private void expireLoop() { while (enabled) { // Sleep try { synchronized (sleepLock) { sleepLock.wait(POLL_INTERVAL); } } catch (InterruptedException e) { Thread.currentThread().interrupt(); } if (!enabled) break; // Loop over conferences for (JitsiMeetConference conference : new ArrayList<JitsiMeetConference>(conferences.values())) { long idleStamp = conference.getIdleTimestamp(); // Is active ? if (idleStamp == -1) { continue; } if (System.currentTimeMillis() - idleStamp > timeout) { logger.info("Focus idle timeout for " + conference.getRoomName()); conference.stop(); } } } }
@Override public void run() { synchronized (RESTReservations.this) { Iterator<Conference> conferenceIterator = conferenceMap.values().iterator(); while (conferenceIterator.hasNext()) { Conference conference = conferenceIterator.next(); Date startTimeDate = conference.getStartTime(); if (startTimeDate == null) { logger.error("No 'start_time' for conference: " + conference.getName()); continue; } long startTime = startTimeDate.getTime(); long duration = conference.getDuration(); // Convert duration to millis duration = duration * 1000L; long now = System.currentTimeMillis(); if (now - startTime > duration - EXPIRE_INTERVAL) { // Destroy the conference String mucRoomName = conference.getMucRoomName(); deleteConference(conference.getId()); conferenceIterator.remove(); focusManager.destroyConference(mucRoomName, "Scheduled conference duration exceeded."); } } } }
/** * Removes receiver and sender feedback from RTCP packets. * * @param inPacket the <tt>RTCPCompoundPacket</tt> to filter. * @return the filtered <tt>RawPacket</tt>. */ public RawPacket gateway(RTCPCompoundPacket inPacket) { if (inPacket == null || inPacket.packets == null || inPacket.packets.length == 0) { logger.info("Ignoring empty RTCP packet."); return null; } ArrayList<RTCPPacket> outPackets = new ArrayList<RTCPPacket>(inPacket.packets.length); for (RTCPPacket p : inPacket.packets) { switch (p.type) { case RTCPPacket.RR: case RTCPPacket.SR: case RTCPPacket.SDES: // We generate our own RR/SR/SDES packets. We only want // to forward NACKs/PLIs/etc. break; case RTCPFBPacket.PSFB: RTCPFBPacket psfb = (RTCPFBPacket) p; switch (psfb.fmt) { case RTCPREMBPacket.FMT: // We generate its own REMB packets. break; default: // We let through everything else, like NACK // packets. outPackets.add(psfb); break; } break; default: // We let through everything else, like BYE and APP // packets. outPackets.add(p); break; } } if (outPackets.size() == 0) { return null; } // We have feedback messages to send. Pack them in a compound // RR and send them. TODO Use RFC5506 Reduced-Size RTCP, if the // receiver supports it. Collection<RTCPRRPacket> rrPackets = makeRTCPRRPackets(System.currentTimeMillis()); if (rrPackets != null && rrPackets.size() != 0) { outPackets.addAll(0, rrPackets); } else { logger.warn("We might be sending invalid RTCPs."); } RTCPPacket[] pkts = outPackets.toArray(new RTCPPacket[outPackets.size()]); RTCPCompoundPacket outPacket = new RTCPCompoundPacket(pkts); return generator.apply(outPacket); }
/** * Implements {@link ActiveSpeakerChangedListener#activeSpeakerChanged(long)}. Notifies this * <tt>RecorderRtpImpl</tt> that the audio <tt>ReceiveStream</tt> considered active has changed, * and that the new active stream has SSRC <tt>ssrc</tt>. * * @param ssrc the SSRC of the new active stream. */ @Override public void activeSpeakerChanged(long ssrc) { if (eventHandler != null) { RecorderEvent e = new RecorderEvent(); e.setAudioSsrc(ssrc); // TODO: how do we time this? e.setInstant(System.currentTimeMillis()); e.setType(RecorderEvent.Type.SPEAKER_CHANGED); e.setMediaType(MediaType.VIDEO); eventHandler.handleEvent(e); } }
/** * Adds an RTCP packet to this instance. Time mappings are extracted and used by this instance. * * @param pkt the packet to add. */ void addRTCPPacket(RawPacket pkt) { addRTCPPacket(pkt, System.currentTimeMillis()); }
/** * Implements {@link ControllerListener#controllerUpdate(ControllerEvent)}. Handles events from * the <tt>Processor</tt>s that this instance uses to transcode media. * * @param ev the event to handle. */ public void controllerUpdate(ControllerEvent ev) { if (ev == null || ev.getSourceController() == null) { return; } Processor processor = (Processor) ev.getSourceController(); ReceiveStreamDesc desc = findReceiveStream(processor); if (desc == null) { logger.warn("Event from an orphaned processor, ignoring: " + ev); return; } if (ev instanceof ConfigureCompleteEvent) { if (logger.isInfoEnabled()) { logger.info( "Configured processor for ReceiveStream ssrc=" + desc.ssrc + " (" + desc.format + ")" + " " + System.currentTimeMillis()); } boolean audio = desc.format instanceof AudioFormat; if (audio) { ContentDescriptor cd = processor.setContentDescriptor(AUDIO_CONTENT_DESCRIPTOR); if (!AUDIO_CONTENT_DESCRIPTOR.equals(cd)) { logger.error( "Failed to set the Processor content " + "descriptor to " + AUDIO_CONTENT_DESCRIPTOR + ". Actual result: " + cd); removeReceiveStream(desc, false); return; } } for (TrackControl track : processor.getTrackControls()) { Format trackFormat = track.getFormat(); if (audio) { final long ssrc = desc.ssrc; SilenceEffect silenceEffect; if (Constants.OPUS_RTP.equals(desc.format.getEncoding())) { silenceEffect = new SilenceEffect(48000); } else { // We haven't tested that the RTP timestamps survive // the journey through the chain when codecs other than // opus are in use, so for the moment we rely on FMJ's // timestamps for non-opus formats. silenceEffect = new SilenceEffect(); } silenceEffect.setListener( new SilenceEffect.Listener() { boolean first = true; @Override public void onSilenceNotInserted(long timestamp) { if (first) { first = false; // send event only audioRecordingStarted(ssrc, timestamp); } else { // change file and send event resetRecording(ssrc, timestamp); } } }); desc.silenceEffect = silenceEffect; AudioLevelEffect audioLevelEffect = new AudioLevelEffect(); audioLevelEffect.setAudioLevelListener( new SimpleAudioLevelListener() { @Override public void audioLevelChanged(int level) { activeSpeakerDetector.levelChanged(ssrc, level); } }); try { // We add an effect, which will insert "silence" in // place of lost packets. track.setCodecChain(new Codec[] {silenceEffect, audioLevelEffect}); } catch (UnsupportedPlugInException upie) { logger.warn("Failed to insert silence effect: " + upie); // But do go on, a recording without extra silence is // better than nothing ;) } } else { // transcode vp8/rtp to vp8 (i.e. depacketize vp8) if (trackFormat.matches(vp8RtpFormat)) track.setFormat(vp8Format); else { logger.error("Unsupported track format: " + trackFormat + " for ssrc=" + desc.ssrc); // we currently only support vp8 removeReceiveStream(desc, false); return; } } } processor.realize(); } else if (ev instanceof RealizeCompleteEvent) { desc.dataSource = processor.getDataOutput(); long ssrc = desc.ssrc; boolean audio = desc.format instanceof AudioFormat; String suffix = audio ? AUDIO_FILENAME_SUFFIX : VIDEO_FILENAME_SUFFIX; // XXX '\' on windows? String filename = getNextFilename(path + "/" + ssrc, suffix); desc.filename = filename; DataSink dataSink; if (audio) { try { dataSink = Manager.createDataSink(desc.dataSource, new MediaLocator("file:" + filename)); } catch (NoDataSinkException ndse) { logger.error("Could not create DataSink: " + ndse); removeReceiveStream(desc, false); return; } } else { dataSink = new WebmDataSink(filename, desc.dataSource); } if (logger.isInfoEnabled()) logger.info( "Created DataSink (" + dataSink + ") for SSRC=" + ssrc + ". Output filename: " + filename); try { dataSink.open(); } catch (IOException e) { logger.error("Failed to open DataSink (" + dataSink + ") for" + " SSRC=" + ssrc + ": " + e); removeReceiveStream(desc, false); return; } if (!audio) { final WebmDataSink webmDataSink = (WebmDataSink) dataSink; webmDataSink.setSsrc(ssrc); webmDataSink.setEventHandler(eventHandler); webmDataSink.setKeyFrameControl( new KeyFrameControlAdapter() { @Override public boolean requestKeyFrame(boolean urgent) { return requestFIR(webmDataSink); } }); } try { dataSink.start(); } catch (IOException e) { logger.error( "Failed to start DataSink (" + dataSink + ") for" + " SSRC=" + ssrc + ". " + e); removeReceiveStream(desc, false); return; } if (logger.isInfoEnabled()) logger.info("Started DataSink for SSRC=" + ssrc); desc.dataSink = dataSink; processor.start(); } else if (logger.isDebugEnabled()) { logger.debug( "Unhandled ControllerEvent from the Processor for ssrc=" + desc.ssrc + ": " + ev); } }
/** * Ctor. * * @param ssrc * @param remoteTime * @param rtpTimestamp * @param frequencyHz */ ReceivedRemoteClock(int ssrc, long remoteTime, int rtpTimestamp, int frequencyHz) { this.ssrc = ssrc; this.remoteClock = new RemoteClock(remoteTime, rtpTimestamp); this.frequencyHz = frequencyHz; this.receivedTime = System.currentTimeMillis(); }
/** {@inheritDoc} */ @Override public RawPacket report() { garbageCollector.cleanup(); // TODO Compound RTCP packets should not exceed the MTU of the network // path. // // An individual RTP participant should send only one compound RTCP // packet per report interval in order for the RTCP bandwidth per // participant to be estimated correctly, except when the compound // RTCP packet is split for partial encryption. // // If there are too many sources to fit all the necessary RR packets // into one compound RTCP packet without exceeding the maximum // transmission unit (MTU) of the network path, then only the subset // that will fit into one MTU should be included in each interval. The // subsets should be selected round-robin across multiple intervals so // that all sources are reported. // // It is impossible to know in advance what the MTU of path will be. // There are various algorithms for experimenting to find out, but many // devices do not properly implement (or deliberately ignore) the // necessary standards so it all comes down to trial and error. For that // reason, we can just guess 1200 or 1500 bytes per message. long time = System.currentTimeMillis(); Collection<RTCPPacket> packets = new ArrayList<RTCPPacket>(); // First, we build the RRs. Collection<RTCPRRPacket> rrPackets = makeRTCPRRPackets(time); if (rrPackets != null && rrPackets.size() != 0) { packets.addAll(rrPackets); } // Next, we build the SRs. Collection<RTCPSRPacket> srPackets = makeRTCPSRPackets(time); if (srPackets != null && srPackets.size() != 0) { packets.addAll(srPackets); } // Bail out if we have nothing to report. if (packets.size() == 0) { return null; } // Next, we build the REMB. RTCPREMBPacket rembPacket = makeRTCPREMBPacket(); if (rembPacket != null) { packets.add(rembPacket); } // Finally, we add an SDES packet. RTCPSDESPacket sdesPacket = makeSDESPacket(); if (sdesPacket != null) { packets.add(sdesPacket); } // Prepare the <tt>RTCPCompoundPacket</tt> to return. RTCPPacket rtcpPackets[] = packets.toArray(new RTCPPacket[packets.size()]); RTCPCompoundPacket cp = new RTCPCompoundPacket(rtcpPackets); // Build the <tt>RTCPCompoundPacket</tt> and return the // <tt>RawPacket</tt> to inject to the <tt>MediaStream</tt>. return generator.apply(cp); }