public synchronized boolean waitForState(int state) {
      switch (state) {
        case Processor.Configured:
          p.configure();
          break;
        case Controller.Realized:
          p.realize();
          break;
        case Controller.Prefetched:
          p.prefetch();
          break;
        case Controller.Started:
          p.start();
          break;
      }

      while (p.getState() < state && !error) {
        try {
          wait(1000);
        } catch (Exception e) {
        }
      }
      // p.removeControllerListener(this);
      return !(error);
    }
Ejemplo n.º 2
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  private synchronized boolean waitForState(Processor p, int state) {
    p.addControllerListener(new StateListener());
    failed = false;

    // Call the required method on the processor
    if (state == Processor.Configured) {
      p.configure();
    } else if (state == Processor.Realized) {
      p.realize();
    }

    // Wait until we get an event that confirms the
    // success of the method, or a failure event.
    // See StateListener inner class
    while (p.getState() < state && !failed) {
      synchronized (getStateLock()) {
        try {
          getStateLock().wait();
        } catch (InterruptedException ie) {
          return false;
        }
      }
    }

    if (failed) return false;
    else return true;
  }
Ejemplo n.º 3
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 /** Stops the transmission if already started */
 public void stop() {
   synchronized (this) {
     if (processor != null) {
       processor.stop();
       processor.close();
       processor = null;
       rtptransmitter.close();
       rtptransmitter = null;
     }
   }
 }
  /** With the given processor info generated from matchTracks, build each of the processors. */
  public boolean buildTracks(ProcInfo pInfo[]) {
    ContentDescriptor cd = new ContentDescriptor(ContentDescriptor.RAW);
    Processor p;

    for (int i = 0; i < pInfo.length; i++) {
      p = pInfo[i].p;
      p.setContentDescriptor(cd);

      // We are done with programming the processor. Let's just
      // realize the it.
      if (!waitForState(p, Controller.Realized)) {
        System.err.println("- Failed to realize the processor.");
        return false;
      }

      // Set the JPEG quality to .5.
      setJPEGQuality(p, 0.5f);

      PushBufferStream pbs[];
      TrackInfo tInfo;
      int trackID;

      // Cheating. I should have checked the type of DataSource
      // returned.
      pInfo[i].ds = (PushBufferDataSource) p.getDataOutput();
      pbs = pInfo[i].ds.getStreams();

      // Find the matching data stream for the given track for audio.

      for (int type = AUDIO; type < MEDIA_TYPES; type++) {
        for (trackID = 0; trackID < pInfo[i].numTracksByType[type]; trackID++) {
          tInfo = pInfo[i].tracksByType[type][trackID];
          tInfo.pbs = pbs[tInfo.idx];
        }
      }
    }

    return true;
  }
Ejemplo n.º 5
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  /**
   * Starts the transmission. Returns null if transmission started ok. Otherwise it returns a string
   * with the reason why the setup failed.
   */
  public synchronized String start() {
    String result;

    // Create a processor for the specified media locator
    // and program it to output JPEG/RTP
    result = createProcessor();
    if (result != null) return result;

    // Create an RTP session to transmit the output of the
    // processor to the specified IP address and port no.
    result = createTransmitter();
    if (result != null) {
      processor.close();
      processor = null;
      return result;
    }

    // Start the transmission
    processor.start();

    return null;
  }
  /** Create the DataSink. */
  DataSink createDataSink(Processor p, MediaLocator outML) {
    DataSource ds;

    if ((ds = p.getDataOutput()) == null) {
      System.err.println(
          "Something is really wrong: the processor does not have an output DataSource");
      return null;
    }

    DataSink dsink;

    try {
      System.err.println("- Create DataSink for: " + outML);
      dsink = Manager.createDataSink(ds, outML);
      dsink.open();
    } catch (Exception e) {
      System.err.println("Cannot create the DataSink: " + e);
      return null;
    }

    return dsink;
  }
 StateWaiter(Processor p) {
   this.p = p;
   p.addControllerListener(this);
 }
  /**
   * Given an array of input media locators and an output locator, this method will concatenate the
   * input media files to generate a single concatentated output.
   */
  public boolean doIt(MediaLocator inML[], MediaLocator outML) {
    // Guess the output content descriptor from the file extension.
    ContentDescriptor cd;

    if ((cd = fileExtToCD(outML.getRemainder())) == null) {
      System.err.println("Couldn't figure out from the file extension the type of output needed!");
      return false;
    }

    // Build the ProcInfo data structure for each processor.
    ProcInfo pInfo[] = new ProcInfo[inML.length];

    for (int i = 0; i < inML.length; i++) {
      pInfo[i] = new ProcInfo();
      pInfo[i].ml = inML[i];

      try {
        System.err.println("- Create processor for: " + inML[i]);
        pInfo[i].p = Manager.createProcessor(inML[i]);
      } catch (Exception e) {
        System.err.println("Yikes!  Cannot create a processor from the given url: " + e);
        return false;
      }
    }

    // Try to match the tracks from different processors.
    if (!matchTracks(pInfo, cd)) {
      System.err.println("Failed to match the tracks.");
      return false;
    }

    // Program each processors to perform the necessary transcoding
    // to concatenate the tracks.
    if (!buildTracks(pInfo)) {
      System.err.println("Failed to build processors for the inputs.");
      return false;
    }

    // Generate a super glue data source from the processors.
    SuperGlueDataSource ds = new SuperGlueDataSource(pInfo);

    // Create the processor to generate the final output.
    Processor p;
    try {
      p = Manager.createProcessor(ds);
    } catch (Exception e) {
      System.err.println("Failed to create a processor to concatenate the inputs.");
      return false;
    }

    p.addControllerListener(this);

    // Put the Processor into configured state.
    if (!waitForState(p, Processor.Configured)) {
      System.err.println("Failed to configure the processor.");
      return false;
    }

    // Set the output content descriptor on the final processor.
    System.err.println("- Set output content descriptor to: " + cd);
    if ((p.setContentDescriptor(cd)) == null) {
      System.err.println("Failed to set the output content descriptor on the processor.");
      return false;
    }

    // We are done with programming the processor. Let's just
    // realize it.
    if (!waitForState(p, Controller.Realized)) {
      System.err.println("Failed to realize the processor.");
      return false;
    }

    // Now, we'll need to create a DataSink.
    DataSink dsink;
    if ((dsink = createDataSink(p, outML)) == null) {
      System.err.println("Failed to create a DataSink for the given output MediaLocator: " + outML);
      return false;
    }

    dsink.addDataSinkListener(this);
    fileDone = false;

    System.err.println("- Start concatenation...");

    // OK, we can now start the actual concatenation.
    try {
      p.start();
      dsink.start();
    } catch (IOException e) {
      System.err.println("IO error during concatenation");
      return false;
    }

    // Wait for EndOfStream event.
    waitForFileDone();

    // Cleanup.
    try {
      dsink.close();
    } catch (Exception e) {
    }
    p.removeControllerListener(this);

    System.err.println("  ...done concatenation.");

    return true;
  }
Ejemplo n.º 9
0
  private String createProcessor() {
    if (locator == null) return "Locator is null";

    DataSource ds;
    DataSource clone;

    try {
      ds = Manager.createDataSource(locator);
    } catch (Exception e) {
      return "Couldn't create DataSource";
    }

    // Try to create a processor to handle the input media locator
    try {
      processor = Manager.createProcessor(ds);
    } catch (NoProcessorException npe) {
      return "Couldn't create processor";
    } catch (IOException ioe) {
      return "IOException creating processor";
    }

    // Wait for it to configure
    boolean result = waitForState(processor, Processor.Configured);
    if (result == false) return "Couldn't configure processor";

    // Get the tracks from the processor
    TrackControl[] tracks = processor.getTrackControls();

    // Do we have atleast one track?
    if (tracks == null || tracks.length < 1) return "Couldn't find tracks in processor";

    boolean programmed = false;

    // Search through the tracks for a video track
    for (int i = 0; i < tracks.length; i++) {
      Format format = tracks[i].getFormat();
      if (tracks[i].isEnabled() && format instanceof VideoFormat && !programmed) {

        // Found a video track. Try to program it to output JPEG/RTP
        // Make sure the sizes are multiple of 8's.
        Dimension size = ((VideoFormat) format).getSize();
        float frameRate = ((VideoFormat) format).getFrameRate();
        int w = (size.width % 8 == 0 ? size.width : (int) (size.width / 8) * 8);
        int h = (size.height % 8 == 0 ? size.height : (int) (size.height / 8) * 8);
        VideoFormat jpegFormat =
            new VideoFormat(
                VideoFormat.JPEG_RTP,
                new Dimension(w, h),
                Format.NOT_SPECIFIED,
                Format.byteArray,
                frameRate);
        tracks[i].setFormat(jpegFormat);
        System.err.println("Video transmitted as:");
        System.err.println("  " + jpegFormat);
        // Assume succesful
        programmed = true;
      } else tracks[i].setEnabled(false);
    }

    if (!programmed) return "Couldn't find video track";

    // Set the output content descriptor to RAW_RTP
    ContentDescriptor cd = new ContentDescriptor(ContentDescriptor.RAW_RTP);
    processor.setContentDescriptor(cd);

    // Realize the processor. This will internally create a flow
    // graph and attempt to create an output datasource for JPEG/RTP
    // video frames.
    result = waitForState(processor, Controller.Realized);
    if (result == false) return "Couldn't realize processor";

    // Set the JPEG quality to .5.
    setJPEGQuality(processor, 0.5f);

    // Get the output data source of the processor
    dataOutput = processor.getDataOutput();
    return null;
  }