/** * Function called when an audio device is plugged or unplugged. * * @param event The property change event which may concern the audio device. */ public void propertyChange(PropertyChangeEvent event) { if (DeviceConfiguration.PROP_AUDIO_SYSTEM_DEVICES.equals(event.getPropertyName())) { NotificationService notificationService = getNotificationService(); if (notificationService != null) { // Registers only once to the popup message notification // handler. if (!isRegisteredToPopupMessageListener) { isRegisteredToPopupMessageListener = true; managePopupMessageListenerRegistration(true); } // Fires the popup notification. ResourceManagementService resources = NeomediaActivator.getResources(); Map<String, Object> extras = new HashMap<String, Object>(); extras.put(NotificationData.POPUP_MESSAGE_HANDLER_TAG_EXTRA, this); notificationService.fireNotification( DEVICE_CONFIGURATION_HAS_CHANGED, resources.getI18NString("impl.media.configform" + ".AUDIO_DEVICE_CONFIG_CHANGED"), resources.getI18NString( "impl.media.configform" + ".AUDIO_DEVICE_CONFIG_MANAGMENT_CLICK"), null, extras); } } }
/** * Returns the sequence number to use for a specific RTX packet, which is based on the packet's * original sequence number. * * <p>Because we terminate the RTX format, and with simulcast we might translate RTX packets from * multiple SSRCs into the same SSRC, we keep count of the RTX packets (and their sequence * numbers) which we sent for each SSRC. * * @param ssrc the SSRC of the RTX stream for the packet. * @param defaultSeq the default sequence number to use in case we don't (yet) have any * information about <tt>ssrc</tt>. * @return the sequence number which should be used for the next RTX packet sent using SSRC * <tt>ssrc</tt>. */ private int getNextRtxSequenceNumber(long ssrc, int defaultSeq) { Integer seq; synchronized (rtxSequenceNumbers) { seq = rtxSequenceNumbers.get(ssrc); if (seq == null) seq = defaultSeq; else seq++; rtxSequenceNumbers.put(ssrc, seq); } return seq; }
/** * Returns the sequence number to use for a specific RTX packet, which is based on the packet's * original sequence number. * * <p>Because we terminate the RTX format, and with simulcast we might translate RTX packets from * multiple SSRCs into the same SSRC, we keep count of the RTX packets (and their sequence * numbers) which we sent for each SSRC. * * @param ssrc the SSRC of the RTX stream for the packet. * @return the sequence number which should be used for the next RTX packet sent using SSRC * <tt>ssrc</tt>. */ private int getNextRtxSequenceNumber(long ssrc) { Integer seq; synchronized (rtxSequenceNumbers) { seq = rtxSequenceNumbers.get(ssrc); if (seq == null) seq = new Random().nextInt(0xffff); else seq++; rtxSequenceNumbers.put(ssrc, seq); } return seq; }
/** * Returns, the <tt>TransportManager</tt> instance for the channel-bundle with ID * <tt>channelBundleId</tt>. If no instance exists and <tt>create</tt> is <tt>true</tt>, one will * be created. * * @param channelBundleId the ID of the channel-bundle for which to return the * <tt>TransportManager</tt>. * @param create whether to create a new instance, if one doesn't exist. * @return the <tt>TransportManager</tt> instance for the channel-bundle with ID * <tt>channelBundleId</tt>. */ IceUdpTransportManager getTransportManager(String channelBundleId, boolean create) { IceUdpTransportManager transportManager; synchronized (transportManagers) { transportManager = transportManagers.get(channelBundleId); if (transportManager == null && create && !isExpired()) { try { // FIXME: the initiator is hard-coded // We assume rtcp-mux when bundle is used, so we make only // one component. transportManager = new IceUdpTransportManager(this, true, 1); } catch (IOException ioe) { throw new UndeclaredThrowableException(ioe); } transportManagers.put(channelBundleId, transportManager); } } return transportManager; }
/** * Opens new WebRTC data channel using specified parameters. * * @param type channel type as defined in control protocol description. Use 0 for "reliable". * @param prio channel priority. The higher the number, the lower the priority. * @param reliab Reliability Parameter<br> * This field is ignored if a reliable channel is used. If a partial reliable channel with * limited number of retransmissions is used, this field specifies the number of * retransmissions. If a partial reliable channel with limited lifetime is used, this field * specifies the maximum lifetime in milliseconds. The following table summarizes this:<br> * </br> * <p>+------------------------------------------------+------------------+ | Channel Type | * Reliability | | | Parameter | * +------------------------------------------------+------------------+ | * DATA_CHANNEL_RELIABLE | Ignored | | DATA_CHANNEL_RELIABLE_UNORDERED | Ignored | | * DATA_CHANNEL_PARTIAL_RELIABLE_REXMIT | Number of RTX | | * DATA_CHANNEL_PARTIAL_RELIABLE_REXMIT_UNORDERED | Number of RTX | | * DATA_CHANNEL_PARTIAL_RELIABLE_TIMED | Lifetime in ms | | * DATA_CHANNEL_PARTIAL_RELIABLE_TIMED_UNORDERED | Lifetime in ms | * +------------------------------------------------+------------------+ * @param sid SCTP stream id that will be used by new channel (it must not be already used). * @param label text label for the channel. * @return new instance of <tt>WebRtcDataStream</tt> that represents opened WebRTC data channel. * @throws IOException if IO error occurs. */ public synchronized WebRtcDataStream openChannel( int type, int prio, long reliab, int sid, String label) throws IOException { if (channels.containsKey(sid)) { throw new IOException("Channel on sid: " + sid + " already exists"); } // Label Length & Label byte[] labelBytes; int labelByteLength; if (label == null) { labelBytes = null; labelByteLength = 0; } else { labelBytes = label.getBytes("UTF-8"); labelByteLength = labelBytes.length; if (labelByteLength > 0xFFFF) labelByteLength = 0xFFFF; } // Protocol Length & Protocol String protocol = WEBRTC_DATA_CHANNEL_PROTOCOL; byte[] protocolBytes; int protocolByteLength; if (protocol == null) { protocolBytes = null; protocolByteLength = 0; } else { protocolBytes = protocol.getBytes("UTF-8"); protocolByteLength = protocolBytes.length; if (protocolByteLength > 0xFFFF) protocolByteLength = 0xFFFF; } ByteBuffer packet = ByteBuffer.allocate(12 + labelByteLength + protocolByteLength); // Message open new channel on current sid // Message Type packet.put((byte) MSG_OPEN_CHANNEL); // Channel Type packet.put((byte) type); // Priority packet.putShort((short) prio); // Reliability Parameter packet.putInt((int) reliab); // Label Length packet.putShort((short) labelByteLength); // Protocol Length packet.putShort((short) protocolByteLength); // Label if (labelByteLength != 0) { packet.put(labelBytes, 0, labelByteLength); } // Protocol if (protocolByteLength != 0) { packet.put(protocolBytes, 0, protocolByteLength); } int sentCount = sctpSocket.send(packet.array(), true, sid, WEB_RTC_PPID_CTRL); if (sentCount != packet.capacity()) { throw new IOException("Failed to open new chanel on sid: " + sid); } WebRtcDataStream channel = new WebRtcDataStream(sctpSocket, sid, label, false); channels.put(sid, channel); return channel; }
/** * Handles control packet. * * @param data raw packet data that arrived on control PPID. * @param sid SCTP stream id on which the data has arrived. */ private synchronized void onCtrlPacket(byte[] data, int sid) throws IOException { ByteBuffer buffer = ByteBuffer.wrap(data); int messageType = /* 1 byte unsigned integer */ 0xFF & buffer.get(); if (messageType == MSG_CHANNEL_ACK) { if (logger.isDebugEnabled()) { logger.debug(getEndpoint().getID() + " ACK received SID: " + sid); } // Open channel ACK WebRtcDataStream channel = channels.get(sid); if (channel != null) { // Ack check prevents from firing multiple notifications // if we get more than one ACKs (by mistake/bug). if (!channel.isAcknowledged()) { channel.ackReceived(); notifyChannelOpened(channel); } else { logger.warn("Redundant ACK received for SID: " + sid); } } else { logger.error("No channel exists on sid: " + sid); } } else if (messageType == MSG_OPEN_CHANNEL) { int channelType = /* 1 byte unsigned integer */ 0xFF & buffer.get(); int priority = /* 2 bytes unsigned integer */ 0xFFFF & buffer.getShort(); long reliability = /* 4 bytes unsigned integer */ 0xFFFFFFFFL & buffer.getInt(); int labelLength = /* 2 bytes unsigned integer */ 0xFFFF & buffer.getShort(); int protocolLength = /* 2 bytes unsigned integer */ 0xFFFF & buffer.getShort(); String label; String protocol; if (labelLength == 0) { label = ""; } else { byte[] labelBytes = new byte[labelLength]; buffer.get(labelBytes); label = new String(labelBytes, "UTF-8"); } if (protocolLength == 0) { protocol = ""; } else { byte[] protocolBytes = new byte[protocolLength]; buffer.get(protocolBytes); protocol = new String(protocolBytes, "UTF-8"); } if (logger.isDebugEnabled()) { logger.debug( "!!! " + getEndpoint().getID() + " data channel open request on SID: " + sid + " type: " + channelType + " prio: " + priority + " reliab: " + reliability + " label: " + label + " proto: " + protocol); } if (channels.containsKey(sid)) { logger.error("Channel on sid: " + sid + " already exists"); } WebRtcDataStream newChannel = new WebRtcDataStream(sctpSocket, sid, label, true); channels.put(sid, newChannel); sendOpenChannelAck(sid); notifyChannelOpened(newChannel); } else { logger.error("Unexpected ctrl msg type: " + messageType); } }
/** * Inspect an <tt>RTCPCompoundPacket</tt> and build-up the state for future estimations. * * @param pkt */ public void apply(RTCPCompoundPacket pkt) { if (pkt == null || pkt.packets == null || pkt.packets.length == 0) { return; } for (RTCPPacket rtcpPacket : pkt.packets) { switch (rtcpPacket.type) { case RTCPPacket.SR: RTCPSRPacket srPacket = (RTCPSRPacket) rtcpPacket; // The media sender SSRC. int ssrc = srPacket.ssrc; // Convert 64-bit NTP timestamp to Java standard time. // Note that java time (milliseconds) by definition has // less precision then NTP time (picoseconds) so // converting NTP timestamp to java time and back to NTP // timestamp loses precision. For example, Tue, Dec 17 // 2002 09:07:24.810 EST is represented by a single // Java-based time value of f22cd1fc8a, but its NTP // equivalent are all values ranging from // c1a9ae1c.cf5c28f5 to c1a9ae1c.cf9db22c. // Use round-off on fractional part to preserve going to // lower precision long fraction = Math.round(1000D * srPacket.ntptimestamplsw / 0x100000000L); /* * If the most significant bit (MSB) on the seconds * field is set we use a different time base. The * following text is a quote from RFC-2030 (SNTP v4): * * If bit 0 is set, the UTC time is in the range * 1968-2036 and UTC time is reckoned from 0h 0m 0s UTC * on 1 January 1900. If bit 0 is not set, the time is * in the range 2036-2104 and UTC time is reckoned from * 6h 28m 16s UTC on 7 February 2036. */ long msb = srPacket.ntptimestampmsw & 0x80000000L; long remoteTime = (msb == 0) // use base: 7-Feb-2036 @ 06:28:16 UTC ? msb0baseTime + (srPacket.ntptimestampmsw * 1000) + fraction // use base: 1-Jan-1900 @ 01:00:00 UTC : msb1baseTime + (srPacket.ntptimestampmsw * 1000) + fraction; // Estimate the clock rate of the sender. int frequencyHz = -1; if (receivedClocks.containsKey(ssrc)) { // Calculate the clock rate. ReceivedRemoteClock oldStats = receivedClocks.get(ssrc); RemoteClock oldRemoteClock = oldStats.getRemoteClock(); frequencyHz = Math.round( (float) (((int) srPacket.rtptimestamp - oldRemoteClock.getRtpTimestamp()) & 0xffffffffl) / (remoteTime - oldRemoteClock.getRemoteTime())); } // Replace whatever was in there before. receivedClocks.put( ssrc, new ReceivedRemoteClock( ssrc, remoteTime, (int) srPacket.rtptimestamp, frequencyHz)); break; case RTCPPacket.SDES: break; } } }