/**
* Handles a specific <tt>IOException</tt> which was thrown during the execution of {@link
* #runInConnectThread(DTLSProtocol, TlsPeer, DatagramTransport)} while trying to establish a DTLS
* connection
*
* @param ioe the <tt>IOException</tt> to handle
* @param msg the human-readable message to log about the specified <tt>ioe</tt>
* @param i the number of tries remaining after the current one
* @return <tt>true</tt> if the specified <tt>ioe</tt> was successfully handled; <tt>false</tt>,
* otherwise
*/
private boolean handleRunInConnectThreadException(IOException ioe, String msg, int i) {
// SrtpControl.start(MediaType) starts its associated TransformEngine.
// We will use that mediaType to signal the normal stop then as well
// i.e. we will ignore exception after the procedure to stop this
// PacketTransformer has begun.
if (mediaType == null) return false;
if (ioe instanceof TlsFatalAlert) {
TlsFatalAlert tfa = (TlsFatalAlert) ioe;
short alertDescription = tfa.getAlertDescription();
if (alertDescription == AlertDescription.unexpected_message) {
msg += " Received fatal unexpected message.";
if (i == 0
|| !Thread.currentThread().equals(connectThread)
|| connector == null
|| mediaType == null) {
msg += " Giving up after " + (CONNECT_TRIES - i) + " retries.";
} else {
msg += " Will retry.";
logger.error(msg, ioe);
return true;
}
} else {
msg += " Received fatal alert " + alertDescription + ".";
}
}
logger.error(msg, ioe);
return false;
}
/**
* Creates and starts the {@link #sendKeepAliveMessageThread} which is to send STUN keep-alive
* <tt>Message</tt>s to the STUN server associated with the <tt>StunCandidateHarvester</tt> of
* this instance in order to keep the <tt>Candidate</tt>s harvested by this instance alive.
*/
private void createSendKeepAliveMessageThread() {
synchronized (sendKeepAliveMessageSyncRoot) {
Thread t = new SendKeepAliveMessageThread(this);
t.setDaemon(true);
t.setName(getClass().getName() + ".sendKeepAliveMessageThread: " + hostCandidate);
boolean started = false;
sendKeepAliveMessageThread = t;
try {
t.start();
started = true;
} finally {
if (!started && (sendKeepAliveMessageThread == t)) sendKeepAliveMessageThread = null;
}
}
}
/**
* Determines whether {@link #runInConnectThread(DTLSProtocol, TlsPeer, DatagramTransport)} is to
* try to establish a DTLS connection.
*
* @param i the number of tries remaining after the current one
* @param datagramTransport
* @return <tt>true</tt> to try to establish a DTLS connection; otherwise, <tt>false</tt>
*/
private boolean enterRunInConnectThreadLoop(int i, DatagramTransport datagramTransport) {
if (i < 0 || i > CONNECT_TRIES) {
return false;
} else {
Thread currentThread = Thread.currentThread();
synchronized (this) {
if (i > 0 && i < CONNECT_TRIES - 1) {
boolean interrupted = false;
try {
wait(CONNECT_RETRY_INTERVAL);
} catch (InterruptedException ie) {
interrupted = true;
}
if (interrupted) currentThread.interrupt();
}
return currentThread.equals(this.connectThread)
&& datagramTransport.equals(this.datagramTransport);
}
}
}
/**
* Runs in {@link #sendKeepAliveMessageThread} to notify this instance that
* <tt>sendKeepAliveMessageThread</tt> is about to exit.
*/
private void exitSendKeepAliveMessageThread() {
synchronized (sendKeepAliveMessageSyncRoot) {
if (sendKeepAliveMessageThread == Thread.currentThread()) sendKeepAliveMessageThread = null;
/*
* Well, if the currentThread is finishing and this instance is
* still to send keep-alive messages, we'd better start another
* Thread for the purpose to continue the work that the
* currentThread was supposed to carry out.
*/
if ((sendKeepAliveMessageThread == null)
&& (sendKeepAliveMessageInterval != SEND_KEEP_ALIVE_MESSAGE_INTERVAL_NOT_SPECIFIED)) {
createSendKeepAliveMessageThread();
}
}
}
/**
* Gets the {@code SRTPTransformer} used by this instance. If {@link #_srtpTransformer} does not
* exist (yet) and the state of this instance indicates that its initialization is in progess,
* then blocks until {@code _srtpTransformer} is initialized and returns it.
*
* @return the {@code SRTPTransformer} used by this instance
*/
private SinglePacketTransformer waitInitializeAndGetSRTPTransformer() {
SinglePacketTransformer srtpTransformer = _srtpTransformer;
if (srtpTransformer != null) return srtpTransformer;
if (rtcpmux && Component.RTCP == componentID) return initializeSRTCPTransformerFromRtp();
// XXX It is our explicit policy to rely on the SrtpListener to notify
// the user that the session is not secure. Unfortunately, (1) the
// SrtpListener is not supported by this DTLS SrtpControl implementation
// and (2) encrypted packets may arrive soon enough to be let through
// while _srtpTransformer is still initializing. Consequently, we will
// block and wait for _srtpTransformer to initialize.
boolean interrupted = false;
try {
synchronized (this) {
do {
srtpTransformer = _srtpTransformer;
if (srtpTransformer != null) break; // _srtpTransformer is initialized
if (connectThread == null) {
// Though _srtpTransformer is NOT initialized, there is
// no point in waiting because there is no one to
// initialize it.
break;
}
try {
// It does not really matter (enough) how much we wait
// here because we wait in a loop.
long timeout = CONNECT_TRIES * CONNECT_RETRY_INTERVAL;
wait(timeout);
} catch (InterruptedException ie) {
interrupted = true;
}
} while (true);
}
} finally {
if (interrupted) Thread.currentThread().interrupt();
}
return srtpTransformer;
}
/**
* Runs in {@link #sendKeepAliveMessageThread} and sends STUN keep-alive <tt>Message</tt>s to the
* STUN server associated with the <tt>StunCandidateHarvester</tt> of this instance.
*
* @return <tt>true</tt> if the method is to be invoked again; otherwise, <tt>false</tt>
*/
private boolean runInSendKeepAliveMessageThread() {
synchronized (sendKeepAliveMessageSyncRoot) {
// Since we're going to #wait, make sure we're not canceled yet.
if (sendKeepAliveMessageThread != Thread.currentThread()) return false;
if (sendKeepAliveMessageInterval == SEND_KEEP_ALIVE_MESSAGE_INTERVAL_NOT_SPECIFIED) {
return false;
}
// Determine the amount of milliseconds that we'll have to #wait.
long timeout;
if (sendKeepAliveMessageTime == -1) {
/*
* If we're just starting, don't just go and send a new STUN
* keep-alive message but rather wait for the whole interval.
*/
timeout = sendKeepAliveMessageInterval;
} else {
timeout =
sendKeepAliveMessageTime + sendKeepAliveMessageInterval - System.currentTimeMillis();
}
// At long last, #wait if necessary.
if (timeout > 0) {
try {
sendKeepAliveMessageSyncRoot.wait(timeout);
} catch (InterruptedException iex) {
}
/*
* Apart from being the time to send the STUN keep-alive
* message, it could be that we've experienced a spurious
* wake-up or that we've been canceled.
*/
return true;
}
}
sendKeepAliveMessageTime = System.currentTimeMillis();
try {
sendKeepAliveMessage();
} catch (StunException sex) {
logger.log(Level.INFO, "Failed to send STUN keep-alive message.", sex);
}
return true;
}
/**
* Runs a test application that allocates streams, generates an SDP, dumps it on stdout, waits for
* a remote peer SDP on stdin, then feeds that to our local agent and starts ICE processing.
*
* @param args none currently handled
* @throws Throwable every now and then.
*/
public static void main(String[] args) throws Throwable {
final Agent localAgent = createAgent(2020);
localAgent.setNominationStrategy(NominationStrategy.NOMINATE_HIGHEST_PRIO);
// localAgent.addStateChangeListener(new IceProcessingListener());
// let them fight ... fights forge character.
localAgent.setControlling(false);
String localSDP = SdpUtils.createSDPDescription(localAgent);
// wait a bit so that the logger can stop dumping stuff:
Thread.sleep(500);
System.out.println(
"=================== feed the following" + " to the remote agent ===================");
System.out.println(localSDP);
System.out.println(
"======================================" + "========================================\n");
String sdp = readSDP();
startTime = System.currentTimeMillis();
SdpUtils.parseSDP(localAgent, sdp);
localAgent.startConnectivityEstablishment();
localAgent.addStateChangeListener(
new PropertyChangeListener() {
@Override
public void propertyChange(PropertyChangeEvent propertyChangeEvent) {
if (propertyChangeEvent.getPropertyName().equals(Agent.PROPERTY_ICE_PROCESSING_STATE)
&& propertyChangeEvent.getNewValue().equals(IceProcessingState.COMPLETED)) {
System.out.println("************************!!!!!!!!!!!!! Start doing stuff here");
IceMediaStream stream = localAgent.getStream("video");
CandidatePair rtpPair = stream.getComponent(Component.RTP).getSelectedPair();
CandidatePair rtcpPair = stream.getComponent(Component.RTCP).getSelectedPair();
DatagramSocket rtpSocket = rtpPair.getLocalCandidate().getDatagramSocket();
DatagramSocket rtcpSocket = rtcpPair.getLocalCandidate().getDatagramSocket();
byte[] data = "sent".getBytes();
RemoteCandidate rem = rtpPair.getRemoteCandidate();
TransportAddress target = rem.getHostAddress();
DatagramPacket p =
new DatagramPacket(data, data.length, target.getAddress(), target.getPort());
try {
System.out.println("About to send packet..");
rtpSocket.send(p);
System.out.println("Receiving packet..");
DatagramPacket p2 = new DatagramPacket(new byte[data.length], data.length);
rtpSocket.receive(p2);
System.out.println("========Received: " + new String(p2.getData()));
} catch (IOException e) {
e.printStackTrace();
}
}
}
});
// Give processing enough time to finish. We'll System.exit() anyway
// as soon as localAgent enters a final state.
Thread.sleep(60000);
}
/** Starts this <tt>PacketTransformer</tt>. */
private synchronized void start() {
if (this.datagramTransport != null) {
if (this.connectThread == null && dtlsTransport == null) {
logger.warn(
getClass().getName()
+ " has been started but has failed to establish"
+ " the DTLS connection!");
}
return;
}
if (rtcpmux && Component.RTCP == componentID) {
// In the case of rtcp-mux, the RTCP transformer does not create
// a DTLS session. The SRTP context (_srtpTransformer) will be
// initialized on demand using initializeSRTCPTransformerFromRtp().
return;
}
AbstractRTPConnector connector = this.connector;
if (connector == null) throw new NullPointerException("connector");
DtlsControl.Setup setup = this.setup;
SecureRandom secureRandom = DtlsControlImpl.createSecureRandom();
final DTLSProtocol dtlsProtocolObj;
final TlsPeer tlsPeer;
if (DtlsControl.Setup.ACTIVE.equals(setup)) {
dtlsProtocolObj = new DTLSClientProtocol(secureRandom);
tlsPeer = new TlsClientImpl(this);
} else {
dtlsProtocolObj = new DTLSServerProtocol(secureRandom);
tlsPeer = new TlsServerImpl(this);
}
tlsPeerHasRaisedCloseNotifyWarning = false;
final DatagramTransportImpl datagramTransport = new DatagramTransportImpl(componentID);
datagramTransport.setConnector(connector);
Thread connectThread =
new Thread() {
@Override
public void run() {
try {
runInConnectThread(dtlsProtocolObj, tlsPeer, datagramTransport);
} finally {
if (Thread.currentThread().equals(DtlsPacketTransformer.this.connectThread)) {
DtlsPacketTransformer.this.connectThread = null;
}
}
}
};
connectThread.setDaemon(true);
connectThread.setName(DtlsPacketTransformer.class.getName() + ".connectThread");
this.connectThread = connectThread;
this.datagramTransport = datagramTransport;
boolean started = false;
try {
connectThread.start();
started = true;
} finally {
if (!started) {
if (connectThread.equals(this.connectThread)) this.connectThread = null;
if (datagramTransport.equals(this.datagramTransport)) this.datagramTransport = null;
}
}
notifyAll();
}
/**
* Runs in {@link #connectThread} to initialize {@link #dtlsTransport}.
*
* @param dtlsProtocol
* @param tlsPeer
* @param datagramTransport
*/
private void runInConnectThread(
DTLSProtocol dtlsProtocol, TlsPeer tlsPeer, DatagramTransport datagramTransport) {
DTLSTransport dtlsTransport = null;
final boolean srtp = !transformEngine.isSrtpDisabled();
int srtpProtectionProfile = 0;
TlsContext tlsContext = null;
// DTLS client
if (dtlsProtocol instanceof DTLSClientProtocol) {
DTLSClientProtocol dtlsClientProtocol = (DTLSClientProtocol) dtlsProtocol;
TlsClientImpl tlsClient = (TlsClientImpl) tlsPeer;
for (int i = CONNECT_TRIES - 1; i >= 0; i--) {
if (!enterRunInConnectThreadLoop(i, datagramTransport)) break;
try {
dtlsTransport = dtlsClientProtocol.connect(tlsClient, datagramTransport);
break;
} catch (IOException ioe) {
if (!handleRunInConnectThreadException(
ioe, "Failed to connect this DTLS client to a DTLS" + " server!", i)) {
break;
}
}
}
if (dtlsTransport != null && srtp) {
srtpProtectionProfile = tlsClient.getChosenProtectionProfile();
tlsContext = tlsClient.getContext();
}
}
// DTLS server
else if (dtlsProtocol instanceof DTLSServerProtocol) {
DTLSServerProtocol dtlsServerProtocol = (DTLSServerProtocol) dtlsProtocol;
TlsServerImpl tlsServer = (TlsServerImpl) tlsPeer;
for (int i = CONNECT_TRIES - 1; i >= 0; i--) {
if (!enterRunInConnectThreadLoop(i, datagramTransport)) break;
try {
dtlsTransport = dtlsServerProtocol.accept(tlsServer, datagramTransport);
break;
} catch (IOException ioe) {
if (!handleRunInConnectThreadException(
ioe, "Failed to accept a connection from a DTLS client!", i)) {
break;
}
}
}
if (dtlsTransport != null && srtp) {
srtpProtectionProfile = tlsServer.getChosenProtectionProfile();
tlsContext = tlsServer.getContext();
}
} else {
// It MUST be either a DTLS client or a DTLS server.
throw new IllegalStateException("dtlsProtocol");
}
SinglePacketTransformer srtpTransformer =
(dtlsTransport == null || !srtp)
? null
: initializeSRTPTransformer(srtpProtectionProfile, tlsContext);
boolean closeSRTPTransformer;
synchronized (this) {
if (Thread.currentThread().equals(this.connectThread)
&& datagramTransport.equals(this.datagramTransport)) {
this.dtlsTransport = dtlsTransport;
_srtpTransformer = srtpTransformer;
notifyAll();
}
closeSRTPTransformer = (_srtpTransformer != srtpTransformer);
}
if (closeSRTPTransformer && srtpTransformer != null) srtpTransformer.close();
}