/** {@inheritDoc} */ @Override public RawPacket transform(RawPacket pkt) { byte[] buf = pkt.getBuffer(); int off = pkt.getOffset(); int len = pkt.getLength(); // If the specified pkt represents a DTLS record, then it should pass // through this PacketTransformer (e.g. it has been sent through // DatagramTransportImpl). if (isDtlsRecord(buf, off, len)) return pkt; // SRTP if (!transformEngine.isSrtpDisabled()) { // DTLS-SRTP has not been initialized yet or has failed to // initialize. SinglePacketTransformer srtpTransformer = waitInitializeAndGetSRTPTransformer(); if (srtpTransformer != null) pkt = srtpTransformer.transform(pkt); else if (DROP_UNENCRYPTED_PKTS) pkt = null; // XXX Else, it is our explicit policy to let the received packet // pass through and rely on the SrtpListener to notify the user that // the session is not secured. } // Pure/non-SRTP DTLS else { // The specified pkt will pass through this PacketTransformer only // if it gets transformed into a DTLS record. pkt = null; sendApplicationData(buf, off, len); } return pkt; }
/** * Copies the content of the most recently received packet into <tt>data</tt>. * * @param buffer an optional <tt>Buffer</tt> instance associated with the specified <tt>data</tt>, * <tt>offset</tt> and <tt>length</tt> and provided to the method in case the implementation * would like to provide additional <tt>Buffer</tt> properties such as <tt>flags</tt> * @param data the <tt>byte[]</tt> that we'd like to copy the content of the packet to. * @param offset the position where we are supposed to start writing in <tt>data</tt>. * @param length the number of <tt>byte</tt>s available for writing in <tt>data</tt>. * @return the number of bytes read * @throws IOException if <tt>length</tt> is less than the size of the packet. */ protected int read(Buffer buffer, byte[] data, int offset, int length) throws IOException { if (data == null) throw new NullPointerException("data"); if (ioError) return -1; RawPacket pkt; synchronized (pktSyncRoot) { pkt = this.pkt; this.pkt = null; } int pktLength; if (pkt == null) { pktLength = 0; } else { // By default, pkt will be returned to the pool after it was read. boolean poolPkt = true; try { pktLength = pkt.getLength(); if (length < pktLength) { /* * If pkt is still the latest RawPacket made available to * reading, reinstate it for the next invocation of read; * otherwise, return it to the pool. */ poolPkt = false; throw new IOException("Input buffer not big enough for " + pktLength); } else { byte[] pktBuffer = pkt.getBuffer(); if (pktBuffer == null) { throw new NullPointerException( "pkt.buffer null, pkt.length " + pktLength + ", pkt.offset " + pkt.getOffset()); } else { System.arraycopy(pkt.getBuffer(), pkt.getOffset(), data, offset, pktLength); if (buffer != null) buffer.setFlags(pkt.getFlags()); } } } finally { if (!poolPkt) { synchronized (pktSyncRoot) { if (this.pkt == null) this.pkt = pkt; else poolPkt = true; } } if (poolPkt) { // Return pkt to the pool because it was successfully read. poolRawPacket(pkt); } } } return pktLength; }
/** * Sends a specific <tt>RawPacket</tt> through this <tt>OutputDataStream</tt> to a specific * <tt>InetSocketAddress</tt>. * * @param packet the <tt>RawPacket</tt> to send through this <tt>OutputDataStream</tt> to the * specified <tt>target</tt> * @param target the <tt>InetSocketAddress</tt> to which the specified <tt>packet</tt> is to be * sent through this <tt>OutputDataStream</tt> * @throws IOException if anything goes wrong while sending the specified <tt>packet</tt> through * this <tt>OutputDataStream</tt> to the specified <tt>target</tt> */ @Override protected void sendToTarget(RawPacket packet, InetSocketAddress target) throws IOException { socket.send( new DatagramPacket( packet.getBuffer(), packet.getOffset(), packet.getLength(), target.getAddress(), target.getPort())); }
private void emptyPacketBuffer(long ssrc) { RawPacket[] pkts = rtpConnector.packetBuffer.emptyBuffer(ssrc); RTPConnectorImpl.OutputDataStreamImpl dataStream; try { dataStream = rtpConnector.getDataOutputStream(); } catch (IOException ioe) { logger.error("Failed to empty packet buffer for SSRC=" + ssrc + ": " + ioe); return; } for (RawPacket pkt : pkts) dataStream.write( pkt.getBuffer(), pkt.getOffset(), pkt.getLength(), false /* already transformed */); }
@Override public int read(byte[] buffer, int offset, int length) throws IOException { RawPacket pendingPacket; if (isControlStream) { pendingPacket = pendingControlPacket; } else { pendingPacket = pendingDataPacket; } int bytesToRead = 0; byte[] pendingPacketBuffer = pendingPacket.getBuffer(); if (pendingPacketBuffer != null) { int pendingPacketLength = pendingPacket.getLength(); bytesToRead = length > pendingPacketLength ? pendingPacketLength : length; System.arraycopy( pendingPacketBuffer, pendingPacket.getOffset(), buffer, offset, bytesToRead); } return bytesToRead; }
/** * Log the packet. * * @param packet packet to log */ @Override protected void doLogPacket(RawPacket packet, InetSocketAddress target) { if (socket == null || packet == null || target == null) return; // Do not log the packet if it has been processed (and already // logged) by the ice4j stack. if (socket instanceof MultiplexingDatagramSocket) return; PacketLoggingService pktLogging = getPacketLoggingService(); if (pktLogging != null) { pktLogging.logPacket( PacketLoggingService.ProtocolName.RTP, socket.getLocalAddress().getAddress(), socket.getLocalPort(), target.getAddress().getAddress(), target.getPort(), PacketLoggingService.TransportName.UDP, true, packet.getBuffer(), packet.getOffset(), packet.getLength()); } }
private void runOnDtlsTransport(StreamConnector connector) throws IOException { DtlsControlImpl dtlsControl = (DtlsControlImpl) getTransportManager().getDtlsControl(this); DtlsTransformEngine engine = dtlsControl.getTransformEngine(); final DtlsPacketTransformer transformer = (DtlsPacketTransformer) engine.getRTPTransformer(); byte[] receiveBuffer = new byte[SCTP_BUFFER_SIZE]; if (LOG_SCTP_PACKETS) { System.setProperty( ConfigurationService.PNAME_SC_HOME_DIR_LOCATION, System.getProperty("java.io.tmpdir")); System.setProperty( ConfigurationService.PNAME_SC_HOME_DIR_NAME, SctpConnection.class.getName()); } synchronized (this) { // FIXME local SCTP port is hardcoded in bridge offer SDP (Jitsi // Meet) sctpSocket = Sctp.createSocket(5000); assocIsUp = false; acceptedIncomingConnection = false; } // Implement output network link for SCTP stack on DTLS transport sctpSocket.setLink( new NetworkLink() { @Override public void onConnOut(SctpSocket s, byte[] packet) throws IOException { if (LOG_SCTP_PACKETS) { LibJitsi.getPacketLoggingService() .logPacket( PacketLoggingService.ProtocolName.ICE4J, new byte[] {0, 0, 0, (byte) debugId}, 5000, new byte[] {0, 0, 0, (byte) (debugId + 1)}, remoteSctpPort, PacketLoggingService.TransportName.UDP, true, packet); } // Send through DTLS transport transformer.sendApplicationData(packet, 0, packet.length); } }); if (logger.isDebugEnabled()) { logger.debug("Connecting SCTP to port: " + remoteSctpPort + " to " + getEndpoint().getID()); } sctpSocket.setNotificationListener(this); sctpSocket.listen(); // FIXME manage threads threadPool.execute( new Runnable() { @Override public void run() { SctpSocket sctpSocket = null; try { // sctpSocket is set to null on close sctpSocket = SctpConnection.this.sctpSocket; while (sctpSocket != null) { if (sctpSocket.accept()) { acceptedIncomingConnection = true; break; } Thread.sleep(100); sctpSocket = SctpConnection.this.sctpSocket; } if (isReady()) { notifySctpConnectionReady(); } } catch (Exception e) { logger.error("Error accepting SCTP connection", e); } if (sctpSocket == null && logger.isInfoEnabled()) { logger.info( "SctpConnection " + getID() + " closed" + " before SctpSocket accept()-ed."); } } }); // Notify that from now on SCTP connection is considered functional sctpSocket.setDataCallback(this); // Setup iceSocket DatagramSocket datagramSocket = connector.getDataSocket(); if (datagramSocket != null) { this.iceSocket = new IceUdpSocketWrapper(datagramSocket); } else { this.iceSocket = new IceTcpSocketWrapper(connector.getDataTCPSocket()); } DatagramPacket rcvPacket = new DatagramPacket(receiveBuffer, 0, receiveBuffer.length); // Receive loop, breaks when SCTP socket is closed try { do { iceSocket.receive(rcvPacket); RawPacket raw = new RawPacket(rcvPacket.getData(), rcvPacket.getOffset(), rcvPacket.getLength()); raw = transformer.reverseTransform(raw); // Check for app data if (raw == null) continue; if (LOG_SCTP_PACKETS) { LibJitsi.getPacketLoggingService() .logPacket( PacketLoggingService.ProtocolName.ICE4J, new byte[] {0, 0, 0, (byte) (debugId + 1)}, remoteSctpPort, new byte[] {0, 0, 0, (byte) debugId}, 5000, PacketLoggingService.TransportName.UDP, false, raw.getBuffer(), raw.getOffset(), raw.getLength()); } // Pass network packet to SCTP stack sctpSocket.onConnIn(raw.getBuffer(), raw.getOffset(), raw.getLength()); } while (true); } finally { // Eventually, close the socket although it should happen from // expire(). synchronized (this) { assocIsUp = false; acceptedIncomingConnection = false; if (sctpSocket != null) { sctpSocket.close(); sctpSocket = null; } } } }
/** * Notifies this instance that a <tt>DatagramPacket</tt> packet received on the data * <tt>DatagramSocket</tt> of this <tt>Channel</tt> has been accepted for further processing * within Jitsi Videobridge. * * @param pkt the accepted <tt>RawPacket</tt>. */ public void accepted(RawPacket pkt) { // With native simulcast we don't have a notification when a stream // has started/stopped. The simulcast manager implements a timeout // for the high quality stream and it needs to be notified when // the channel has accepted a datagram packet for the timeout to // function correctly. if (!hasLayers() || pkt == null) { return; } // Find the layer that corresponds to this packet. int acceptedSSRC = pkt.getSSRC(); SimulcastLayer[] layers = getSimulcastLayers(); SimulcastLayer acceptedLayer = null; for (SimulcastLayer layer : layers) { // We only care about the primary SSRC and not the RTX ssrc (or // future FEC ssrc). if ((int) layer.getPrimarySSRC() == acceptedSSRC) { acceptedLayer = layer; break; } } // If this is not an RTP packet or if we can't find an accepted // layer, log and return as it makes no sense to continue in this // situation. if (acceptedLayer == null) { return; } // There are sequences of packets with increasing timestamps but without // the marker bit set. Supposedly, they are probes to detect whether the // bandwidth may increase. We think that they should cause neither the // start nor the stop of any SimulcastLayer. // XXX There's RawPacket#getPayloadLength() but the implementation // includes pkt.paddingSize at the time of this writing and we do not // know whether that's going to stay that way. int pktPayloadLength = pkt.getLength() - pkt.getHeaderLength(); int pktPaddingSize = pkt.getPaddingSize(); if (pktPayloadLength <= pktPaddingSize) { if (logger.isTraceEnabled()) { logger.trace( "pkt.payloadLength= " + pktPayloadLength + " <= pkt.paddingSize= " + pktPaddingSize + "(" + pkt.getSequenceNumber() + ")"); } return; } // NOTE(gp) we expect the base layer to be always on, so we never touch // it or starve it. // XXX Refer to the implementation of // SimulcastLayer#touch(boolean, RawPacket) for an explanation of why we // chose to use a return value. boolean frameStarted = acceptedLayer.touch(pkt); if (frameStarted) simulcastLayerFrameStarted(acceptedLayer, pkt, layers); }
/** {@inheritDoc} */ @Override public RawPacket reverseTransform(RawPacket pkt) { byte[] buf = pkt.getBuffer(); int off = pkt.getOffset(); int len = pkt.getLength(); if (isDtlsRecord(buf, off, len)) { if (rtcpmux && Component.RTCP == componentID) { // This should never happen. logger.warn( "Dropping a DTLS record, because it was received on the" + " RTCP channel while rtcpmux is in use."); return null; } boolean receive; synchronized (this) { if (datagramTransport == null) { receive = false; } else { datagramTransport.queueReceive(buf, off, len); receive = true; } } if (receive) { DTLSTransport dtlsTransport = this.dtlsTransport; if (dtlsTransport == null) { // The specified pkt looks like a DTLS record and it has // been consumed for the purposes of the secure channel // represented by this PacketTransformer. pkt = null; } else { try { int receiveLimit = dtlsTransport.getReceiveLimit(); int delta = receiveLimit - len; if (delta > 0) { pkt.grow(delta); buf = pkt.getBuffer(); off = pkt.getOffset(); len = pkt.getLength(); } else if (delta < 0) { pkt.shrink(-delta); buf = pkt.getBuffer(); off = pkt.getOffset(); len = pkt.getLength(); } int received = dtlsTransport.receive(buf, off, len, DTLS_TRANSPORT_RECEIVE_WAITMILLIS); if (received <= 0) { // No application data was decoded. pkt = null; } else { delta = len - received; if (delta > 0) pkt.shrink(delta); } } catch (IOException ioe) { pkt = null; // 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 && !tlsPeerHasRaisedCloseNotifyWarning) { logger.error("Failed to decode a DTLS record!", ioe); } } } } else { // The specified pkt looks like a DTLS record but it is // unexpected in the current state of the secure channel // represented by this PacketTransformer. This PacketTransformer // has not been started (successfully) or has been closed. pkt = null; } } else if (transformEngine.isSrtpDisabled()) { // In pure DTLS mode only DTLS records pass through. pkt = null; } else { // DTLS-SRTP has not been initialized yet or has failed to // initialize. SinglePacketTransformer srtpTransformer = waitInitializeAndGetSRTPTransformer(); if (srtpTransformer != null) pkt = srtpTransformer.reverseTransform(pkt); else if (DROP_UNENCRYPTED_PKTS) pkt = null; // XXX Else, it is our explicit policy to let the received packet // pass through and rely on the SrtpListener to notify the user that // the session is not secured. } return pkt; }