示例#1
0
    void checkThreadInfo(ThreadInfo info) {
      if (!getName().equals(info.getThreadName())) {
        throw new RuntimeException(
            "Name: " + info.getThreadName() + " not matched. Expected: " + getName());
      }

      MonitorInfo[] monitors = info.getLockedMonitors();
      if (monitors.length != OWNED_MONITORS) {
        throw new RuntimeException(
            "Number of locked monitors = "
                + monitors.length
                + " not matched. Expected: "
                + OWNED_MONITORS);
      }
      MonitorInfo m = monitors[0];
      StackTraceElement ste = m.getLockedStackFrame();
      int depth = m.getLockedStackDepth();
      StackTraceElement[] stacktrace = info.getStackTrace();
      if (!ste.equals(stacktrace[depth])) {
        System.out.println("LockedStackFrame:- " + ste);
        System.out.println("StackTrace at " + depth + " :-" + stacktrace[depth]);
        throw new RuntimeException(
            "LockedStackFrame does not match " + "stack frame in ThreadInfo.getStackTrace");
      }

      String className = lock.getClass().getName();
      int hcode = System.identityHashCode(lock);
      if (!className.equals(m.getClassName())
          || hcode != m.getIdentityHashCode()
          || !m.getLockedStackFrame().getMethodName().equals("run")) {
        System.out.println(info);
        throw new RuntimeException("MonitorInfo " + m + " doesn't match.");
      }

      LockInfo[] syncs = info.getLockedSynchronizers();
      if (syncs.length != OWNED_SYNCS) {
        throw new RuntimeException(
            "Number of locked syncs = " + syncs.length + " not matched. Expected: " + OWNED_SYNCS);
      }
      AbstractOwnableSynchronizer s = mutex.getSync();
      String lockName = s.getClass().getName();
      hcode = System.identityHashCode(s);
      if (!lockName.equals(syncs[0].getClassName())) {
        throw new RuntimeException(
            "LockInfo : " + syncs[0] + " class name not matched. Expected: " + lockName);
      }
      if (hcode != syncs[0].getIdentityHashCode()) {
        throw new RuntimeException(
            "LockInfo: " + syncs[0] + " IdentityHashCode not matched. Expected: " + hcode);
      }
      LockInfo li = info.getLockInfo();
      if (li == null) {
        throw new RuntimeException("Expected non-null LockInfo");
      }
    }
示例#2
0
 // To be called exactly twice by the child process
 public static void rendezvousChild() {
   try {
     for (int i = 0; i < 100; i++) {
       System.gc();
       System.runFinalization();
       Thread.sleep(50);
     }
     System.out.write((byte) '\n');
     System.out.flush();
     System.in.read();
   } catch (Throwable t) {
     throw new Error(t);
   }
 }
示例#3
0
    final void test() throws Exception {
      Future[] futures = new Future[nthreads];
      for (int i = 0; i < nthreads; ++i) futures[i] = pool.submit(this);

      barrier.await();
      Thread.sleep(TIMEOUT);
      boolean tooLate = false;
      for (int i = 1; i < nthreads; ++i) {
        if (!futures[i].cancel(true)) tooLate = true;
        // Unbunch some of the cancels
        if ((i & 3) == 0) Thread.sleep(1 + rng.next() % 10);
      }

      Object f0 = futures[0].get();
      if (!tooLate) {
        for (int i = 1; i < nthreads; ++i) {
          if (!futures[i].isDone() || !futures[i].isCancelled())
            throw new Error("Only one thread should complete");
        }
      } else System.out.print("(cancelled too late) ");

      long endTime = System.nanoTime();
      long time = endTime - timer.startTime;
      if (print) {
        double secs = (double) (time) / 1000000000.0;
        System.out.println("\t " + secs + "s run time");
      }
    }
 protected boolean interpolatePath() {
   long timeNow = System.currentTimeMillis();
   PathLocAndDir locAndDir = pathState.interpolatePath(timeNow);
   long oid = obj.getOid();
   //         if (locAndDir != null) {
   //             if (Log.loggingDebug) {
   //                 Log.debug("BaseBehavior.interpolatePath: oid = " + oid + "; loc = " +
   // locAndDir.getLoc() + "; dir = " + locAndDir.getDir());
   //             }
   //         }
   //         else {
   //             if (Log.loggingDebug)
   //                 Log.debug("BaseBehavior.interpolatePath: oid = " + oid + "; locAndDir is
   // null");
   //         }
   if (locAndDir == null) {
     // We have arrived - - turn off interpolation, and cancel that path
     interpolatingPath = false;
     if (Log.loggingDebug)
       Log.debug(
           "BaseBehavior.interpolatePath: cancelling path: oid = "
               + oid
               + "; myLoc = "
               + obj.getWorldNode().getLoc());
     cancelPathInterpolator(oid);
     obj.getWorldNode().setDir(new MVVector(0, 0, 0));
   } else {
     obj.getWorldNode()
         .setPathInterpolatorValues(
             timeNow, locAndDir.getDir(), locAndDir.getLoc(), locAndDir.getOrientation());
     MobManagerPlugin.getTracker(obj.getInstanceOid()).updateEntity(obj);
   }
   return interpolatingPath;
 }
示例#5
0
 /**
  * Spins/blocks until node s is matched by a fulfill operation.
  *
  * @param s the waiting node
  * @param timed true if timed wait
  * @param nanos timeout value
  * @return matched node, or s if cancelled
  */
 SNode awaitFulfill(SNode s, boolean timed, long nanos) {
   /*
    * When a node/thread is about to block, it sets its waiter
    * field and then rechecks state at least one more time
    * before actually parking, thus covering race vs
    * fulfiller noticing that waiter is non-null so should be
    * woken.
    *
    * When invoked by nodes that appear at the point of call
    * to be at the head of the stack, calls to park are
    * preceded by spins to avoid blocking when producers and
    * consumers are arriving very close in time.  This can
    * happen enough to bother only on multiprocessors.
    *
    * The order of checks for returning out of main loop
    * reflects fact that interrupts have precedence over
    * normal returns, which have precedence over
    * timeouts. (So, on timeout, one last check for match is
    * done before giving up.) Except that calls from untimed
    * SynchronousQueue.{poll/offer} don't check interrupts
    * and don't wait at all, so are trapped in transfer
    * method rather than calling awaitFulfill.
    */
   long lastTime = timed ? System.nanoTime() : 0;
   Thread w = Thread.currentThread();
   SNode h = head;
   int spins = (shouldSpin(s) ? (timed ? maxTimedSpins : maxUntimedSpins) : 0);
   for (; ; ) {
     if (w.isInterrupted()) s.tryCancel();
     SNode m = s.match;
     if (m != null) return m;
     if (timed) {
       long now = System.nanoTime();
       nanos -= now - lastTime;
       lastTime = now;
       if (nanos <= 0) {
         s.tryCancel();
         continue;
       }
     }
     if (spins > 0) spins = shouldSpin(s) ? (spins - 1) : 0;
     else if (s.waiter == null) s.waiter = w; // establish waiter so can park next iter
     else if (!timed) LockSupport.park(this);
     else if (nanos > spinForTimeoutThreshold) LockSupport.parkNanos(this, nanos);
   }
 }
示例#6
0
 /** Initializes a random variable */
 private void createRandom() {
   this.random =
       new Random(
           System.currentTimeMillis()
               + Thread.currentThread().getId()
               - Thread.currentThread().hashCode()
               + this.cname.hashCode());
 }
示例#7
0
    public static void main(String[] args) throws Throwable {
      final ReentrantLock lock = new ReentrantLock();
      lock.lock();

      final ReentrantReadWriteLock rwlock = new ReentrantReadWriteLock();
      final ReentrantReadWriteLock.ReadLock readLock = rwlock.readLock();
      final ReentrantReadWriteLock.WriteLock writeLock = rwlock.writeLock();
      rwlock.writeLock().lock();

      final BlockingQueue<Object> q = new LinkedBlockingQueue<Object>();
      final Semaphore fairSem = new Semaphore(0, true);
      final Semaphore unfairSem = new Semaphore(0, false);
      // final int threads =
      // rnd.nextInt(Runtime.getRuntime().availableProcessors() + 1) + 1;
      final int threads = 3;
      // On Linux, this test runs very slowly for some reason,
      // so use a smaller number of iterations.
      // Solaris can handle 1 << 18.
      // On the other hand, jmap is much slower on Solaris...
      final int iterations = 1 << 8;
      final CyclicBarrier cb = new CyclicBarrier(threads + 1);

      for (int i = 0; i < threads; i++)
        new Thread() {
          public void run() {
            try {
              final Random rnd = new Random();
              for (int j = 0; j < iterations; j++) {
                if (j == iterations / 10 || j == iterations - 1) {
                  cb.await(); // Quiesce
                  cb.await(); // Resume
                }
                // int t = rnd.nextInt(2000);
                int t = rnd.nextInt(900);
                check(!lock.tryLock(t, NANOSECONDS));
                check(!readLock.tryLock(t, NANOSECONDS));
                check(!writeLock.tryLock(t, NANOSECONDS));
                equal(null, q.poll(t, NANOSECONDS));
                check(!fairSem.tryAcquire(t, NANOSECONDS));
                check(!unfairSem.tryAcquire(t, NANOSECONDS));
              }
            } catch (Throwable t) {
              unexpected(t);
            }
          }
        }.start();

      cb.await(); // Quiesce
      rendezvousChild(); // Measure
      cb.await(); // Resume

      cb.await(); // Quiesce
      rendezvousChild(); // Measure
      cb.await(); // Resume

      System.exit(failed);
    }
 private boolean discardAvailableConnections(long timeout, TimeUnit unit)
     throws InterruptedException {
   long start = System.nanoTime();
   boolean success = true;
   for (Connection connection : connections) {
     success &= connection.close(timeout - Cluster.timeSince(start, unit), unit);
     open.decrementAndGet();
   }
   return success;
 }
示例#9
0
文件: Manager.java 项目: JCortz/SD
 public void saveManager() throws FileNotFoundException, IOException {
   String workingDir = System.getProperty("user.dir");
   FileOutputStream fos = new FileOutputStream(workingDir + "\\Manager.ser");
   ObjectOutputStream oos = new ObjectOutputStream(fos);
   try {
     oos.writeObject(this);
     oos.close();
   } catch (IOException e) {
     System.out.println("\nerror saving file!\n");
   }
 }
示例#10
0
  protected static Object[] extractMockArguments(Object[] args) {
    int i = 7;

    if (args.length > i) {
      Object[] mockArgs = new Object[args.length - i];
      System.arraycopy(args, i, mockArgs, 0, mockArgs.length);
      return mockArgs;
    }

    return EMPTY_ARGS;
  }
示例#11
0
文件: Manager.java 项目: JCortz/SD
 public Manager loadManager() throws IOException, ClassNotFoundException {
   try {
     String workingDir = System.getProperty("user.dir");
     FileInputStream fin = new FileInputStream(workingDir + "\\Manager.ser");
     ObjectInputStream oin = new ObjectInputStream(fin);
     Manager m = (Manager) oin.readObject();
     if (m != null) return m;
     else return new Manager(new Warehouse());
   } catch (IOException e) {
     System.out.println("\nerror loading file!\n");
     return new Manager(new Warehouse());
   }
 }
示例#12
0
 @Override
 public void close() throws BlockStoreException {
   try {
     buffer.force();
     if (System.getProperty("os.name").toLowerCase().contains("win")) {
       log.info("Windows mmap hack: Forcing buffer cleaning");
       WindowsMMapHack.forceRelease(buffer);
     }
     buffer = null; // Allow it to be GCd and the underlying file mapping to go away.
     randomAccessFile.close();
   } catch (IOException e) {
     throw new BlockStoreException(e);
   }
 }
示例#13
0
  static void realMain(String[] args) throws Throwable {
    // jmap doesn't work on Windows
    if (System.getProperty("os.name").startsWith("Windows")) return;

    final String childClassName = Job.class.getName();
    final String classToCheckForLeaks = Job.classToCheckForLeaks();
    final String uniqueID = String.valueOf(new Random().nextInt(Integer.MAX_VALUE));

    final String[] jobCmd = {
      java,
      "-Xmx8m",
      "-classpath",
      System.getProperty("test.classes", "."),
      childClassName,
      uniqueID
    };
    final Process p = new ProcessBuilder(jobCmd).start();

    final String childPid =
        match(
            commandOutputOf(jps, "-m"),
            "(?m)^ *([0-9]+) +\\Q" + childClassName + "\\E *" + uniqueID + "$",
            1);

    final int n0 = objectsInUse(p, childPid, classToCheckForLeaks);
    final int n1 = objectsInUse(p, childPid, classToCheckForLeaks);
    equal(p.waitFor(), 0);
    equal(p.exitValue(), 0);
    failed += p.exitValue();

    // Check that no objects were leaked.
    System.out.printf("%d -> %d%n", n0, n1);
    check(Math.abs(n1 - n0) < 2); // Almost always n0 == n1
    check(n1 < 20);
    drainers.shutdown();
  }
示例#14
0
  private void generateCNAME() {
    String hostname;

    if (this.mcSession) {
      hostname = this.rtpMCSock.getLocalAddress().getCanonicalHostName();
    } else {
      hostname = this.rtpSock.getLocalAddress().getCanonicalHostName();
    }

    // if(hostname.equals("0.0.0.0") && System.getenv("HOSTNAME") != null) {
    //	hostname = System.getenv("HOSTNAME");
    // }

    cname = System.getProperty("user.name") + "@" + hostname;
  }
示例#15
0
 /**
  * Spins/blocks until node s is fulfilled.
  *
  * @param s the waiting node
  * @param e the comparison value for checking match
  * @param timed true if timed wait
  * @param nanos timeout value
  * @return matched item, or s if cancelled
  */
 Object awaitFulfill(QNode s, Object e, boolean timed, long nanos) {
   /* Same idea as TransferStack.awaitFulfill */
   long lastTime = timed ? System.nanoTime() : 0;
   Thread w = Thread.currentThread();
   int spins = ((head.next == s) ? (timed ? maxTimedSpins : maxUntimedSpins) : 0);
   for (; ; ) {
     if (w.isInterrupted()) s.tryCancel(e);
     Object x = s.item;
     if (x != e) return x;
     if (timed) {
       long now = System.nanoTime();
       nanos -= now - lastTime;
       lastTime = now;
       if (nanos <= 0) {
         s.tryCancel(e);
         continue;
       }
     }
     if (spins > 0) --spins;
     else if (s.waiter == null) s.waiter = w;
     else if (!timed) LockSupport.park(this);
     else if (nanos > spinForTimeoutThreshold) LockSupport.parkNanos(this, nanos);
   }
 }
示例#16
0
  @Override
  public void write(int ireg, byte[] data, boolean waitForCompletion) {
    try {
      synchronized (this.concurrentClientLock) {
        synchronized (this.callbackLock) {
          // Wait until we can write to the write cache
          while (this.writeCacheStatus != WRITE_CACHE_STATUS.IDLE) {
            this.callbackLock.wait();
          }

          // Indicate where we want to write
          this.iregWriteFirst = ireg;
          this.cregWrite = data.length;

          // Indicate we are dirty so the callback will write us out
          this.writeCacheStatus = WRITE_CACHE_STATUS.DIRTY;

          // Provide the data we want to write
          this.writeCacheLock.lockInterruptibly();
          try {
            System.arraycopy(data, 0, this.writeCache, dibCacheOverhead, data.length);
          } finally {
            this.writeCacheLock.unlock();
          }

          // Let the callback know we've got new data for him
          this.callback.onNewDataToWrite();

          if (waitForCompletion) {
            // Wait until the write at least issues to the device controller. This will
            // help make any delays/sleeps that follow a write() be more deterministically
            // relative to the actual I2C device write.
            while (writeCacheStatus != WRITE_CACHE_STATUS.IDLE) {
              this.callbackLock.wait();
            }
          }
        }
      }
    } catch (InterruptedException e) {
      Util.handleCapturedInterrupt(e);
    }
  }
 protected long setupPathInterpolator(
     long oid, Point myLoc, Point dest, boolean follow, boolean followsTerrain) {
   long timeNow = System.currentTimeMillis();
   WorldManagerClient.MobPathReqMessage reqMsg =
       pathState.setupPathInterpolator(timeNow, myLoc, dest, mobSpeed, follow, followsTerrain);
   if (reqMsg != null) {
     try {
       Engine.getAgent().sendBroadcast(reqMsg);
       if (Log.loggingDebug)
         Log.debug("BaseBehavior.setupPathInterpolator: send MobPathReqMessage " + reqMsg);
     } catch (Exception e) {
       throw new RuntimeException(e);
     }
     interpolatingPath = true;
     return pathState.pathTimeRemaining();
   } else {
     interpolatingPath = false;
     return 0;
   }
 }
示例#18
0
 public static void startRDPServer() {
   if (rdpServerStarted) return;
   rdpServerStarted = true;
   rdpServerThread = new Thread(rdpServer, "RDPServer");
   retryThread = new Thread(new RetryThread(), "RDPRetry");
   packetCallbackThread = new Thread(new PacketCallbackThread(), "RDPCallback");
   if (Log.loggingNet) Log.net("static - starting rdpserver thread");
   try {
     selector = Selector.open();
   } catch (Exception e) {
     Log.exception("RDPServer caught exception opening selector", e);
     System.exit(1);
   }
   rdpServerThread.setPriority(rdpServerThread.getPriority() + 2);
   if (Log.loggingDebug)
     Log.debug(
         "RDPServer: starting rdpServerThread with priority " + rdpServerThread.getPriority());
   rdpServerThread.start();
   retryThread.start();
   packetCallbackThread.start();
 }
  private Connection waitForConnection(long timeout, TimeUnit unit)
      throws ConnectionException, TimeoutException {
    long start = System.nanoTime();
    long remaining = timeout;
    do {
      try {
        awaitAvailableConnection(remaining, unit);
      } catch (InterruptedException e) {
        Thread.currentThread().interrupt();
        // If we're interrupted fine, check if there is a connection available but stop waiting
        // otherwise
        timeout = 0; // this will make us stop the loop if we don't get a connection right away
      }

      if (isShutdown()) throw new ConnectionException(host.getAddress(), "Pool is shutdown");

      int minInFlight = Integer.MAX_VALUE;
      Connection leastBusy = null;
      for (Connection connection : connections) {
        int inFlight = connection.inFlight.get();
        if (inFlight < minInFlight) {
          minInFlight = inFlight;
          leastBusy = connection;
        }
      }

      while (true) {
        int inFlight = leastBusy.inFlight.get();

        if (inFlight >= Connection.MAX_STREAM_PER_CONNECTION) break;

        if (leastBusy.inFlight.compareAndSet(inFlight, inFlight + 1)) return leastBusy;
      }

      remaining = timeout - Cluster.timeSince(start, unit);
    } while (remaining > 0);

    throw new TimeoutException();
  }
示例#20
0
 static String javahome() {
   String jh = System.getProperty("java.home");
   return (jh.endsWith("jre")) ? jh.substring(0, jh.length() - 4) : jh;
 }
示例#21
0
    public void run() {
      // every second, go through all the packets that havent been
      // ack'd
      List<RDPConnection> conList = new LinkedList<RDPConnection>();
      long lastCounterTime = System.currentTimeMillis();
      while (true) {
        try {
          long startTime = System.currentTimeMillis();
          long interval = startTime - lastCounterTime;
          if (interval > 1000) {

            if (Log.loggingNet) {
              Log.net(
                  "RDPServer counters: activeChannelCalls "
                      + activeChannelCalls
                      + ", selectCalls "
                      + selectCalls
                      + ", transmits "
                      + transmits
                      + ", retransmits "
                      + retransmits
                      + " in "
                      + interval
                      + "ms");
            }
            activeChannelCalls = 0;
            selectCalls = 0;
            transmits = 0;
            retransmits = 0;
            lastCounterTime = startTime;
          }
          if (Log.loggingNet) Log.net("RDPServer.RETRY: startTime=" + startTime);

          // go through all the rdpconnections and re-send any
          // unacked packets
          conList.clear();

          lock.lock();
          try {
            // make a copy since the values() collection is
            // backed by the map
            Set<RDPConnection> conCol = RDPServer.getAllConnections();
            if (conCol == null) {
              throw new MVRuntimeException("values() returned null");
            }
            conList.addAll(conCol); // make non map backed copy
          } finally {
            lock.unlock();
          }

          Iterator<RDPConnection> iter = conList.iterator();
          while (iter.hasNext()) {
            RDPConnection con = iter.next();
            long currentTime = System.currentTimeMillis();

            // is the connection in CLOSE_WAIT
            if (con.getState() == RDPConnection.CLOSE_WAIT) {
              long closeTime = con.getCloseWaitTimer();
              long elapsedTime = currentTime - closeTime;
              Log.net(
                  "RDPRetryThread: con is in CLOSE_WAIT: elapsed close timer(ms)="
                      + elapsedTime
                      + ", waiting for 30seconds to elapse. con="
                      + con);
              if (elapsedTime > 30000) {
                // close the connection
                Log.net("RDPRetryThread: removing CLOSE_WAIT connection. con=" + con);
                removeConnection(con);
              } else {
                Log.net(
                    "RDPRetryThread: time left on CLOSE_WAIT timer: "
                        + (30000 - (currentTime - closeTime)));
              }
              // con.close();
              continue;
            }
            if (Log.loggingNet)
              Log.net(
                  "RDPServer.RETRY: resending expired packets "
                      + con
                      + " - current list size = "
                      + con.unackListSize());

            // see if we should send a null packet, but only if con is already open
            if ((con.getState() == RDPConnection.OPEN)
                && ((currentTime - con.getLastNullPacketTime()) > 30000)) {
              con.getLock().lock();
              try {
                RDPPacket nulPacket = RDPPacket.makeNulPacket();
                con.sendPacketImmediate(nulPacket, false);
                con.setLastNullPacketTime();
                if (Log.loggingNet) Log.net("RDPServer.retry: sent nul packet: " + nulPacket);
              } finally {
                con.getLock().unlock();
              }
            } else {
              if (Log.loggingNet)
                Log.net(
                    "RDPServer.retry: sending nul packet in "
                        + (30000 - (currentTime - con.getLastNullPacketTime())));
            }
            con.resend(
                currentTime - resendTimerMS, // resend cutoff time
                currentTime - resendTimeoutMS); // giveup time
          }

          long endTime = System.currentTimeMillis();
          if (Log.loggingNet)
            Log.net(
                "RDPServer.RETRY: endTime=" + endTime + ", elapse(ms)=" + (endTime - startTime));
          Thread.sleep(250);
        } catch (Exception e) {
          Log.exception("RDPServer.RetryThread.run caught exception", e);
        }
      }
    }
示例#22
0
    void updateStateMachines(UPDATE_STATE_MACHINE caller)
          // We've got quite the little state machine here!
        {
      synchronized (callbackLock) {
        // ----------------------------------------------------------------------------------
        // If we're calling from other than the callback (in which we *know* the port is
        // ready), we need to check whether things are currently busy. We defer until
        // later if they are.
        if (caller == UPDATE_STATE_MACHINE.FROM_USER_WRITE) {
          if (!i2cDevice.isI2cPortReady() || callbackThread == null) return;

          // Optimized calling from user mode is not yet implemented
          return;
        }

        // ----------------------------------------------------------------------------------
        // Some ancillary bookkeeping

        if (caller == UPDATE_STATE_MACHINE.FROM_CALLBACK) {
          // Capture the current callback thread if we haven't already
          if (callbackThread == null) {
            callbackThread = Thread.currentThread();
            callbackThreadOriginalPriority = callbackThread.getPriority();
          } else
            assertTrue(
                !BuildConfig.DEBUG || callbackThread.getId() == Thread.currentThread().getId());

          // Set the thread name to make the system more debuggable
          if (0 == hardwareCycleCount)
            Thread.currentThread().setName(String.format("RWLoop(%s)", i2cDevice.getDeviceName()));

          // Adjust the target thread priority. Note that we only ever adjust it upwards,
          // not downwards, because in reality the thread is shared by other I2C objects
          // on the same controller and we don't want to fight with their understanding
          // of what the priority should be.
          int targetPriority = callbackThreadOriginalPriority + callbackThreadPriorityBoost;
          if (callbackThread.getPriority() < targetPriority) {
            try {
              callbackThread.setPriority(targetPriority);
            } catch (Exception e) {
              /* ignore: just run as is */
            }
          }

          // Update cycle statistics
          hardwareCycleCount++;
        }

        // ----------------------------------------------------------------------------------
        // Initialize state for managing state transition

        setActionFlag = false;
        queueFullWrite = false;
        queueRead = false;
        heartbeatRequired =
            (msHeartbeatInterval > 0
                && milliseconds(timeSinceLastHeartbeat) >= msHeartbeatInterval);
        enabledReadMode = false;
        enabledWriteMode = false;

        prevReadCacheStatus = readCacheStatus;
        prevWriteCacheStatus = writeCacheStatus;
        prevModeCacheStatus = modeCacheStatus;

        // ----------------------------------------------------------------------------------
        // Handle the state machine

        if (caller == UPDATE_STATE_MACHINE.FROM_CALLBACK) {
          // --------------------------------------------------------------------------
          // Deal with the fact that we've completed any previous queueing operation

          if (modeCacheStatus == MODE_CACHE_STATUS.QUEUED) modeCacheStatus = MODE_CACHE_STATUS.IDLE;

          if (readCacheStatus == READ_CACHE_STATUS.QUEUED
              || readCacheStatus == READ_CACHE_STATUS.VALID_QUEUED) {
            readCacheStatus = READ_CACHE_STATUS.QUEUE_COMPLETED;
            nanoTimeReadCacheValid = System.nanoTime();
          }

          if (writeCacheStatus == WRITE_CACHE_STATUS.QUEUED) {
            writeCacheStatus = WRITE_CACHE_STATUS.IDLE;
            // Our write mode status should have been reported back to us
            assertTrue(!BuildConfig.DEBUG || i2cDevice.isI2cPortInWriteMode());
          }

          // --------------------------------------------------------------------------
          // That limits the number of states the caches can now be in

          assertTrue(
              !BuildConfig.DEBUG
                  || (readCacheStatus == READ_CACHE_STATUS.IDLE
                      || readCacheStatus == READ_CACHE_STATUS.SWITCHINGTOREADMODE
                      || readCacheStatus == READ_CACHE_STATUS.VALID_ONLYONCE
                      || readCacheStatus == READ_CACHE_STATUS.QUEUE_COMPLETED));
          assertTrue(
              !BuildConfig.DEBUG
                  || (writeCacheStatus == WRITE_CACHE_STATUS.IDLE
                      || writeCacheStatus == WRITE_CACHE_STATUS.DIRTY));

          // --------------------------------------------------------------------------
          // Complete any read mode switch if there is one

          if (readCacheStatus == READ_CACHE_STATUS.SWITCHINGTOREADMODE) {
            // We're trying to switch into read mode. Are we there yet?
            if (i2cDevice.isI2cPortInReadMode()) {
              // See also below XYZZY
              readCacheStatus = READ_CACHE_STATUS.QUEUED;
              setActionFlag = true; // actually do an I2C read
              queueRead = true; // read the I2C read results
            } else {
              queueRead = true; // read the mode byte
            }
          }

          // --------------------------------------------------------------------------
          // If there's a write request pending, and it's ok to issue the write, do so

          else if (writeCacheStatus == WRITE_CACHE_STATUS.DIRTY) {
            issueWrite();

            // Our ordering rules are that any reads after a write have to wait until
            // the write is actually sent to the hardware, so anything we've read before is junk.
            // Note that there's an analogous check in read().
            readCacheStatus = READ_CACHE_STATUS.IDLE;
          }

          // --------------------------------------------------------------------------
          // Initiate reading if we should. Be sure to honor the policy of the read mode

          else if (readCacheStatus == READ_CACHE_STATUS.IDLE || readWindowChanged) {
            if (readWindow != null && readWindow.isOkToRead()) {
              // We're going to read from this window. If it's an only-once, then
              // ensure we don't come down this path again with the same ReadWindow instance.
              readWindow.setReadIssued();

              // You know...we might *already* have set up the controller to read what we want.
              // Maybe the previous read was a one-shot, for example.
              if (readWindowSentToController != null
                  && readWindowSentToController.contains(readWindow)
                  && i2cDevice.isI2cPortInReadMode()) {
                // Lucky us! We can go ahead and queue the read right now!
                // See also above XYZZY
                readWindowActuallyRead = readWindowSentToController;
                readCacheStatus = READ_CACHE_STATUS.QUEUED;
                setActionFlag = true; // actually do an I2C read
                queueRead = true; // read the results of the read
              } else {
                // We'll start switching now, and queue the read later
                readWindowActuallyRead = readWindow;
                startSwitchingToReadMode(readWindow);
              }
            } else {
              // There's nothing to read. Make *sure* we are idle.
              readCacheStatus = READ_CACHE_STATUS.IDLE;
            }

            readWindowChanged = false;
          }

          // --------------------------------------------------------------------------
          // Reissue any previous read if we should. The only way we are here and
          // see READ_CACHE_STATUS.QUEUE_COMPLETED is if we completed a queuing operation
          // above.

          else if (readCacheStatus == READ_CACHE_STATUS.QUEUE_COMPLETED) {
            if (readWindow != null && readWindow.isOkToRead()) {
              readCacheStatus = READ_CACHE_STATUS.VALID_QUEUED;
              setActionFlag = true; // actually do an I2C read
              queueRead = true; // read the results of the read
            } else {
              readCacheStatus = READ_CACHE_STATUS.VALID_ONLYONCE;
            }
          }

          // --------------------------------------------------------------------------
          // Completing the possibilities:

          else if (readCacheStatus == READ_CACHE_STATUS.VALID_ONLYONCE) {
            // Just leave it there until someone reads it
          }

          // ----------------------------------------------------------------------------------
          // Ok, after all that we finally know what how we're required to
          // interact with the device controller according to what we've been
          // asked to read or write. But what, now, about heartbeats?

          if (!setActionFlag && heartbeatRequired) {
            if (heartbeatAction != null) {
              if (readWindowSentToController != null && heartbeatAction.rereadLastRead) {
                // Controller is in or is switching to read mode. If he's there
                // yet, then issue an I2C read; if he's not, then he soon will be.
                if (i2cDevice.isI2cPortInReadMode()) {
                  setActionFlag = true; // issue an I2C read
                } else {
                  assertTrue(
                      !BuildConfig.DEBUG
                          || readCacheStatus == READ_CACHE_STATUS.SWITCHINGTOREADMODE);
                }
              } else if (readWindowSentToControllerInitialized
                  && readWindowSentToController == null
                  && heartbeatAction.rewriteLastWritten) {
                // Controller is in write mode, and the write cache has what we last wrote
                queueFullWrite = true;
                setActionFlag = true; // issue an I2C write
              } else if (heartbeatAction.heartbeatReadWindow != null) {
                // The simplest way to do this is just to do a new read from the outside, as that
                // means it has literally zero impact here on our state machine. That unfortunately
                // introduces concurrency where otherwise none might exist, but that's ONLY if you
                // choose this flavor of heartbeat, so that's a reasonable tradeoff.
                final ReadWindow window =
                    heartbeatAction
                        .heartbeatReadWindow; // capture here while we still have the lock
                Thread thread =
                    new Thread(
                        new Runnable() {
                          @Override
                          public void run() {
                            try {
                              I2cDeviceClient.this.read(window.getIregFirst(), window.getCreg());
                            } catch (Exception e) // paranoia
                            {
                              // ignored
                            }
                          }
                        });
                // Start the thread a-going. It will run relatively quickly and then shut down
                thread.setName("I2C heartbeat read thread");
                thread.setPriority(heartbeatAction.explicitReadPriority);
                thread.start();
              }
            }
          }

          if (setActionFlag) {
            // We're about to communicate on I2C right now, so reset the heartbeat.
            // Note that we reset() *before* we talk to the device so as to do
            // conservative timing accounting.
            timeSinceLastHeartbeat.reset();
          }
        } else if (caller == UPDATE_STATE_MACHINE.FROM_USER_WRITE) {
          // There's nothing we know to do that would speed things up, so we
          // just do nothing here and wait until the next portIsReady() callback.
        }

        // ----------------------------------------------------------------------------------
        // Read, set action flag and / or queue to module as requested

        if (setActionFlag) i2cDevice.setI2cPortActionFlag();
        else clearActionFlag();

        if (setActionFlag && !queueFullWrite) {
          i2cDevice.writeI2cPortFlagOnlyToController();
        } else if (queueFullWrite) {
          i2cDevice.writeI2cCacheToController();
          //
          if (modeCacheStatus == MODE_CACHE_STATUS.DIRTY)
            modeCacheStatus = MODE_CACHE_STATUS.QUEUED;
        }

        // Queue a read after queuing any write for a bit of paranoia: if we're mode switching
        // to write, we want that write to go out first, THEN read the mode status. It probably
        // would anyway, but why not...
        if (queueRead) {
          i2cDevice.readI2cCacheFromController();
        }

        // ----------------------------------------------------------------------------------
        // Do logging

        if (loggingEnabled) {
          StringBuilder message = new StringBuilder();

          switch (caller) {
            case FROM_CALLBACK:
              message.append(String.format("cyc %d", hardwareCycleCount));
              break;
            case FROM_USER_WRITE:
              message.append(String.format("usr write"));
              break;
          }
          if (setActionFlag) message.append("|flag");
          if (setActionFlag && !queueFullWrite) message.append("|f");
          else if (queueFullWrite) message.append("|w");
          else message.append("|.");
          if (queueRead) message.append("|r");
          if (readCacheStatus != prevReadCacheStatus)
            message.append(
                "| R." + prevReadCacheStatus.toString() + "->" + readCacheStatus.toString());
          if (writeCacheStatus != prevWriteCacheStatus)
            message.append(
                "| W." + prevWriteCacheStatus.toString() + "->" + writeCacheStatus.toString());
          // if (modeCacheStatus != prevModeCacheStatus)   message.append("| M." +
          // prevModeCacheStatus.toString() + "->" + modeCacheStatus.toString());
          if (enabledWriteMode)
            message.append(String.format("| setWrite(0x%02x,%d)", iregWriteFirst, cregWrite));
          if (enabledReadMode)
            message.append(
                String.format(
                    "| setRead(0x%02x,%d)", readWindow.getIregFirst(), readWindow.getCreg()));

          log(Log.DEBUG, message.toString());
        }

        // ----------------------------------------------------------------------------------
        // Notify anyone blocked in read() or write()
        callbackLock.notifyAll();
      }
    }
示例#23
0
  /**
   * Send data to all participants registered as receivers, using the current timeStamp and payload
   * type. The RTP timestamp will be the same for all the packets.
   *
   * @param buffers A buffer of bytes, should not bed padded and less than 1500 bytes on most
   *     networks.
   * @param csrcArray an array with the SSRCs of contributing sources
   * @param markers An array indicating what packets should be marked. Rarely anything but the first
   *     one
   * @param rtpTimestamp The RTP timestamp to be applied to all packets
   * @param seqNumbers An array with the sequence number associated with each byte[]
   * @return null if there was a problem sending the packets, 2-dim array with {RTP Timestamp,
   *     Sequence number}
   */
  public long[][] sendData(
      byte[][] buffers, long[] csrcArray, boolean[] markers, long rtpTimestamp, long[] seqNumbers) {
    logger.debug("-> RTPSession.sendData(byte[])");

    // Same RTP timestamp for all
    if (rtpTimestamp < 0) rtpTimestamp = System.currentTimeMillis();

    // Return values
    long[][] ret = new long[buffers.length][2];

    for (int i = 0; i < buffers.length; i++) {
      byte[] buf = buffers[i];

      boolean marker = false;
      if (markers != null) marker = markers[i];

      if (buf.length > 1500) {
        System.out.println(
            "RTPSession.sendData() called with buffer exceeding 1500 bytes (" + buf.length + ")");
      }

      // Get the return values
      ret[i][0] = rtpTimestamp;
      if (seqNumbers == null) {
        ret[i][1] = getNextSeqNum();
      } else {
        ret[i][1] = seqNumbers[i];
      }
      // Create a new RTP Packet
      RtpPkt pkt = new RtpPkt(rtpTimestamp, this.ssrc, (int) ret[i][1], this.payloadType, buf);

      if (csrcArray != null) pkt.setCsrcs(csrcArray);

      pkt.setMarked(marker);

      // Creates a raw packet
      byte[] pktBytes = pkt.encode();

      // System.out.println(Integer.toString(StaticProcs.bytesToUIntInt(pktBytes, 2)));

      // Pre-flight check, are resolving an SSRC conflict?
      if (this.conflict) {
        System.out.println("RTPSession.sendData() called while trying to resolve conflict.");
        return null;
      }

      if (this.mcSession) {
        DatagramPacket packet = null;

        try {
          packet =
              new DatagramPacket(pktBytes, pktBytes.length, this.mcGroup, this.rtpMCSock.getPort());
        } catch (Exception e) {
          System.out.println("RTPSession.sendData() packet creation failed.");
          e.printStackTrace();
          return null;
        }

        try {
          rtpMCSock.send(packet);
          // Debug
          if (this.debugAppIntf != null) {
            this.debugAppIntf.packetSent(
                1,
                (InetSocketAddress) packet.getSocketAddress(),
                new String(
                    "Sent multicast RTP packet of size "
                        + packet.getLength()
                        + " to "
                        + packet.getSocketAddress().toString()
                        + " via "
                        + rtpMCSock.getLocalSocketAddress().toString()));
          }
        } catch (Exception e) {
          System.out.println("RTPSession.sendData() multicast failed.");
          e.printStackTrace();
          return null;
        }

      } else {
        // Loop over recipients
        Iterator<Participant> iter = partDb.getUnicastReceivers();
        while (iter.hasNext()) {
          InetSocketAddress receiver = iter.next().rtpAddress;
          DatagramPacket packet = null;

          logger.debug("   Sending to {}", receiver);

          try {
            packet = new DatagramPacket(pktBytes, pktBytes.length, receiver);
          } catch (Exception e) {
            System.out.println("RTPSession.sendData() packet creation failed.");
            e.printStackTrace();
            return null;
          }

          // Actually send the packet
          try {
            rtpSock.send(packet);
            // Debug
            if (this.debugAppIntf != null) {
              this.debugAppIntf.packetSent(
                  0,
                  (InetSocketAddress) packet.getSocketAddress(),
                  new String(
                      "Sent unicast RTP packet of size "
                          + packet.getLength()
                          + " to "
                          + packet.getSocketAddress().toString()
                          + " via "
                          + rtpSock.getLocalSocketAddress().toString()));
            }
          } catch (Exception e) {
            System.out.println("RTPSession.sendData() unicast failed.");
            e.printStackTrace();
            return null;
          }
        }
      }

      // Update our stats
      this.sentPktCount++;
      this.sentOctetCount++;

      logger.info("<- RTPSession.sendData(byte[])", pkt.getSeqNumber());
    }

    return ret;
  }