?.toDouble()?.times(1000)?.toLong()
            if (currentRtt != null && currentRtt > 0) {
                viewLifecycleOwner.lifecycleScope.launch {
                    // 更新 RTT 状态
                    rttState.longValue = currentRtt

                    // 更新 RTT 历史记录
                    rttHistory.add(currentRtt)
                    if (rttHistory.size > 60) {
                        rttHistory.removeAt(0)
                    }

                    // 计算 RTT 的最大、最小和平均值
                    val maxRtt = rttHistory.maxOrNull() ?: 0L
                    val minRtt = rttHistory.minOrNull() ?: 0L
                    val averageRtt = if (rttHistory.isNotEmpty()) {
                        rttHistory.average().toLong()
                    } else {
                        0L
                    }

                    // 估算单向时延 OWD
                    owdState.longValue = averageRtt / 2

                    Log.d(TAG, "RTT - 最新: $currentRtt ms, 最大: $maxRtt ms, 最小: $minRtt ms, 平均: $averageRtt ms")
                    Log.d(TAG, "单向时延 (OWD) - 估算: ${owdState.longValue} ms")
                }
            }
        }
    }
}

步骤二：定期调用 `getStats`

确保在 startStatsCollection 方法中，定期调用 getStats 来获取最新的统计信息。

private fun startStatsCollection() {
    statsJob = viewLifecycleOwner.lifecycleScope.launch {
        while (isActive) {
            delay(1000) // 每秒收集一次统计信息
            localPeer?.getStats { report ->
                parseStatsReport(report)
            } ?: Log.e(TAG, "获取统计信息失败: localPeer 为 null")
        }
    }
}

步骤三：更新 UI 显示

在 Compose 布局中，您已经有相关的 UI 组件来显示 RTT 和 OWD。确保这些状态变量能够及时更新，以反映最新的网络状况。

Text(
    text = "往返时延 (RTT): ${rttState.longValue} ms",
    color = Color.White,
    style = MaterialTheme.typography.bodyMedium,
    modifier = Modifier.padding(bottom = 2.dp)
)

Text(
    text = "单向时延 (OWD): ${owdState.longValue} ms",
    color = Color.White,
    style = MaterialTheme.typography.bodyMedium
)

3. 优化建议

数据平滑处理：为了避免瞬时波动导致的数据显示不稳定，可以对 RTT 数据进行平滑处理，如移动平均。

val smoothedRtt = if (rttHistory.size >= 5) {
    rttHistory.takeLast(5).average().toLong()
} else {
    rttHistory.average().toLong()
}
rttState.longValue = smoothedRtt

异常检测：设置合理的阈值，检测 RTT 是否超出预期范围，以便及时响应网络问题。

if (smoothedRtt > 300) { // 例如，RTT 超过 300ms 视为高延迟
    // 执行相应的处理，如提示用户网络状况不佳
}

结合其他统计信息：除了 RTT，还可以结合带宽、丢包率等其他统计信息，全面评估网络状况。

4. 其他补充方法（可选）

虽然使用 WebRTC 的 getStats 是最直接和高效的方法，但您也可以结合其他方法进一步提升时延监控的准确性：

数据通道 Ping-Pong 测试：通过数据通道发送 Ping 消息，测量响应时间，作为 RTT 的补充。
多次测量取平均值：进行多次 RTT 测量，取平均值以减少偶然误差的影响。

不过，这些方法会增加实现的复杂性，通常在需要更高精度时才会采用。

总结

利用 WebRTC 提供的 getStats 方法获取 currentRoundTripTime 是解决您当前时延计算问题的最合理方案。它不仅实现简便，而且能够提供准确的 RTT 数据，帮助您有效监控和优化网络延迟。结合数据平滑处理和异常检测，您可以进一步提升时延监控的稳定性和可靠性。

Câu hỏi

Suy nghĩ

Trả lời

1. 引入处理延迟

2. 多次测量取平均值

3. 利用 WebRTC 自带的统计信息

4. 利用数据通道进行 Ping-Pong 测试

5. 结合多种方法

总结

Câu hỏi

Suy nghĩ

Trả lời

推荐方案：使用 WebRTC 的 getStats 获取 RTT

1. 为什么选择 WebRTC 的 getStats？

2. 如何实现

步骤一：修改 parseStatsReport 方法

步骤二：定期调用 getStats

步骤三：更新 UI 显示

3. 优化建议

4. 其他补充方法（可选）

总结

Chia sẻ Q&A này

推荐方案：使用 WebRTC 的 `getStats` 获取 RTT

1. 为什么选择 WebRTC 的 `getStats`？

步骤一：修改 `parseStatsReport` 方法

步骤二：定期调用 `getStats`