Esempio n. 1
0
 /**
  * Drains the queue as {@link BlockingQueue#drainTo(Collection, int)}, but if the requested {@code
  * numElements} elements are not available, it will wait for them up to the specified timeout.
  *
  * @param q the blocking queue to be drained
  * @param buffer where to add the transferred elements
  * @param numElements the number of elements to be waited for
  * @param timeout how long to wait before giving up, in units of {@code unit}
  * @param unit a {@code TimeUnit} determining how to interpret the timeout parameter
  * @return the number of elements transferred
  * @throws InterruptedException if interrupted while waiting
  */
 @Beta
 public static <E> int drain(
     BlockingQueue<E> q,
     Collection<? super E> buffer,
     int numElements,
     long timeout,
     TimeUnit unit)
     throws InterruptedException {
   Preconditions.checkNotNull(buffer);
   /*
    * This code performs one System.nanoTime() more than necessary, and in return, the time to
    * execute Queue#drainTo is not added *on top* of waiting for the timeout (which could make
    * the timeout arbitrarily inaccurate, given a queue that is slow to drain).
    */
   long deadline = System.nanoTime() + unit.toNanos(timeout);
   int added = 0;
   while (added < numElements) {
     // we could rely solely on #poll, but #drainTo might be more efficient when there are multiple
     // elements already available (e.g. LinkedBlockingQueue#drainTo locks only once)
     added += q.drainTo(buffer, numElements - added);
     if (added < numElements) { // not enough elements immediately available; will have to poll
       E e = q.poll(deadline - System.nanoTime(), TimeUnit.NANOSECONDS);
       if (e == null) {
         break; // we already waited enough, and there are no more elements in sight
       }
       buffer.add(e);
       added++;
     }
   }
   return added;
 }
Esempio n. 2
0
 /**
  * Drains the queue as {@linkplain #drain(BlockingQueue, Collection, int, long, TimeUnit)}, but
  * with a different behavior in case it is interrupted while waiting. In that case, the operation
  * will continue as usual, and in the end the thread's interruption status will be set (no {@code
  * InterruptedException} is thrown).
  *
  * @param q the blocking queue to be drained
  * @param buffer where to add the transferred elements
  * @param numElements the number of elements to be waited for
  * @param timeout how long to wait before giving up, in units of {@code unit}
  * @param unit a {@code TimeUnit} determining how to interpret the timeout parameter
  * @return the number of elements transferred
  */
 @Beta
 public static <E> int drainUninterruptibly(
     BlockingQueue<E> q,
     Collection<? super E> buffer,
     int numElements,
     long timeout,
     TimeUnit unit) {
   Preconditions.checkNotNull(buffer);
   long deadline = System.nanoTime() + unit.toNanos(timeout);
   int added = 0;
   boolean interrupted = false;
   try {
     while (added < numElements) {
       // we could rely solely on #poll, but #drainTo might be more efficient when there are
       // multiple elements already available (e.g. LinkedBlockingQueue#drainTo locks only once)
       added += q.drainTo(buffer, numElements - added);
       if (added < numElements) { // not enough elements immediately available; will have to poll
         E e; // written exactly once, by a successful (uninterrupted) invocation of #poll
         while (true) {
           try {
             e = q.poll(deadline - System.nanoTime(), TimeUnit.NANOSECONDS);
             break;
           } catch (InterruptedException ex) {
             interrupted = true; // note interruption and retry
           }
         }
         if (e == null) {
           break; // we already waited enough, and there are no more elements in sight
         }
         buffer.add(e);
         added++;
       }
     }
   } finally {
     if (interrupted) {
       Thread.currentThread().interrupt();
     }
   }
   return added;
 }