private void ProbeWorkers() { try { while (!m_exit) { try { SIPEndPoint activeWorkerEndPoint = GetFirstHealthyEndPoint(); SIPCallDescriptor callDescriptor = new SIPCallDescriptor(m_dispatcherUsername, null, "sip:" + m_dispatcherUsername + "@" + activeWorkerEndPoint.SocketEndPoint.ToString(), "sip:" + m_dispatcherUsername + "@sipcalldispatcher", "sip:" + activeWorkerEndPoint.SocketEndPoint.ToString(), null, null, null, SIPCallDirection.Out, null, null, null); SIPClientUserAgent uac = new SIPClientUserAgent(m_sipTransport, null, null, null, null); uac.CallAnswered += DispatcherCallAnswered; uac.CallFailed += new SIPCallFailedDelegate(DispatcherCallFailed); uac.Call(callDescriptor); } catch (Exception probeExcp) { dispatcherLogger.Error("Exception SIPCallDispatcher Sending Probe. " + probeExcp.Message); } Thread.Sleep(PROBE_WORKER_CALL_PERIOD); } } catch (Exception excp) { logger.Error("Exception SIPCallDispatcher ProberWorkers. " + excp.Message); } }
public void Start(string endpoint) { this.endpoint = endpoint; var caller = "1003"; var password = passwords[0]; var port = FreePort.FindNextAvailableUDPPort(15090); rtpChannel = new RTPChannel { DontTimeout = true, RemoteEndPoint = new IPEndPoint(IPAddress.Parse(asterisk), port) }; rtpChannel.SetFrameType(FrameTypesEnum.Audio); rtpChannel.ReservePorts(15000, 15090); rtpChannel.OnFrameReady += RtpChannel_OnFrameReady; uac = new SIPClientUserAgent(transport, null, null, null, null); var uri = SIPURI.ParseSIPURIRelaxed($"{ endpoint }@{ asterisk }"); var from = (new SIPFromHeader(caller, new SIPURI(caller, asterisk, null), null)).ToString(); var random = Crypto.GetRandomInt(5).ToString(); var sdp = new SDP { Version = 2, Username = "******", SessionId = random, Address = localIPEndPoint.Address.ToString(), SessionName = "redfox_" + random, Timing = "0 0", Connection = new SDPConnectionInformation(publicIPAddress.ToString()) }; var announcement = new SDPMediaAnnouncement { Media = SDPMediaTypesEnum.audio, MediaFormats = new List <SDPMediaFormat>() { new SDPMediaFormat((int)SDPMediaFormatsEnum.PCMU, "PCMU", 8000) }, Port = rtpChannel.RTPPort }; sdp.Media.Add(announcement); var descriptor = new SIPCallDescriptor(caller, password, uri.ToString(), from, null, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, sdp.ToString(), null); uac.CallTrying += Uac_CallTrying; uac.CallRinging += Uac_CallRinging; uac.CallAnswered += Uac_CallAnswered; uac.CallFailed += Uac_CallFailed; uac.Call(descriptor); }
public void CallWithAdjustedInviteHeaderTest() { logger.LogDebug("--> " + System.Reflection.MethodBase.GetCurrentMethod().Name); logger.BeginScope(System.Reflection.MethodBase.GetCurrentMethod().Name); SIPTransport transport = new SIPTransport(); MockSIPChannel channel = new MockSIPChannel(new System.Net.IPEndPoint(IPAddress.Any, 0)); transport.AddSIPChannel(channel); SIPClientUserAgent userAgent = new SIPClientUserAgent( transport, new SIPEndPoint(new IPEndPoint(new IPAddress(new byte[] { 192, 168, 11, 50 }), 5060)), "owner", "admin", null); SIPContactHeader testHeader = new SIPContactHeader("Contact Name", new SIPURI("User", "Host", "Param=Value")); userAgent.AdjustInvite = invite => { invite.Header.Contact = new List <SIPContactHeader> { testHeader }; return(invite); }; var desc = new SIPCallDescriptor( "user", "pass", "sip:user@host", "sip:user@host", "sip:destination@destinationhost", null, new List <string>(), "user", SIPCallDirection.Out, null, null, null); userAgent.Call(desc); channel.SIPMessageSent.WaitOne(5000); Assert.Contains(testHeader.ToString(), channel.LastSIPMessageSent); }
/// <summary> /// Places an outgoing SIP call. /// </summary> /// <param name="destination">The SIP URI to place a call to. The destination can be a full SIP URI in which case the all will /// be placed anonymously directly to that URI. Alternatively it can be just the user portion of a URI in which case it will /// be sent to the configured SIP server.</param> public void Call(MediaManager mediaManager, string destination) { //_initialisationTask.Wait(_cancelCallTokenSource.Token); _mediaManager = mediaManager; _mediaManager.NewCall(); // Determine if this is a direct anonymous call or whether it should be placed using the pre-configured SIP server account. SIPURI callURI = null; string sipUsername = null; string sipPassword = null; string fromHeader = null; if (destination.Contains("@") || m_sipServer == null) { // Anonymous call direct to SIP server specified in the URI. callURI = SIPURI.ParseSIPURIRelaxed(destination); fromHeader = (new SIPFromHeader(m_sipFromName, SIPURI.ParseSIPURI(SIPFromHeader.DEFAULT_FROM_URI), null)).ToString(); } else { // This call will use the pre-configured SIP account. callURI = SIPURI.ParseSIPURIRelaxed(destination + "@" + m_sipServer); sipUsername = m_sipUsername; sipPassword = m_sipPassword; fromHeader = (new SIPFromHeader(m_sipFromName, new SIPURI(m_sipUsername, m_sipServer, null), null)).ToString(); } StatusMessage("Starting call to " + callURI.ToString() + "."); m_uac = new SIPClientUserAgent(m_sipTransport, null, null, null, null); m_uac.CallTrying += CallTrying; m_uac.CallRinging += CallRinging; m_uac.CallAnswered += CallAnswered; m_uac.CallFailed += CallFailed; // Get the SDP requesting that the public IP address be used if the host on the call destination is not a private IP address. SDP sdp = _mediaManager.GetSDP(!(IPAddress.TryParse(callURI.Host, out _) && IPSocket.IsPrivateAddress(callURI.Host))); System.Diagnostics.Debug.WriteLine(sdp.ToString()); SIPCallDescriptor callDescriptor = new SIPCallDescriptor(sipUsername, sipPassword, callURI.ToString(), fromHeader, null, null, null, null, SIPCallDirection.Out, _sdpMimeContentType, sdp.ToString(), null); m_uac.Call(callDescriptor); }
/// <summary> /// Sends the SIP INVITE probe request. /// </summary> private void ProbeWorker(SIPAppServerWorker worker, bool isInitialProbe) { try { if (isInitialProbe) { worker.InitialProbeCount++; } int workerProcessID = worker.WorkerProcess.Id; SIPEndPoint workerEndPoint = worker.AppServerEndpoint; DateTime probeSentAt = DateTime.Now; SIPCallDescriptor callDescriptor = new SIPCallDescriptor(m_dispatcherUsername, null, "sip:" + m_dispatcherUsername + "@" + workerEndPoint.GetIPEndPoint().ToString(), "sip:" + m_dispatcherUsername + "@sipcalldispatcher", "sip:" + workerEndPoint.GetIPEndPoint().ToString(), null, null, null, SIPCallDirection.Out, null, null, null); SIPClientUserAgent uac = new SIPClientUserAgent(m_sipTransport, null, null, null, null); uac.CallFailed += (failedUAC, errorMessage) => { AppServerCallFailed(failedUAC, errorMessage, workerProcessID, probeSentAt, isInitialProbe); }; uac.CallAnswered += (call, sipResponse) => { if (sipResponse.Status != SIPResponseStatusCodesEnum.BadExtension) { //logger.Warn("Probe call answered with unexpected response code of " + sipResponse.StatusCode + "."); AppServerCallFailed(call, "Unexpected response of " + ((int)sipResponse.StatusCode) + " on probe call.", workerProcessID, probeSentAt, isInitialProbe); } else { AppServerCallSucceeded(call); } }; uac.Call(callDescriptor); } catch (Exception excp) { logger.Error("Exception SIPAppServerManager ProberWorker. " + excp.Message); } }
/// <summary> /// Places an outgoing SIP call. /// </summary> /// <param name="destination">The SIP URI to place a call to. The destination can be a full SIP URI in which case the all will /// be placed anonymously directly to that URI. Alternatively it can be just the user portion of a URI in which case it will /// be sent to the configured SIP server.</param> public void Call(string destination) { // Determine if this is a direct anonymous call or whether it should be placed using the pre-configured SIP server account. SIPURI callURI = null; string sipUsername = null; string sipPassword = null; string fromHeader = null; if (destination.Contains("@") || m_sipServer == null) { // Anonymous call direct to SIP server specified in the URI. callURI = SIPURI.ParseSIPURIRelaxed(destination); } else { // This call will use the pre-configured SIP account. callURI = SIPURI.ParseSIPURIRelaxed(destination + "@" + m_sipServer); sipUsername = m_sipUsername; sipPassword = m_sipPassword; fromHeader = (new SIPFromHeader(m_sipFromName, new SIPURI(m_sipUsername, m_sipServer, null), null)).ToString(); } StatusMessage("Starting call to " + callURI.ToString() + "."); m_uac = new SIPClientUserAgent(m_sipTransport, null, null, null, null); m_uac.CallTrying += CallTrying; m_uac.CallRinging += CallRinging; m_uac.CallAnswered += CallAnswered; m_uac.CallFailed += CallFailed; _audioChannel = new AudioChannel(); // Get the SDP requesting that the public IP address be used if the host on the call destination is not a private IP address. SDP sdp = _audioChannel.GetSDP(!(IPSocket.IsIPAddress(callURI.Host) && IPSocket.IsPrivateAddress(callURI.Host))); SIPCallDescriptor callDescriptor = new SIPCallDescriptor(sipUsername, sipPassword, callURI.ToString(), fromHeader, null, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, sdp.ToString(), null); m_uac.Call(callDescriptor); }
static void Main(string[] args) { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. ManualResetEvent exitMre = new ManualResetEvent(false); bool isCallHungup = false; bool hasCallFailed = false; Log = AddConsoleLogger(); SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); if (args != null && args.Length > 0) { if (!SIPURI.TryParse(args[0], out callUri)) { Log.LogWarning($"Command line argument could not be parsed as a SIP URI {args[0]}"); } } Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); EnableTraceLogs(sipTransport); var audioSession = new WindowsAudioEndPoint(new AudioEncoder()); var rtpSession = new VoIPMediaSession(audioSession.ToMediaEndPoints()); var offerSDP = rtpSession.CreateOffer(null); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallRinging += async(uac, resp) => { Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); if (resp.Status == SIPResponseStatusCodesEnum.SessionProgress) { await rtpSession.Start(); } }; uac.CallFailed += (uac, err, resp) => { Log.LogWarning($"Call attempt to {uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += async(iuac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); var result = rtpSession.SetRemoteDescription(SdpType.answer, SDP.ParseSDPDescription(resp.Body)); if (result == SetDescriptionResultEnum.OK) { await rtpSession.Start(); } else { Log.LogWarning($"Failed to set remote description {result}."); uac.Hangup(); } } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += async(SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPResponse okResponse = SIPResponse.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); await sipTransport.SendResponseAsync(okResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; exitMre.Set(); } } }; // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, callUri.ToString(), SIPConstants.SIP_DEFAULT_FROMURI, callUri.CanonicalAddress, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, offerSDP.ToString(), null); uac.Call(callDescriptor, null); uac.ServerTransaction.TransactionTraceMessage += (tx, msg) => Log.LogInformation($"UAC tx trace message. {msg}"); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; exitMre.Set(); }; // Wait for a signal saying the call failed, was cancelled with ctrl-c or completed. exitMre.WaitOne(); Log.LogInformation("Exiting..."); rtpSession.Close(null); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }
static void Main() { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. CancellationTokenSource rtpCts = new CancellationTokenSource(); // Cancellation token to stop the RTP stream. bool isCallHungup = false; bool hasCallFailed = false; AddConsoleLogger(); SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); sipTransport.AddSIPChannel(new SIPUDPChannel(new IPEndPoint(IPAddress.Any, 0))); // Un/comment this line to see/hide each SIP message sent and received. EnableTraceLogs(sipTransport); // Note this relies on the callURI host being an IP address. If it's a hostname a DNS lookup is required. IPAddress localIPAddress = NetServices.GetLocalAddressForRemote(callUri.ToSIPEndPoint().Address); // Initialise an RTP session to receive the RTP packets from the remote SIP server. var rtpSession = new RTPSession((int)SDPMediaFormatsEnum.PCMU, null, null, true, localIPAddress.AddressFamily); var offerSDP = rtpSession.GetSDP(localIPAddress); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => { Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); }; uac.CallRinging += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { Log.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); rtpSession.DestinationEndPoint = SDP.GetSDPRTPEndPoint(resp.Body); Log.LogDebug($"Remote RTP socket {rtpSession.DestinationEndPoint}."); } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += async(SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPResponse okResponse = SIPResponse.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); await sipTransport.SendResponseAsync(okResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; rtpCts.Cancel(); } } }; // Wire up the RTP receive session to the default speaker. var(audioOutEvent, audioOutProvider) = GetAudioOutputDevice(); rtpSession.OnReceivedSampleReady += (sample) => { for (int index = 0; index < sample.Length; index++) { short pcm = NAudio.Codecs.MuLawDecoder.MuLawToLinearSample(sample[index]); byte[] pcmSample = new byte[] { (byte)(pcm & 0xFF), (byte)(pcm >> 8) }; audioOutProvider.AddSamples(pcmSample, 0, 2); } }; // Send audio packets (in this case silence) to the callee. Task.Run(() => SendSilence(rtpSession, rtpCts)); // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, callUri.ToString(), SIPConstants.SIP_DEFAULT_FROMURI, null, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, offerSDP.ToString(), null); uac.Call(callDescriptor); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; rtpCts.Cancel(); }; // Give the call some time to answer. Task.Delay(3000).Wait(); // Send some DTMF key presses via RTP events. var dtmf5 = new RTPEvent(0x05, false, RTPEvent.DEFAULT_VOLUME, 1200, RTPSession.DTMF_EVENT_PAYLOAD_ID); rtpSession.SendDtmfEvent(dtmf5, rtpCts.Token).Wait(); Task.Delay(2000, rtpCts.Token).Wait(); var dtmf9 = new RTPEvent(0x09, false, RTPEvent.DEFAULT_VOLUME, 1200, RTPSession.DTMF_EVENT_PAYLOAD_ID); rtpSession.SendDtmfEvent(dtmf9, rtpCts.Token).Wait(); Task.Delay(2000, rtpCts.Token).Wait(); var dtmf2 = new RTPEvent(0x02, false, RTPEvent.DEFAULT_VOLUME, 1200, RTPSession.DTMF_EVENT_PAYLOAD_ID); rtpSession.SendDtmfEvent(dtmf2, rtpCts.Token).Wait(); Task.Delay(2000, rtpCts.Token).ContinueWith((task) => { }).Wait(); // Don't care about the exception if the cancellation token is set. Log.LogInformation("Exiting..."); rtpCts.Cancel(); audioOutEvent?.Stop(); rtpSession.CloseSession(null); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }
static void Main() { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. CancellationTokenSource rtpCts = new CancellationTokenSource(); // Cancellation token to stop the RTP stream. bool isCallHungup = false; bool hasCallFailed = false; AddConsoleLogger(); SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); int port = SIPConstants.DEFAULT_SIP_PORT + 1000; sipTransport.AddSIPChannel(new SIPUDPChannel(new IPEndPoint(IPAddress.Any, port))); // Uncomment this line to see each SIP message sent and received. EnableTraceLogs(sipTransport); // Send an OPTIONS request to determine the local IP address to use for the RTP socket. var optionsTask = SendOptionsTaskAsync(sipTransport, callUri); var result = Task.WhenAny(optionsTask, Task.Delay(SIP_REQUEST_TIMEOUT_MILLISECONDS)); result.Wait(); if (optionsTask.IsCompletedSuccessfully == false || optionsTask.Result == null) { Log.LogError($"OPTIONS request to {callUri} failed."); } else { IPAddress localIPAddress = optionsTask.Result; // Initialise an RTP session to receive the RTP packets from the remote SIP server. Socket rtpSocket = null; Socket controlSocket = null; NetServices.CreateRtpSocket(localIPAddress, 49000, 49100, false, out rtpSocket, out controlSocket); var rtpRecvSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); var rtpSendSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => { Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); Log.LogDebug(resp.ToString()); }; uac.CallRinging += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { Log.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); _remoteRtpEndPoint = SDP.GetSDPRTPEndPoint(resp.Body); Log.LogDebug($"Remote RTP socket {_remoteRtpEndPoint}."); } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += (SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPNonInviteTransaction byeTransaction = sipTransport.CreateNonInviteTransaction(sipRequest, remoteEndPoint, localSIPEndPoint, null); SIPResponse byeResponse = SIPTransport.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); byeTransaction.SendFinalResponse(byeResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; rtpCts.Cancel(); } } }; // It's a good idea to start the RTP receiving socket before the call request is sent. // A SIP server will generally start sending RTP as soon as it has processed the incoming call request and // being ready to receive will stop any ICMP error response being generated. Task.Run(() => RecvRtp(rtpSocket, rtpRecvSession, rtpCts)); Task.Run(() => SendRtp(rtpSocket, rtpSendSession, rtpCts)); // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, callUri.ToString(), SIPConstants.SIP_DEFAULT_FROMURI, null, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, GetSDP(rtpSocket.LocalEndPoint as IPEndPoint).ToString(), null); uac.Call(callDescriptor); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; rtpCts.Cancel(); }; // At this point the call is established. We'll wait for a few seconds and then transfer. Task.Delay(DELAY_UNTIL_TRANSFER_MILLISECONDS).Wait(); SIPRequest referRequest = GetReferRequest(uac, SIPURI.ParseSIPURI(TRANSFER_DESTINATION_SIP_URI)); SIPNonInviteTransaction referTx = sipTransport.CreateNonInviteTransaction(referRequest, referRequest.RemoteSIPEndPoint, referRequest.LocalSIPEndPoint, null); referTx.NonInviteTransactionFinalResponseReceived += (SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPTransaction sipTransaction, SIPResponse sipResponse) => { if (sipResponse.Header.CSeqMethod == SIPMethodsEnum.REFER && sipResponse.Status == SIPResponseStatusCodesEnum.Accepted) { Log.LogInformation("Call transfer was accepted by remote server."); isCallHungup = true; rtpCts.Cancel(); } }; referTx.SendReliableRequest(); // At this point the call transfer has been initiated and everything will be handled in an event handler or on the RTP // receive task. The code below is to gracefully exit. // Wait for a signal saying the call failed, was cancelled with ctrl-c or completed. rtpCts.Token.WaitHandle.WaitOne(); Log.LogInformation("Exiting..."); rtpSocket?.Close(); controlSocket?.Close(); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }
private static ConcurrentQueue <RTPEvent> _dtmfEvents = new ConcurrentQueue <RTPEvent>(); // Add a DTMF event to this queue to have the it sent static void Main() { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. CancellationTokenSource rtpCts = new CancellationTokenSource(); // Cancellation token to stop the RTP stream. bool isCallHungup = false; bool hasCallFailed = false; AddConsoleLogger(); SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); sipTransport.AddSIPChannel(new SIPUDPChannel(new IPEndPoint(IPAddress.Any, 0))); // Un/comment this line to see/hide each SIP message sent and received. EnableTraceLogs(sipTransport); // Note this relies on the callURI host being an IP address. If it's a hostname a DNS lookup is required. IPAddress localIPAddress = NetServices.GetLocalAddressForRemote(callUri.ToSIPEndPoint().Address); // Initialise an RTP session to receive the RTP packets from the remote SIP server. Socket rtpSocket = null; Socket controlSocket = null; NetServices.CreateRtpSocket(localIPAddress, 49000, 49100, false, out rtpSocket, out controlSocket); var rtpRecvSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); var rtpSendSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => { Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); }; uac.CallRinging += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { Log.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); _remoteRtpEndPoint = SDP.GetSDPRTPEndPoint(resp.Body); Log.LogDebug($"Remote RTP socket {_remoteRtpEndPoint}."); } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += (SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPNonInviteTransaction byeTransaction = sipTransport.CreateNonInviteTransaction(sipRequest, null); SIPResponse byeResponse = SIPTransport.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); byeTransaction.SendFinalResponse(byeResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; rtpCts.Cancel(); } } }; // It's a good idea to start the RTP receiving socket before the call request is sent. // A SIP server will generally start sending RTP as soon as it has processed the incoming call request and // being ready to receive will stop any ICMP error response being generated. Task.Run(() => RecvRtp(rtpSocket, rtpRecvSession, rtpCts)); Task.Run(() => SendRtp(rtpSocket, rtpSendSession, rtpCts)); // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, callUri.ToString(), SIPConstants.SIP_DEFAULT_FROMURI, null, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, GetSDP(rtpSocket.LocalEndPoint as IPEndPoint, RTPPayloadTypesEnum.PCMU).ToString(), null); uac.Call(callDescriptor); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; rtpCts.Cancel(); }; // At this point the call has been initiated and everything will be handled in an event handler or on the RTP // receive task. The code below is to gracefully exit. Task.Delay(3000).Wait(); // Add some DTMF events to the queue. These will be transmitted by the SendRtp thread. _dtmfEvents.Enqueue(new RTPEvent(0x05, false, RTPEvent.DEFAULT_VOLUME, 1200, DTMF_EVENT_PAYLOAD_ID)); Task.Delay(2000, rtpCts.Token).Wait(); _dtmfEvents.Enqueue(new RTPEvent(0x09, false, RTPEvent.DEFAULT_VOLUME, 1200, DTMF_EVENT_PAYLOAD_ID)); Task.Delay(2000, rtpCts.Token).Wait(); _dtmfEvents.Enqueue(new RTPEvent(0x02, false, RTPEvent.DEFAULT_VOLUME, 1200, DTMF_EVENT_PAYLOAD_ID)); Task.Delay(2000, rtpCts.Token).Wait(); Log.LogInformation("Exiting..."); rtpCts.Cancel(); rtpSocket?.Close(); controlSocket?.Close(); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }
static async Task Main(string[] args) { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. ManualResetEvent exitMre = new ManualResetEvent(false); bool isCallHungup = false; bool hasCallFailed = false; AddConsoleLogger(); SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); if (args != null && args.Length > 0) { if (!SIPURI.TryParse(args[0], out callUri)) { Log.LogWarning($"Command line argument could not be parsed as a SIP URI {args[0]}"); } } Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); EnableTraceLogs(sipTransport); // Get the IP address the RTP will be sent from. While we can listen on IPAddress.Any | IPv6Any // we can't put 0.0.0.0 or [::0] in the SDP or the callee will treat our RTP stream as inactive. var lookupResult = SIPDNSManager.ResolveSIPService(callUri, false); Log.LogDebug($"DNS lookup result for {callUri}: {lookupResult?.GetSIPEndPoint()}."); var dstAddress = lookupResult.GetSIPEndPoint().Address; // Initialise an RTP session to receive the RTP packets from the remote SIP server. var rtpSession = new RtpAVSession(dstAddress.AddressFamily, new AudioOptions { AudioSource = AudioSourcesEnum.Microphone }, null); var offerSDP = await rtpSession.createOffer(new RTCOfferOptions { RemoteSignallingAddress = dstAddress }); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallRinging += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { Log.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); rtpSession.setRemoteDescription(new RTCSessionDescription { type = RTCSdpType.answer, sdp = SDP.ParseSDPDescription(resp.Body) }); rtpSession.Start(); } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += async(SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPResponse okResponse = SIPResponse.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); await sipTransport.SendResponseAsync(okResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; exitMre.Set(); } } }; // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, callUri.ToString(), SIPConstants.SIP_DEFAULT_FROMURI, callUri.CanonicalAddress, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, offerSDP.ToString(), null); uac.Call(callDescriptor); uac.ServerTransaction.TransactionTraceMessage += (tx, msg) => Log.LogInformation($"UAC tx trace message. {msg}"); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; exitMre.Set(); }; // Wait for a signal saying the call failed, was cancelled with ctrl-c or completed. exitMre.WaitOne(); Log.LogInformation("Exiting..."); rtpSession.CloseSession(null); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }
private static readonly int RTP_REPORTING_PERIOD_SECONDS = 5; // Period at which to write RTP stats. static void Main() { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. CancellationTokenSource cts = new CancellationTokenSource(); bool isCallHungup = false; bool hasCallFailed = false; // Logging configuration. Can be ommitted if internal SIPSorcery debug and warning messages are not required. var loggerFactory = new Microsoft.Extensions.Logging.LoggerFactory(); var loggerConfig = new LoggerConfiguration() .Enrich.FromLogContext() .MinimumLevel.Is(Serilog.Events.LogEventLevel.Debug) .WriteTo.Console() .CreateLogger(); loggerFactory.AddSerilog(loggerConfig); SIPSorcery.Sys.Log.LoggerFactory = loggerFactory; // Set up a default SIP transport. IPAddress defaultAddr = LocalIPConfig.GetDefaultIPv4Address(); var sipTransport = new SIPTransport(SIPDNSManager.ResolveSIPService, new SIPTransactionEngine()); int port = FreePort.FindNextAvailableUDPPort(SIPConstants.DEFAULT_SIP_PORT + 2); var sipChannel = new SIPUDPChannel(new IPEndPoint(defaultAddr, port)); sipTransport.AddSIPChannel(sipChannel); // Initialise an RTP session to receive the RTP packets from the remote SIP server. Socket rtpSocket = null; Socket controlSocket = null; NetServices.CreateRtpSocket(defaultAddr, 49000, 49100, false, out rtpSocket, out controlSocket); var rtpSendSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => SIPSorcery.Sys.Log.Logger.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallRinging += (uac, resp) => SIPSorcery.Sys.Log.Logger.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { SIPSorcery.Sys.Log.Logger.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { SIPSorcery.Sys.Log.Logger.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); IPEndPoint remoteRtpEndPoint = SDP.GetSDPRTPEndPoint(resp.Body); SIPSorcery.Sys.Log.Logger.LogDebug($"Sending initial RTP packet to remote RTP socket {remoteRtpEndPoint}."); // Send a dummy packet to open the NAT session on the RTP path. rtpSendSession.SendAudioFrame(rtpSocket, remoteRtpEndPoint, 0, new byte[] { 0x00 }); } else { SIPSorcery.Sys.Log.Logger.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += (SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPNonInviteTransaction byeTransaction = sipTransport.CreateNonInviteTransaction(sipRequest, remoteEndPoint, localSIPEndPoint, null); SIPResponse byeResponse = SIPTransport.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); byeTransaction.SendFinalResponse(byeResponse); if (uac.IsUACAnswered) { SIPSorcery.Sys.Log.Logger.LogInformation("Call was hungup by remote server."); isCallHungup = true; cts.Cancel(); } } }; // It's a good idea to start the RTP receiving socket before the call request is sent. // A SIP server will generally start sending RTP as soon as it has processed the incoming call request and // being ready to receive will stop any ICMP error response being generated. Task.Run(() => SendRecvRtp(rtpSocket, rtpSendSession, cts)); // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, DESTINATION_SIP_URI, SIPConstants.SIP_DEFAULT_FROMURI, null, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, GetSDP(rtpSocket.LocalEndPoint as IPEndPoint).ToString(), null); uac.Call(callDescriptor); // At this point the call has been initiated and everything will be handled in an event handler or on the RTP // receive task. The code below is to gracefully exit. // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += async delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; cts.Cancel(); SIPSorcery.Sys.Log.Logger.LogInformation("Exiting..."); rtpSocket?.Close(); controlSocket?.Close(); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { SIPSorcery.Sys.Log.Logger.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { SIPSorcery.Sys.Log.Logger.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. SIPSorcery.Sys.Log.Logger.LogInformation("Waiting 1s for call to clean up..."); await Task.Delay(1000); } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { SIPSorcery.Sys.Log.Logger.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }; }
static void Main(string[] args) { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. CancellationTokenSource rtpCts = new CancellationTokenSource(); // Cancellation token to stop the RTP stream. bool isCallHungup = false; bool hasCallFailed = false; // Logging configuration. Can be ommitted if internal SIPSorcery debug and warning messages are not required. var loggerFactory = new Microsoft.Extensions.Logging.LoggerFactory(); var loggerConfig = new LoggerConfiguration() .Enrich.FromLogContext() .MinimumLevel.Is(Serilog.Events.LogEventLevel.Debug) .WriteTo.Console() .CreateLogger(); loggerFactory.AddSerilog(loggerConfig); SIPSorcery.Sys.Log.LoggerFactory = loggerFactory; SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); if (args != null && args.Length > 0) { if (!SIPURI.TryParse(args[0])) { Log.LogWarning($"Command line argument could not be parsed as a SIP URI {args[0]}"); } else { callUri = SIPURI.ParseSIPURIRelaxed(args[0]); } } Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); int port = SIPConstants.DEFAULT_SIP_PORT + 1000; IPAddress localAddress = sipTransport.GetLocalAddress(IPAddress.Parse("8.8.8.8")); sipTransport.AddSIPChannel(new SIPUDPChannel(new IPEndPoint(localAddress, port))); //sipTransport.AddSIPChannel(new SIPUDPChannel(new IPEndPoint(IPAddress.Any, port))); //sipTransport.AddSIPChannel(new SIPUDPChannel(new IPEndPoint(IPAddress.IPv6Any, port))); //EnableTraceLogs(sipTransport); // Select the IP address to use for RTP based on the destination SIP URI. var endPointForCall = callUri.ToSIPEndPoint() == null?sipTransport.GetDefaultSIPEndPoint(callUri.Protocol) : sipTransport.GetDefaultSIPEndPoint(callUri.ToSIPEndPoint()); // Initialise an RTP session to receive the RTP packets from the remote SIP server. Socket rtpSocket = null; Socket controlSocket = null; // TODO (find something better): If the SIP endpoint is using 0.0.0.0 for SIP use loopback for RTP. IPAddress rtpAddress = localAddress; NetServices.CreateRtpSocket(rtpAddress, 49000, 49100, false, out rtpSocket, out controlSocket); var rtpSendSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => { Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); }; uac.CallRinging += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { Log.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); IPEndPoint remoteRtpEndPoint = SDP.GetSDPRTPEndPoint(resp.Body); Log.LogDebug($"Sending initial RTP packet to remote RTP socket {remoteRtpEndPoint}."); // Send a dummy packet to open the NAT session on the RTP path. rtpSendSession.SendAudioFrame(rtpSocket, remoteRtpEndPoint, 0, new byte[] { 0x00 }); } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += (SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPNonInviteTransaction byeTransaction = sipTransport.CreateNonInviteTransaction(sipRequest, remoteEndPoint, localSIPEndPoint, null); SIPResponse byeResponse = SIPTransport.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); byeTransaction.SendFinalResponse(byeResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; rtpCts.Cancel(); } } }; // It's a good idea to start the RTP receiving socket before the call request is sent. // A SIP server will generally start sending RTP as soon as it has processed the incoming call request and // being ready to receive will stop any ICMP error response being generated. Task.Run(() => SendRecvRtp(rtpSocket, rtpSendSession, rtpCts)); // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, callUri.ToString(), SIPConstants.SIP_DEFAULT_FROMURI, null, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, GetSDP(rtpSocket.LocalEndPoint as IPEndPoint).ToString(), null); uac.Call(callDescriptor); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; rtpCts.Cancel(); }; // At this point the call has been initiated and everything will be handled in an event handler or on the RTP // receive task. The code below is to gracefully exit. // Wait for a signal saying the call failed, was cancelled with ctrl-c or completed. rtpCts.Token.WaitHandle.WaitOne(); Log.LogInformation("Exiting..."); rtpSocket?.Close(); controlSocket?.Close(); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }
/// <summary> /// Sends the SIP INVITE probe request. /// </summary> public void SendProbe() { try { if (WorkerProcess == null) { logger.Debug("When attempting to send probe the worker process was null. Marking for immediate restart."); NeedsImmediateRestart = true; } else if (WorkerProcess.HasExited) { logger.Debug("When attempting to send probe the worker had exited. Marking for immediate restart."); NeedsImmediateRestart = true; } else if (m_probeUAC != null && !m_probeUAC.IsUACAnswered) { // A probe call has timed out. m_probeUAC.Cancel(); m_missedProbes++; if (m_missedProbes >= m_missedProbesLimit) { logger.Warn(m_missedProbes + " probes missed for " + AppServerEndpoint.ToString() + ". Marking for immediate restart."); NeedsImmediateRestart = true; } } if (!NeedsImmediateRestart && !NeedsToRestart) { m_probeCount++; //logger.Debug("Sending probe " + m_probeCount + " to " + AppServerEndpoint.GetIPEndPoint().ToString() + "."); DateTime probeSentAt = DateTime.Now; SIPCallDescriptor callDescriptor = new SIPCallDescriptor(m_dispatcherUsername, null, "sip:" + m_dispatcherUsername + "@" + AppServerEndpoint.GetIPEndPoint().ToString(), "sip:" + m_dispatcherUsername + "@sipcalldispatcher", "sip:" + AppServerEndpoint.GetIPEndPoint().ToString(), null, null, null, SIPCallDirection.Out, null, null, null); m_probeUAC = new SIPClientUserAgent(m_sipTransport, null, null, null, null, null, null, null, null, null); m_probeUAC.CallAnswered += (call, sipResponse) => { //logger.Debug("Probe response received for " + AppServerEndpoint.ToString() + "."); if (sipResponse.Status != SIPResponseStatusCodesEnum.BadExtension) //if (sipResponse.Status != SIPResponseStatusCodesEnum.InternalServerError) { logger.Warn("Probe to " + AppServerEndpoint.ToString() + " answered incorrectly on probe number " + m_probeCount + " after " + DateTime.Now.Subtract(probeSentAt).TotalSeconds.ToString("0.##") + "s, unexpected response of " + ((int)sipResponse.StatusCode) + "."); NeedsImmediateRestart = true; } else { m_gotInitialProbeResponse = true; } if (m_initialResponseMRE != null) { m_initialResponseMRE.Set(); } }; m_probeUAC.Call(callDescriptor); } } catch (Exception excp) { logger.Error("Exception SendProbe. " + excp.Message); } }
static void Main() { Console.WriteLine("SIPSorcery call hold example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. CancellationTokenSource exitCts = new CancellationTokenSource(); // Cancellation token to stop the SIP trnasport and RTP stream. bool isCallHungup = false; bool hasCallFailed = false; AddConsoleLogger(); SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); sipTransport.AddSIPChannel(new SIPUDPChannel(new IPEndPoint(IPAddress.Any, 0))); EnableTraceLogs(sipTransport); var lookupResult = SIPDNSManager.ResolveSIPService(callUri, false); Log.LogDebug($"DNS lookup result for {callUri}: {lookupResult?.GetSIPEndPoint()}."); var dstAddress = lookupResult.GetSIPEndPoint().Address; IPAddress localIPAddress = NetServices.GetLocalAddressForRemote(dstAddress); // Initialise an RTP session to receive the RTP packets from the remote SIP server. Socket rtpSocket = null; Socket controlSocket = null; NetServices.CreateRtpSocket(localIPAddress, 48000, 48100, false, out rtpSocket, out controlSocket); var rtpRecvSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); var rtpSendSession = new RTPSession((int)RTPPayloadTypesEnum.PCMU, null, null); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => { Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); }; uac.CallRinging += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { Log.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); // Only set the remote RTP end point if there hasn't already been a packet received on it. if (_remoteRtpEndPoint == null) { _remoteRtpEndPoint = SDP.GetSDPRTPEndPoint(resp.Body); Log.LogDebug($"Remote RTP socket {_remoteRtpEndPoint}."); } } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += (SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPNonInviteTransaction byeTransaction = sipTransport.CreateNonInviteTransaction(sipRequest, null); SIPResponse byeResponse = SIPTransport.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); byeTransaction.SendFinalResponse(byeResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; exitCts.Cancel(); } } }; // It's a good idea to start the RTP receiving socket before the call request is sent. // A SIP server will generally start sending RTP as soon as it has processed the incoming call request and // being ready to receive will stop any ICMP error response being generated. Task.Run(() => RecvRtp(rtpSocket, rtpRecvSession, exitCts)); Task.Run(() => SendRtp(rtpSocket, rtpSendSession, exitCts)); // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIP_USERNAME, SIP_PASSWORD, callUri.ToString(), $"sip:{SIP_USERNAME}@localhost", callUri.CanonicalAddress, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, GetSDP(rtpSocket.LocalEndPoint as IPEndPoint).ToString(), null); uac.Call(callDescriptor); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; exitCts.Cancel(); }; // At this point the call has been initiated and everything will be handled in an event handler. Task.Run(() => { try { while (!exitCts.Token.WaitHandle.WaitOne(0)) { var keyProps = Console.ReadKey(); if (keyProps.KeyChar == 'h') { } else if (keyProps.KeyChar == 'q') { Console.WriteLine(); Console.WriteLine("Hangup requested by user..."); uac.Hangup(); exitCts.Cancel(); rtpSocket?.Close(); controlSocket?.Close(); SIPSorcery.Sys.Log.Logger.LogInformation("Quitting..."); if (sipTransport != null) { SIPSorcery.Sys.Log.Logger.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } } } } catch (Exception excp) { SIPSorcery.Sys.Log.Logger.LogError($"Exception Key Press listener. {excp.Message}."); } }); // Wait for a signal saying the call failed, was cancelled with ctrl-c or completed. exitCts.Token.WaitHandle.WaitOne(); Log.LogInformation("Exiting..."); rtpSocket?.Close(); controlSocket?.Close(); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }
private static int INPUT_SAMPLE_PERIOD_MILLISECONDS = 20; // This sets the frequency of the RTP packets. static void Main(string[] args) { Console.WriteLine("SIPSorcery client user agent example."); Console.WriteLine("Press ctrl-c to exit."); // Plumbing code to facilitate a graceful exit. ManualResetEvent exitMre = new ManualResetEvent(false); bool isCallHungup = false; bool hasCallFailed = false; AddConsoleLogger(); SIPURI callUri = SIPURI.ParseSIPURI(DEFAULT_DESTINATION_SIP_URI); if (args != null && args.Length > 0) { if (!SIPURI.TryParse(args[0], out callUri)) { Log.LogWarning($"Command line argument could not be parsed as a SIP URI {args[0]}"); } } Log.LogInformation($"Call destination {callUri}."); // Set up a default SIP transport. var sipTransport = new SIPTransport(); EnableTraceLogs(sipTransport); // Get the IP address the RTP will be sent from. While we can listen on IPAddress.Any | IPv6Any // we can't put 0.0.0.0 or [::0] in the SDP or the callee will ignore us. var lookupResult = SIPDNSManager.ResolveSIPService(callUri, false); Log.LogDebug($"DNS lookup result for {callUri}: {lookupResult?.GetSIPEndPoint()}."); var dstAddress = lookupResult.GetSIPEndPoint().Address; IPAddress localIPAddress = NetServices.GetLocalAddressForRemote(dstAddress); // Initialise an RTP session to receive the RTP packets from the remote SIP server. var rtpSession = new RTPMediaSession((int)SDPMediaFormatsEnum.PCMU, localIPAddress.AddressFamily); var offerSDP = rtpSession.GetSDP(localIPAddress); // Get the audio input device. WaveInEvent waveInEvent = GetAudioInputDevice(); // Create a client user agent to place a call to a remote SIP server along with event handlers for the different stages of the call. var uac = new SIPClientUserAgent(sipTransport); uac.CallTrying += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Trying: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallRinging += (uac, resp) => Log.LogInformation($"{uac.CallDescriptor.To} Ringing: {resp.StatusCode} {resp.ReasonPhrase}."); uac.CallFailed += (uac, err) => { Log.LogWarning($"{uac.CallDescriptor.To} Failed: {err}"); hasCallFailed = true; }; uac.CallAnswered += (uac, resp) => { if (resp.Status == SIPResponseStatusCodesEnum.Ok) { Log.LogInformation($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); // Only set the remote RTP end point if there hasn't already been a packet received on it. if (rtpSession.DestinationEndPoint == null) { rtpSession.DestinationEndPoint = SDP.GetSDPRTPEndPoint(resp.Body); Log.LogDebug($"Remote RTP socket {rtpSession.DestinationEndPoint}."); } rtpSession.SetRemoteSDP(SDP.ParseSDPDescription(resp.Body)); waveInEvent.StartRecording(); } else { Log.LogWarning($"{uac.CallDescriptor.To} Answered: {resp.StatusCode} {resp.ReasonPhrase}."); } }; // The only incoming request that needs to be explicitly handled for this example is if the remote end hangs up the call. sipTransport.SIPTransportRequestReceived += async(SIPEndPoint localSIPEndPoint, SIPEndPoint remoteEndPoint, SIPRequest sipRequest) => { if (sipRequest.Method == SIPMethodsEnum.BYE) { SIPResponse okResponse = SIPResponse.GetResponse(sipRequest, SIPResponseStatusCodesEnum.Ok, null); await sipTransport.SendResponseAsync(okResponse); if (uac.IsUACAnswered) { Log.LogInformation("Call was hungup by remote server."); isCallHungup = true; exitMre.Set(); } } }; // Wire up the RTP receive session to the audio output device. var(audioOutEvent, audioOutProvider) = GetAudioOutputDevice(); rtpSession.OnReceivedSampleReady += (sample) => { for (int index = 0; index < sample.Length; index++) { short pcm = NAudio.Codecs.MuLawDecoder.MuLawToLinearSample(sample[index]); byte[] pcmSample = new byte[] { (byte)(pcm & 0xFF), (byte)(pcm >> 8) }; audioOutProvider.AddSamples(pcmSample, 0, 2); } }; // Wire up the RTP send session to the audio input device. uint rtpSendTimestamp = 0; waveInEvent.DataAvailable += (object sender, WaveInEventArgs args) => { byte[] sample = new byte[args.Buffer.Length / 2]; int sampleIndex = 0; for (int index = 0; index < args.BytesRecorded; index += 2) { var ulawByte = NAudio.Codecs.MuLawEncoder.LinearToMuLawSample(BitConverter.ToInt16(args.Buffer, index)); sample[sampleIndex++] = ulawByte; } if (rtpSession.DestinationEndPoint != null) { rtpSession.SendAudioFrame(rtpSendTimestamp, sample); rtpSendTimestamp += (uint)(8000 / waveInEvent.BufferMilliseconds); } }; // Start the thread that places the call. SIPCallDescriptor callDescriptor = new SIPCallDescriptor( SIPConstants.SIP_DEFAULT_USERNAME, null, callUri.ToString(), SIPConstants.SIP_DEFAULT_FROMURI, callUri.CanonicalAddress, null, null, null, SIPCallDirection.Out, SDP.SDP_MIME_CONTENTTYPE, offerSDP.ToString(), null); uac.Call(callDescriptor); uac.ServerTransaction.TransactionTraceMessage += (tx, msg) => Log.LogInformation($"UAC tx trace message. {msg}"); // Ctrl-c will gracefully exit the call at any point. Console.CancelKeyPress += delegate(object sender, ConsoleCancelEventArgs e) { e.Cancel = true; exitMre.Set(); }; // Wait for a signal saying the call failed, was cancelled with ctrl-c or completed. exitMre.WaitOne(); Log.LogInformation("Exiting..."); waveInEvent?.StopRecording(); audioOutEvent?.Stop(); rtpSession.CloseSession(null); if (!isCallHungup && uac != null) { if (uac.IsUACAnswered) { Log.LogInformation($"Hanging up call to {uac.CallDescriptor.To}."); uac.Hangup(); } else if (!hasCallFailed) { Log.LogInformation($"Cancelling call to {uac.CallDescriptor.To}."); uac.Cancel(); } // Give the BYE or CANCEL request time to be transmitted. Log.LogInformation("Waiting 1s for call to clean up..."); Task.Delay(1000).Wait(); } SIPSorcery.Net.DNSManager.Stop(); if (sipTransport != null) { Log.LogInformation("Shutting down SIP transport..."); sipTransport.Shutdown(); } }