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This artifact provides a single jar that contains all classes required to use remote EJB and JMS, including all dependencies. It is intended for use by those not using maven, maven users should just import the EJB and JMS BOM's instead (shaded JAR's cause lots of problems with maven, as it is very easy to inadvertently end up with different versions on classes on the class path).

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/*
 * Copyright (C) 2007 The Guava Authors
 *
 * Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
 * in compliance with the License. You may obtain a copy of the License at
 *
 * http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software distributed under the License
 * is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express
 * or implied. See the License for the specific language governing permissions and limitations under
 * the License.
 */

package com.google.common.util.concurrent;

import static com.google.common.base.Preconditions.checkNotNull;
import static com.google.common.util.concurrent.NullnessCasts.uncheckedNull;
import static java.lang.Integer.toHexString;
import static java.lang.System.identityHashCode;
import static java.util.Objects.requireNonNull;
import static java.util.concurrent.atomic.AtomicReferenceFieldUpdater.newUpdater;

import com.google.common.annotations.GwtCompatible;
import com.google.common.base.Strings;
import com.google.common.util.concurrent.internal.InternalFutureFailureAccess;
import com.google.common.util.concurrent.internal.InternalFutures;
import com.google.errorprone.annotations.CanIgnoreReturnValue;
import com.google.errorprone.annotations.ForOverride;
import com.google.j2objc.annotations.ReflectionSupport;
import java.security.AccessController;
import java.security.PrivilegedActionException;
import java.security.PrivilegedExceptionAction;
import java.util.Locale;
import java.util.concurrent.CancellationException;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.Executor;
import java.util.concurrent.Future;
import java.util.concurrent.ScheduledFuture;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.TimeoutException;
import java.util.concurrent.atomic.AtomicReferenceFieldUpdater;
import java.util.concurrent.locks.LockSupport;
import java.util.logging.Level;
import java.util.logging.Logger;
import javax.annotation.CheckForNull;
import org.checkerframework.checker.nullness.qual.Nullable;

/**
 * An abstract implementation of {@link ListenableFuture}, intended for advanced users only. More
 * common ways to create a {@code ListenableFuture} include instantiating a {@link SettableFuture},
 * submitting a task to a {@link ListeningExecutorService}, and deriving a {@code Future} from an
 * existing one, typically using methods like {@link Futures#transform(ListenableFuture,
 * com.google.common.base.Function, java.util.concurrent.Executor) Futures.transform} and {@link
 * Futures#catching(ListenableFuture, Class, com.google.common.base.Function,
 * java.util.concurrent.Executor) Futures.catching}.
 *
 * 

This class implements all methods in {@code ListenableFuture}. Subclasses should provide a way * to set the result of the computation through the protected methods {@link #set(Object)}, {@link * #setFuture(ListenableFuture)} and {@link #setException(Throwable)}. Subclasses may also override * {@link #afterDone()}, which will be invoked automatically when the future completes. Subclasses * should rarely override other methods. * * @author Sven Mawson * @author Luke Sandberg * @since 1.0 */ @SuppressWarnings({ "ShortCircuitBoolean", // we use non-short circuiting comparisons intentionally "nullness", // TODO(b/147136275): Remove once our checker understands & and |. }) @GwtCompatible(emulated = true) @ReflectionSupport(value = ReflectionSupport.Level.FULL) @ElementTypesAreNonnullByDefault public abstract class AbstractFuture extends InternalFutureFailureAccess implements ListenableFuture { // NOTE: Whenever both tests are cheap and functional, it's faster to use &, | instead of &&, || static final boolean GENERATE_CANCELLATION_CAUSES; static { // System.getProperty may throw if the security policy does not permit access. boolean generateCancellationCauses; try { generateCancellationCauses = Boolean.parseBoolean( System.getProperty("guava.concurrent.generate_cancellation_cause", "false")); } catch (SecurityException e) { generateCancellationCauses = false; } GENERATE_CANCELLATION_CAUSES = generateCancellationCauses; } /** * Tag interface marking trusted subclasses. This enables some optimizations. The implementation * of this interface must also be an AbstractFuture and must not override or expose for overriding * any of the public methods of ListenableFuture. */ interface Trusted extends ListenableFuture {} /** * A less abstract subclass of AbstractFuture. This can be used to optimize setFuture by ensuring * that {@link #get} calls exactly the implementation of {@link AbstractFuture#get}. */ abstract static class TrustedFuture extends AbstractFuture implements Trusted { @CanIgnoreReturnValue @Override @ParametricNullness public final V get() throws InterruptedException, ExecutionException { return super.get(); } @CanIgnoreReturnValue @Override @ParametricNullness public final V get(long timeout, TimeUnit unit) throws InterruptedException, ExecutionException, TimeoutException { return super.get(timeout, unit); } @Override public final boolean isDone() { return super.isDone(); } @Override public final boolean isCancelled() { return super.isCancelled(); } @Override public final void addListener(Runnable listener, Executor executor) { super.addListener(listener, executor); } @CanIgnoreReturnValue @Override public final boolean cancel(boolean mayInterruptIfRunning) { return super.cancel(mayInterruptIfRunning); } } // Logger to log exceptions caught when running listeners. private static final Logger log = Logger.getLogger(AbstractFuture.class.getName()); // A heuristic for timed gets. If the remaining timeout is less than this, spin instead of // blocking. This value is what AbstractQueuedSynchronizer uses. private static final long SPIN_THRESHOLD_NANOS = 1000L; private static final AtomicHelper ATOMIC_HELPER; static { AtomicHelper helper; Throwable thrownUnsafeFailure = null; Throwable thrownAtomicReferenceFieldUpdaterFailure = null; try { helper = new UnsafeAtomicHelper(); } catch (RuntimeException | Error unsafeFailure) { thrownUnsafeFailure = unsafeFailure; // catch absolutely everything and fall through to our 'SafeAtomicHelper' // The access control checks that ARFU does means the caller class has to be AbstractFuture // instead of SafeAtomicHelper, so we annoyingly define these here try { helper = new SafeAtomicHelper( newUpdater(Waiter.class, Thread.class, "thread"), newUpdater(Waiter.class, Waiter.class, "next"), newUpdater(AbstractFuture.class, Waiter.class, "waiters"), newUpdater(AbstractFuture.class, Listener.class, "listeners"), newUpdater(AbstractFuture.class, Object.class, "value")); } catch (RuntimeException | Error atomicReferenceFieldUpdaterFailure) { // Some Android 5.0.x Samsung devices have bugs in JDK reflection APIs that cause // getDeclaredField to throw a NoSuchFieldException when the field is definitely there. // For these users fallback to a suboptimal implementation, based on synchronized. This will // be a definite performance hit to those users. thrownAtomicReferenceFieldUpdaterFailure = atomicReferenceFieldUpdaterFailure; helper = new SynchronizedHelper(); } } ATOMIC_HELPER = helper; // Prevent rare disastrous classloading in first call to LockSupport.park. // See: https://bugs.openjdk.java.net/browse/JDK-8074773 @SuppressWarnings("unused") Class ensureLoaded = LockSupport.class; // Log after all static init is finished; if an installed logger uses any Futures methods, it // shouldn't break in cases where reflection is missing/broken. if (thrownAtomicReferenceFieldUpdaterFailure != null) { log.log(Level.SEVERE, "UnsafeAtomicHelper is broken!", thrownUnsafeFailure); log.log( Level.SEVERE, "SafeAtomicHelper is broken!", thrownAtomicReferenceFieldUpdaterFailure); } } /** Waiter links form a Treiber stack, in the {@link #waiters} field. */ private static final class Waiter { static final Waiter TOMBSTONE = new Waiter(false /* ignored param */); @CheckForNull volatile Thread thread; @CheckForNull volatile Waiter next; /** * Constructor for the TOMBSTONE, avoids use of ATOMIC_HELPER in case this class is loaded * before the ATOMIC_HELPER. Apparently this is possible on some android platforms. */ Waiter(boolean unused) {} Waiter() { // avoid volatile write, write is made visible by subsequent CAS on waiters field ATOMIC_HELPER.putThread(this, Thread.currentThread()); } // non-volatile write to the next field. Should be made visible by subsequent CAS on waiters // field. void setNext(@CheckForNull Waiter next) { ATOMIC_HELPER.putNext(this, next); } void unpark() { // This is racy with removeWaiter. The consequence of the race is that we may spuriously call // unpark even though the thread has already removed itself from the list. But even if we did // use a CAS, that race would still exist (it would just be ever so slightly smaller). Thread w = thread; if (w != null) { thread = null; LockSupport.unpark(w); } } } /** * Marks the given node as 'deleted' (null waiter) and then scans the list to unlink all deleted * nodes. This is an O(n) operation in the common case (and O(n^2) in the worst), but we are saved * by two things. * *

    *
  • This is only called when a waiting thread times out or is interrupted. Both of which * should be rare. *
  • The waiters list should be very short. *
*/ private void removeWaiter(Waiter node) { node.thread = null; // mark as 'deleted' restart: while (true) { Waiter pred = null; Waiter curr = waiters; if (curr == Waiter.TOMBSTONE) { return; // give up if someone is calling complete } Waiter succ; while (curr != null) { succ = curr.next; if (curr.thread != null) { // we aren't unlinking this node, update pred. pred = curr; } else if (pred != null) { // We are unlinking this node and it has a predecessor. pred.next = succ; if (pred.thread == null) { // We raced with another node that unlinked pred. Restart. continue restart; } } else if (!ATOMIC_HELPER.casWaiters(this, curr, succ)) { // We are unlinking head continue restart; // We raced with an add or complete } curr = succ; } break; } } /** Listeners also form a stack through the {@link #listeners} field. */ private static final class Listener { static final Listener TOMBSTONE = new Listener(); @CheckForNull // null only for TOMBSTONE final Runnable task; @CheckForNull // null only for TOMBSTONE final Executor executor; // writes to next are made visible by subsequent CAS's on the listeners field @CheckForNull Listener next; Listener(Runnable task, Executor executor) { this.task = task; this.executor = executor; } Listener() { this.task = null; this.executor = null; } } /** A special value to represent {@code null}. */ private static final Object NULL = new Object(); /** A special value to represent failure, when {@link #setException} is called successfully. */ private static final class Failure { static final Failure FALLBACK_INSTANCE = new Failure( new Throwable("Failure occurred while trying to finish a future.") { @Override public synchronized Throwable fillInStackTrace() { return this; // no stack trace } }); final Throwable exception; Failure(Throwable exception) { this.exception = checkNotNull(exception); } } /** A special value to represent cancellation and the 'wasInterrupted' bit. */ private static final class Cancellation { // constants to use when GENERATE_CANCELLATION_CAUSES = false @CheckForNull static final Cancellation CAUSELESS_INTERRUPTED; @CheckForNull static final Cancellation CAUSELESS_CANCELLED; static { if (GENERATE_CANCELLATION_CAUSES) { CAUSELESS_CANCELLED = null; CAUSELESS_INTERRUPTED = null; } else { CAUSELESS_CANCELLED = new Cancellation(false, null); CAUSELESS_INTERRUPTED = new Cancellation(true, null); } } final boolean wasInterrupted; @CheckForNull final Throwable cause; Cancellation(boolean wasInterrupted, @CheckForNull Throwable cause) { this.wasInterrupted = wasInterrupted; this.cause = cause; } } /** A special value that encodes the 'setFuture' state. */ private static final class SetFuture implements Runnable { final AbstractFuture owner; final ListenableFuture future; SetFuture(AbstractFuture owner, ListenableFuture future) { this.owner = owner; this.future = future; } @Override public void run() { if (owner.value != this) { // nothing to do, we must have been cancelled, don't bother inspecting the future. return; } Object valueToSet = getFutureValue(future); if (ATOMIC_HELPER.casValue(owner, this, valueToSet)) { complete( owner, /* * Interruption doesn't propagate through a SetFuture chain (see getFutureValue), so * don't invoke interruptTask. */ false); } } } // TODO(lukes): investigate using the @Contended annotation on these fields when jdk8 is // available. /** * This field encodes the current state of the future. * *

The valid values are: * *

    *
  • {@code null} initial state, nothing has happened. *
  • {@link Cancellation} terminal state, {@code cancel} was called. *
  • {@link Failure} terminal state, {@code setException} was called. *
  • {@link SetFuture} intermediate state, {@code setFuture} was called. *
  • {@link #NULL} terminal state, {@code set(null)} was called. *
  • Any other non-null value, terminal state, {@code set} was called with a non-null * argument. *
*/ @CheckForNull private volatile Object value; /** All listeners. */ @CheckForNull private volatile Listener listeners; /** All waiting threads. */ @CheckForNull private volatile Waiter waiters; /** Constructor for use by subclasses. */ protected AbstractFuture() {} // Gets and Timed Gets // // * Be responsive to interruption // * Don't create Waiter nodes if you aren't going to park, this helps reduce contention on the // waiters field. // * Future completion is defined by when #value becomes non-null/non SetFuture // * Future completion can be observed if the waiters field contains a TOMBSTONE // Timed Get // There are a few design constraints to consider // * We want to be responsive to small timeouts, unpark() has non trivial latency overheads (I // have observed 12 micros on 64-bit linux systems to wake up a parked thread). So if the // timeout is small we shouldn't park(). This needs to be traded off with the cpu overhead of // spinning, so we use SPIN_THRESHOLD_NANOS which is what AbstractQueuedSynchronizer uses for // similar purposes. // * We want to behave reasonably for timeouts of 0 // * We are more responsive to completion than timeouts. This is because parkNanos depends on // system scheduling and as such we could either miss our deadline, or unpark() could be delayed // so that it looks like we timed out even though we didn't. For comparison FutureTask respects // completion preferably and AQS is non-deterministic (depends on where in the queue the waiter // is). If we wanted to be strict about it, we could store the unpark() time in the Waiter node // and we could use that to make a decision about whether or not we timed out prior to being // unparked. /** * {@inheritDoc} * *

The default {@link AbstractFuture} implementation throws {@code InterruptedException} if the * current thread is interrupted during the call, even if the value is already available. * * @throws CancellationException {@inheritDoc} */ @CanIgnoreReturnValue @Override @ParametricNullness public V get(long timeout, TimeUnit unit) throws InterruptedException, TimeoutException, ExecutionException { // NOTE: if timeout < 0, remainingNanos will be < 0 and we will fall into the while(true) loop // at the bottom and throw a timeoutexception. final long timeoutNanos = unit.toNanos(timeout); // we rely on the implicit null check on unit. long remainingNanos = timeoutNanos; if (Thread.interrupted()) { throw new InterruptedException(); } Object localValue = value; if (localValue != null & !(localValue instanceof SetFuture)) { return getDoneValue(localValue); } // we delay calling nanoTime until we know we will need to either park or spin final long endNanos = remainingNanos > 0 ? System.nanoTime() + remainingNanos : 0; long_wait_loop: if (remainingNanos >= SPIN_THRESHOLD_NANOS) { Waiter oldHead = waiters; if (oldHead != Waiter.TOMBSTONE) { Waiter node = new Waiter(); do { node.setNext(oldHead); if (ATOMIC_HELPER.casWaiters(this, oldHead, node)) { while (true) { OverflowAvoidingLockSupport.parkNanos(this, remainingNanos); // Check interruption first, if we woke up due to interruption we need to honor that. if (Thread.interrupted()) { removeWaiter(node); throw new InterruptedException(); } // Otherwise re-read and check doneness. If we loop then it must have been a spurious // wakeup localValue = value; if (localValue != null & !(localValue instanceof SetFuture)) { return getDoneValue(localValue); } // timed out? remainingNanos = endNanos - System.nanoTime(); if (remainingNanos < SPIN_THRESHOLD_NANOS) { // Remove the waiter, one way or another we are done parking this thread. removeWaiter(node); break long_wait_loop; // jump down to the busy wait loop } } } oldHead = waiters; // re-read and loop. } while (oldHead != Waiter.TOMBSTONE); } // re-read value, if we get here then we must have observed a TOMBSTONE while trying to add a // waiter. // requireNonNull is safe because value is always set before TOMBSTONE. return getDoneValue(requireNonNull(value)); } // If we get here then we have remainingNanos < SPIN_THRESHOLD_NANOS and there is no node on the // waiters list while (remainingNanos > 0) { localValue = value; if (localValue != null & !(localValue instanceof SetFuture)) { return getDoneValue(localValue); } if (Thread.interrupted()) { throw new InterruptedException(); } remainingNanos = endNanos - System.nanoTime(); } String futureToString = toString(); final String unitString = unit.toString().toLowerCase(Locale.ROOT); String message = "Waited " + timeout + " " + unit.toString().toLowerCase(Locale.ROOT); // Only report scheduling delay if larger than our spin threshold - otherwise it's just noise if (remainingNanos + SPIN_THRESHOLD_NANOS < 0) { // We over-waited for our timeout. message += " (plus "; long overWaitNanos = -remainingNanos; long overWaitUnits = unit.convert(overWaitNanos, TimeUnit.NANOSECONDS); long overWaitLeftoverNanos = overWaitNanos - unit.toNanos(overWaitUnits); boolean shouldShowExtraNanos = overWaitUnits == 0 || overWaitLeftoverNanos > SPIN_THRESHOLD_NANOS; if (overWaitUnits > 0) { message += overWaitUnits + " " + unitString; if (shouldShowExtraNanos) { message += ","; } message += " "; } if (shouldShowExtraNanos) { message += overWaitLeftoverNanos + " nanoseconds "; } message += "delay)"; } // It's confusing to see a completed future in a timeout message; if isDone() returns false, // then we know it must have given a pending toString value earlier. If not, then the future // completed after the timeout expired, and the message might be success. if (isDone()) { throw new TimeoutException(message + " but future completed as timeout expired"); } throw new TimeoutException(message + " for " + futureToString); } /** * {@inheritDoc} * *

The default {@link AbstractFuture} implementation throws {@code InterruptedException} if the * current thread is interrupted during the call, even if the value is already available. * * @throws CancellationException {@inheritDoc} */ @CanIgnoreReturnValue @Override @ParametricNullness public V get() throws InterruptedException, ExecutionException { if (Thread.interrupted()) { throw new InterruptedException(); } Object localValue = value; if (localValue != null & !(localValue instanceof SetFuture)) { return getDoneValue(localValue); } Waiter oldHead = waiters; if (oldHead != Waiter.TOMBSTONE) { Waiter node = new Waiter(); do { node.setNext(oldHead); if (ATOMIC_HELPER.casWaiters(this, oldHead, node)) { // we are on the stack, now wait for completion. while (true) { LockSupport.park(this); // Check interruption first, if we woke up due to interruption we need to honor that. if (Thread.interrupted()) { removeWaiter(node); throw new InterruptedException(); } // Otherwise re-read and check doneness. If we loop then it must have been a spurious // wakeup localValue = value; if (localValue != null & !(localValue instanceof SetFuture)) { return getDoneValue(localValue); } } } oldHead = waiters; // re-read and loop. } while (oldHead != Waiter.TOMBSTONE); } // re-read value, if we get here then we must have observed a TOMBSTONE while trying to add a // waiter. // requireNonNull is safe because value is always set before TOMBSTONE. return getDoneValue(requireNonNull(value)); } /** Unboxes {@code obj}. Assumes that obj is not {@code null} or a {@link SetFuture}. */ @ParametricNullness private V getDoneValue(Object obj) throws ExecutionException { // While this seems like it might be too branch-y, simple benchmarking proves it to be // unmeasurable (comparing done AbstractFutures with immediateFuture) if (obj instanceof Cancellation) { throw cancellationExceptionWithCause("Task was cancelled.", ((Cancellation) obj).cause); } else if (obj instanceof Failure) { throw new ExecutionException(((Failure) obj).exception); } else if (obj == NULL) { /* * It's safe to return null because we would only have stored it in the first place if it were * a valid value for V. */ return uncheckedNull(); } else { @SuppressWarnings("unchecked") // this is the only other option V asV = (V) obj; return asV; } } @Override public boolean isDone() { final Object localValue = value; return localValue != null & !(localValue instanceof SetFuture); } @Override public boolean isCancelled() { final Object localValue = value; return localValue instanceof Cancellation; } /** * {@inheritDoc} * *

If a cancellation attempt succeeds on a {@code Future} that had previously been {@linkplain * #setFuture set asynchronously}, then the cancellation will also be propagated to the delegate * {@code Future} that was supplied in the {@code setFuture} call. * *

Rather than override this method to perform additional cancellation work or cleanup, * subclasses should override {@link #afterDone}, consulting {@link #isCancelled} and {@link * #wasInterrupted} as necessary. This ensures that the work is done even if the future is * cancelled without a call to {@code cancel}, such as by calling {@code * setFuture(cancelledFuture)}. * *

Beware of completing a future while holding a lock. Its listeners may do slow work or * acquire other locks, risking deadlocks. */ @CanIgnoreReturnValue @Override public boolean cancel(boolean mayInterruptIfRunning) { Object localValue = value; boolean rValue = false; if (localValue == null | localValue instanceof SetFuture) { // Try to delay allocating the exception. At this point we may still lose the CAS, but it is // certainly less likely. Object valueToSet = GENERATE_CANCELLATION_CAUSES ? new Cancellation( mayInterruptIfRunning, new CancellationException("Future.cancel() was called.")) /* * requireNonNull is safe because we've initialized these if * !GENERATE_CANCELLATION_CAUSES. * * TODO(cpovirk): Maybe it would be cleaner to define a CancellationSupplier interface * with two implementations, one that contains causeless Cancellation instances and * the other of which creates new Cancellation instances each time it's called? Yet * another alternative is to fill in a non-null value for each of the fields no matter * what and to just not use it if !GENERATE_CANCELLATION_CAUSES. */ : requireNonNull( mayInterruptIfRunning ? Cancellation.CAUSELESS_INTERRUPTED : Cancellation.CAUSELESS_CANCELLED); AbstractFuture abstractFuture = this; while (true) { if (ATOMIC_HELPER.casValue(abstractFuture, localValue, valueToSet)) { rValue = true; complete(abstractFuture, mayInterruptIfRunning); if (localValue instanceof SetFuture) { // propagate cancellation to the future set in setfuture, this is racy, and we don't // care if we are successful or not. ListenableFuture futureToPropagateTo = ((SetFuture) localValue).future; if (futureToPropagateTo instanceof Trusted) { // If the future is a TrustedFuture then we specifically avoid calling cancel() // this has 2 benefits // 1. for long chains of futures strung together with setFuture we consume less stack // 2. we avoid allocating Cancellation objects at every level of the cancellation // chain // We can only do this for TrustedFuture, because TrustedFuture.cancel is final and // does nothing but delegate to this method. AbstractFuture trusted = (AbstractFuture) futureToPropagateTo; localValue = trusted.value; if (localValue == null | localValue instanceof SetFuture) { abstractFuture = trusted; continue; // loop back up and try to complete the new future } } else { // not a TrustedFuture, call cancel directly. futureToPropagateTo.cancel(mayInterruptIfRunning); } } break; } // obj changed, reread localValue = abstractFuture.value; if (!(localValue instanceof SetFuture)) { // obj cannot be null at this point, because value can only change from null to non-null. // So if value changed (and it did since we lost the CAS), then it cannot be null and // since it isn't a SetFuture, then the future must be done and we should exit the loop break; } } } return rValue; } /** * Subclasses can override this method to implement interruption of the future's computation. The * method is invoked automatically by a successful call to {@link #cancel(boolean) cancel(true)}. * *

The default implementation does nothing. * *

This method is likely to be deprecated. Prefer to override {@link #afterDone}, checking * {@link #wasInterrupted} to decide whether to interrupt your task. * * @since 10.0 */ protected void interruptTask() {} /** * Returns true if this future was cancelled with {@code mayInterruptIfRunning} set to {@code * true}. * * @since 14.0 */ protected final boolean wasInterrupted() { final Object localValue = value; return (localValue instanceof Cancellation) && ((Cancellation) localValue).wasInterrupted; } /** * {@inheritDoc} * * @since 10.0 */ @Override public void addListener(Runnable listener, Executor executor) { checkNotNull(listener, "Runnable was null."); checkNotNull(executor, "Executor was null."); // Checking isDone and listeners != TOMBSTONE may seem redundant, but our contract for // addListener says that listeners execute 'immediate' if the future isDone(). However, our // protocol for completing a future is to assign the value field (which sets isDone to true) and // then to release waiters, followed by executing afterDone(), followed by releasing listeners. // That means that it is possible to observe that the future isDone and that your listeners // don't execute 'immediately'. By checking isDone here we avoid that. // A corollary to all that is that we don't need to check isDone inside the loop because if we // get into the loop we know that we weren't done when we entered and therefore we aren't under // an obligation to execute 'immediately'. if (!isDone()) { Listener oldHead = listeners; if (oldHead != Listener.TOMBSTONE) { Listener newNode = new Listener(listener, executor); do { newNode.next = oldHead; if (ATOMIC_HELPER.casListeners(this, oldHead, newNode)) { return; } oldHead = listeners; // re-read } while (oldHead != Listener.TOMBSTONE); } } // If we get here then the Listener TOMBSTONE was set, which means the future is done, call // the listener. executeListener(listener, executor); } /** * Sets the result of this {@code Future} unless this {@code Future} has already been cancelled or * set (including {@linkplain #setFuture set asynchronously}). When a call to this method returns, * the {@code Future} is guaranteed to be {@linkplain #isDone done} only if the call was * accepted (in which case it returns {@code true}). If it returns {@code false}, the {@code * Future} may have previously been set asynchronously, in which case its result may not be known * yet. That result, though not yet known, cannot be overridden by a call to a {@code set*} * method, only by a call to {@link #cancel}. * *

Beware of completing a future while holding a lock. Its listeners may do slow work or * acquire other locks, risking deadlocks. * * @param value the value to be used as the result * @return true if the attempt was accepted, completing the {@code Future} */ @CanIgnoreReturnValue protected boolean set(@ParametricNullness V value) { Object valueToSet = value == null ? NULL : value; if (ATOMIC_HELPER.casValue(this, null, valueToSet)) { complete(this, /*callInterruptTask=*/ false); return true; } return false; } /** * Sets the failed result of this {@code Future} unless this {@code Future} has already been * cancelled or set (including {@linkplain #setFuture set asynchronously}). When a call to this * method returns, the {@code Future} is guaranteed to be {@linkplain #isDone done} only if * the call was accepted (in which case it returns {@code true}). If it returns {@code false}, the * {@code Future} may have previously been set asynchronously, in which case its result may not be * known yet. That result, though not yet known, cannot be overridden by a call to a {@code set*} * method, only by a call to {@link #cancel}. * *

Beware of completing a future while holding a lock. Its listeners may do slow work or * acquire other locks, risking deadlocks. * * @param throwable the exception to be used as the failed result * @return true if the attempt was accepted, completing the {@code Future} */ @CanIgnoreReturnValue protected boolean setException(Throwable throwable) { Object valueToSet = new Failure(checkNotNull(throwable)); if (ATOMIC_HELPER.casValue(this, null, valueToSet)) { complete(this, /*callInterruptTask=*/ false); return true; } return false; } /** * Sets the result of this {@code Future} to match the supplied input {@code Future} once the * supplied {@code Future} is done, unless this {@code Future} has already been cancelled or set * (including "set asynchronously," defined below). * *

If the supplied future is {@linkplain #isDone done} when this method is called and the call * is accepted, then this future is guaranteed to have been completed with the supplied future by * the time this method returns. If the supplied future is not done and the call is accepted, then * the future will be set asynchronously. Note that such a result, though not yet known, * cannot be overridden by a call to a {@code set*} method, only by a call to {@link #cancel}. * *

If the call {@code setFuture(delegate)} is accepted and this {@code Future} is later * cancelled, cancellation will be propagated to {@code delegate}. Additionally, any call to * {@code setFuture} after any cancellation will propagate cancellation to the supplied {@code * Future}. * *

Note that, even if the supplied future is cancelled and it causes this future to complete, * it will never trigger interruption behavior. In particular, it will not cause this future to * invoke the {@link #interruptTask} method, and the {@link #wasInterrupted} method will not * return {@code true}. * *

Beware of completing a future while holding a lock. Its listeners may do slow work or * acquire other locks, risking deadlocks. * * @param future the future to delegate to * @return true if the attempt was accepted, indicating that the {@code Future} was not previously * cancelled or set. * @since 19.0 */ @CanIgnoreReturnValue protected boolean setFuture(ListenableFuture future) { checkNotNull(future); Object localValue = value; if (localValue == null) { if (future.isDone()) { Object value = getFutureValue(future); if (ATOMIC_HELPER.casValue(this, null, value)) { complete( this, /* * Interruption doesn't propagate through a SetFuture chain (see getFutureValue), so * don't invoke interruptTask. */ false); return true; } return false; } SetFuture valueToSet = new SetFuture(this, future); if (ATOMIC_HELPER.casValue(this, null, valueToSet)) { // the listener is responsible for calling completeWithFuture, directExecutor is appropriate // since all we are doing is unpacking a completed future which should be fast. try { future.addListener(valueToSet, DirectExecutor.INSTANCE); } catch (RuntimeException | Error t) { // addListener has thrown an exception! SetFuture.run can't throw any exceptions so this // must have been caused by addListener itself. The most likely explanation is a // misconfigured mock. Try to switch to Failure. Failure failure; try { failure = new Failure(t); } catch (RuntimeException | Error oomMostLikely) { failure = Failure.FALLBACK_INSTANCE; } // Note: The only way this CAS could fail is if cancel() has raced with us. That is ok. boolean unused = ATOMIC_HELPER.casValue(this, valueToSet, failure); } return true; } localValue = value; // we lost the cas, fall through and maybe cancel } // The future has already been set to something. If it is cancellation we should cancel the // incoming future. if (localValue instanceof Cancellation) { // we don't care if it fails, this is best-effort. future.cancel(((Cancellation) localValue).wasInterrupted); } return false; } /** * Returns a value that satisfies the contract of the {@link #value} field based on the state of * given future. * *

This is approximately the inverse of {@link #getDoneValue(Object)} */ private static Object getFutureValue(ListenableFuture future) { if (future instanceof Trusted) { // Break encapsulation for TrustedFuture instances since we know that subclasses cannot // override .get() (since it is final) and therefore this is equivalent to calling .get() // and unpacking the exceptions like we do below (just much faster because it is a single // field read instead of a read, several branches and possibly creating exceptions). Object v = ((AbstractFuture) future).value; if (v instanceof Cancellation) { // If the other future was interrupted, clear the interrupted bit while preserving the cause // this will make it consistent with how non-trustedfutures work which cannot propagate the // wasInterrupted bit Cancellation c = (Cancellation) v; if (c.wasInterrupted) { v = c.cause != null ? new Cancellation(/* wasInterrupted= */ false, c.cause) : Cancellation.CAUSELESS_CANCELLED; } } // requireNonNull is safe as long as we call this method only on completed futures. return requireNonNull(v); } if (future instanceof InternalFutureFailureAccess) { Throwable throwable = InternalFutures.tryInternalFastPathGetFailure((InternalFutureFailureAccess) future); if (throwable != null) { return new Failure(throwable); } } boolean wasCancelled = future.isCancelled(); // Don't allocate a CancellationException if it's not necessary if (!GENERATE_CANCELLATION_CAUSES & wasCancelled) { /* * requireNonNull is safe because we've initialized CAUSELESS_CANCELLED if * !GENERATE_CANCELLATION_CAUSES. */ return requireNonNull(Cancellation.CAUSELESS_CANCELLED); } // Otherwise calculate the value by calling .get() try { Object v = getUninterruptibly(future); if (wasCancelled) { return new Cancellation( false, new IllegalArgumentException( "get() did not throw CancellationException, despite reporting " + "isCancelled() == true: " + future)); } return v == null ? NULL : v; } catch (ExecutionException exception) { if (wasCancelled) { return new Cancellation( false, new IllegalArgumentException( "get() did not throw CancellationException, despite reporting " + "isCancelled() == true: " + future, exception)); } return new Failure(exception.getCause()); } catch (CancellationException cancellation) { if (!wasCancelled) { return new Failure( new IllegalArgumentException( "get() threw CancellationException, despite reporting isCancelled() == false: " + future, cancellation)); } return new Cancellation(false, cancellation); } catch (RuntimeException | Error t) { return new Failure(t); } } /** * An inlined private copy of {@link Uninterruptibles#getUninterruptibly} used to break an * internal dependency on other /util/concurrent classes. */ @ParametricNullness private static V getUninterruptibly(Future future) throws ExecutionException { boolean interrupted = false; try { while (true) { try { return future.get(); } catch (InterruptedException e) { interrupted = true; } } } finally { if (interrupted) { Thread.currentThread().interrupt(); } } } /** Unblocks all threads and runs all listeners. */ private static void complete(AbstractFuture param, boolean callInterruptTask) { // Declare a "true" local variable so that the Checker Framework will infer nullness. AbstractFuture future = param; Listener next = null; outer: while (true) { future.releaseWaiters(); /* * We call interruptTask() immediately before afterDone() so that migrating between the two * can be a no-op. */ if (callInterruptTask) { future.interruptTask(); /* * Interruption doesn't propagate through a SetFuture chain (see getFutureValue), so don't * invoke interruptTask on any subsequent futures. */ callInterruptTask = false; } // We call this before the listeners in order to avoid needing to manage a separate stack data // structure for them. Also, some implementations rely on this running prior to listeners // so that the cleanup work is visible to listeners. // afterDone() should be generally fast and only used for cleanup work... but in theory can // also be recursive and create StackOverflowErrors future.afterDone(); // push the current set of listeners onto next next = future.clearListeners(next); future = null; while (next != null) { Listener curr = next; next = next.next; /* * requireNonNull is safe because the listener stack never contains TOMBSTONE until after * clearListeners. */ Runnable task = requireNonNull(curr.task); if (task instanceof SetFuture) { SetFuture setFuture = (SetFuture) task; // We unwind setFuture specifically to avoid StackOverflowErrors in the case of long // chains of SetFutures // Handling this special case is important because there is no way to pass an executor to // setFuture, so a user couldn't break the chain by doing this themselves. It is also // potentially common if someone writes a recursive Futures.transformAsync transformer. future = setFuture.owner; if (future.value == setFuture) { Object valueToSet = getFutureValue(setFuture.future); if (ATOMIC_HELPER.casValue(future, setFuture, valueToSet)) { continue outer; } } // otherwise the future we were trying to set is already done. } else { /* * requireNonNull is safe because the listener stack never contains TOMBSTONE until after * clearListeners. */ executeListener(task, requireNonNull(curr.executor)); } } break; } } /** * Callback method that is called exactly once after the future is completed. * *

If {@link #interruptTask} is also run during completion, {@link #afterDone} runs after it. * *

The default implementation of this method in {@code AbstractFuture} does nothing. This is * intended for very lightweight cleanup work, for example, timing statistics or clearing fields. * If your task does anything heavier consider, just using a listener with an executor. * * @since 20.0 */ @ForOverride protected void afterDone() {} // TODO(b/114236866): Inherit doc from InternalFutureFailureAccess. Also, -link to its URL. /** * Usually returns {@code null} but, if this {@code Future} has failed, may optionally * return the cause of the failure. "Failure" means specifically "completed with an exception"; it * does not include "was cancelled." To be explicit: If this method returns a non-null value, * then: * *

    *
  • {@code isDone()} must return {@code true} *
  • {@code isCancelled()} must return {@code false} *
  • {@code get()} must not block, and it must throw an {@code ExecutionException} with the * return value of this method as its cause *
* *

This method is {@code protected} so that classes like {@code * com.google.common.util.concurrent.SettableFuture} do not expose it to their users as an * instance method. In the unlikely event that you need to call this method, call {@link * InternalFutures#tryInternalFastPathGetFailure(InternalFutureFailureAccess)}. * * @since 27.0 */ @Override /* * We should annotate the superclass, InternalFutureFailureAccess, to say that its copy of this * method returns @Nullable, too. However, we're not sure if we want to make any changes to that * class, since it's in a separate artifact that we planned to release only a single version of. */ @CheckForNull protected final Throwable tryInternalFastPathGetFailure() { if (this instanceof Trusted) { Object obj = value; if (obj instanceof Failure) { return ((Failure) obj).exception; } } return null; } /** * If this future has been cancelled (and possibly interrupted), cancels (and possibly interrupts) * the given future (if available). */ final void maybePropagateCancellationTo(@CheckForNull Future related) { if (related != null & isCancelled()) { related.cancel(wasInterrupted()); } } /** Releases all threads in the {@link #waiters} list, and clears the list. */ private void releaseWaiters() { Waiter head = ATOMIC_HELPER.gasWaiters(this, Waiter.TOMBSTONE); for (Waiter currentWaiter = head; currentWaiter != null; currentWaiter = currentWaiter.next) { currentWaiter.unpark(); } } /** * Clears the {@link #listeners} list and prepends its contents to {@code onto}, least recently * added first. */ @CheckForNull private Listener clearListeners(@CheckForNull Listener onto) { // We need to // 1. atomically swap the listeners with TOMBSTONE, this is because addListener uses that // to synchronize with us // 2. reverse the linked list, because despite our rather clear contract, people depend on us // executing listeners in the order they were added // 3. push all the items onto 'onto' and return the new head of the stack Listener head = ATOMIC_HELPER.gasListeners(this, Listener.TOMBSTONE); Listener reversedList = onto; while (head != null) { Listener tmp = head; head = head.next; tmp.next = reversedList; reversedList = tmp; } return reversedList; } // TODO(user): move parts into a default method on ListenableFuture? @Override public String toString() { // TODO(cpovirk): Presize to something plausible? StringBuilder builder = new StringBuilder(); if (getClass().getName().startsWith("com.google.common.util.concurrent.")) { builder.append(getClass().getSimpleName()); } else { builder.append(getClass().getName()); } builder.append('@').append(toHexString(identityHashCode(this))).append("[status="); if (isCancelled()) { builder.append("CANCELLED"); } else if (isDone()) { addDoneString(builder); } else { addPendingString(builder); // delegates to addDoneString if future completes midway } return builder.append("]").toString(); } /** * Provide a human-readable explanation of why this future has not yet completed. * * @return null if an explanation cannot be provided (e.g. because the future is done). * @since 23.0 */ @CheckForNull protected String pendingToString() { // TODO(diamondm) consider moving this into addPendingString so it's always in the output if (this instanceof ScheduledFuture) { return "remaining delay=[" + ((ScheduledFuture) this).getDelay(TimeUnit.MILLISECONDS) + " ms]"; } return null; } private void addPendingString(StringBuilder builder) { // Capture current builder length so it can be truncated if this future ends up completing while // the toString is being calculated int truncateLength = builder.length(); builder.append("PENDING"); Object localValue = value; if (localValue instanceof SetFuture) { builder.append(", setFuture=["); appendUserObject(builder, ((SetFuture) localValue).future); builder.append("]"); } else { String pendingDescription; try { pendingDescription = Strings.emptyToNull(pendingToString()); } catch (RuntimeException | StackOverflowError e) { // Don't call getMessage or toString() on the exception, in case the exception thrown by the // subclass is implemented with bugs similar to the subclass. pendingDescription = "Exception thrown from implementation: " + e.getClass(); } if (pendingDescription != null) { builder.append(", info=[").append(pendingDescription).append("]"); } } // The future may complete while calculating the toString, so we check once more to see if the // future is done if (isDone()) { // Truncate anything that was appended before realizing this future is done builder.delete(truncateLength, builder.length()); addDoneString(builder); } } private void addDoneString(StringBuilder builder) { try { V value = getUninterruptibly(this); builder.append("SUCCESS, result=["); appendResultObject(builder, value); builder.append("]"); } catch (ExecutionException e) { builder.append("FAILURE, cause=[").append(e.getCause()).append("]"); } catch (CancellationException e) { builder.append("CANCELLED"); // shouldn't be reachable } catch (RuntimeException e) { builder.append("UNKNOWN, cause=[").append(e.getClass()).append(" thrown from get()]"); } } /** * Any object can be the result of a Future, and not every object has a reasonable toString() * implementation. Using a reconstruction of the default Object.toString() prevents OOMs and stack * overflows, and helps avoid sensitive data inadvertently ending up in exception messages. */ private void appendResultObject(StringBuilder builder, @CheckForNull Object o) { if (o == null) { builder.append("null"); } else if (o == this) { builder.append("this future"); } else { builder .append(o.getClass().getName()) .append("@") .append(Integer.toHexString(System.identityHashCode(o))); } } /** Helper for printing user supplied objects into our toString method. */ private void appendUserObject(StringBuilder builder, @CheckForNull Object o) { // This is some basic recursion detection for when people create cycles via set/setFuture or // when deep chains of futures exist resulting in a StackOverflowException. We could detect // arbitrary cycles using a thread local but this should be a good enough solution (it is also // what jdk collections do in these cases) try { if (o == this) { builder.append("this future"); } else { builder.append(o); } } catch (RuntimeException | StackOverflowError e) { // Don't call getMessage or toString() on the exception, in case the exception thrown by the // user object is implemented with bugs similar to the user object. builder.append("Exception thrown from implementation: ").append(e.getClass()); } } /** * Submits the given runnable to the given {@link Executor} catching and logging all {@linkplain * RuntimeException runtime exceptions} thrown by the executor. */ private static void executeListener(Runnable runnable, Executor executor) { try { executor.execute(runnable); } catch (RuntimeException e) { // Log it and keep going -- bad runnable and/or executor. Don't punish the other runnables if // we're given a bad one. We only catch RuntimeException because we want Errors to propagate // up. log.log( Level.SEVERE, "RuntimeException while executing runnable " + runnable + " with executor " + executor, e); } } private abstract static class AtomicHelper { /** Non-volatile write of the thread to the {@link Waiter#thread} field. */ abstract void putThread(Waiter waiter, Thread newValue); /** Non-volatile write of the waiter to the {@link Waiter#next} field. */ abstract void putNext(Waiter waiter, @CheckForNull Waiter newValue); /** Performs a CAS operation on the {@link #waiters} field. */ abstract boolean casWaiters( AbstractFuture future, @CheckForNull Waiter expect, @CheckForNull Waiter update); /** Performs a CAS operation on the {@link #listeners} field. */ abstract boolean casListeners( AbstractFuture future, @CheckForNull Listener expect, Listener update); /** Performs a GAS operation on the {@link #waiters} field. */ abstract Waiter gasWaiters(AbstractFuture future, Waiter update); /** Performs a GAS operation on the {@link #listeners} field. */ abstract Listener gasListeners(AbstractFuture future, Listener update); /** Performs a CAS operation on the {@link #value} field. */ abstract boolean casValue(AbstractFuture future, @CheckForNull Object expect, Object update); } /** * {@link AtomicHelper} based on {@link sun.misc.Unsafe}. * *

Static initialization of this class will fail if the {@link sun.misc.Unsafe} object cannot * be accessed. */ @SuppressWarnings("sunapi") private static final class UnsafeAtomicHelper extends AtomicHelper { static final sun.misc.Unsafe UNSAFE; static final long LISTENERS_OFFSET; static final long WAITERS_OFFSET; static final long VALUE_OFFSET; static final long WAITER_THREAD_OFFSET; static final long WAITER_NEXT_OFFSET; static { sun.misc.Unsafe unsafe = null; try { unsafe = sun.misc.Unsafe.getUnsafe(); } catch (SecurityException tryReflectionInstead) { try { unsafe = AccessController.doPrivileged( new PrivilegedExceptionAction() { @Override public sun.misc.Unsafe run() throws Exception { Class k = sun.misc.Unsafe.class; for (java.lang.reflect.Field f : k.getDeclaredFields()) { f.setAccessible(true); Object x = f.get(null); if (k.isInstance(x)) { return k.cast(x); } } throw new NoSuchFieldError("the Unsafe"); } }); } catch (PrivilegedActionException e) { throw new RuntimeException("Could not initialize intrinsics", e.getCause()); } } try { Class abstractFuture = AbstractFuture.class; WAITERS_OFFSET = unsafe.objectFieldOffset(abstractFuture.getDeclaredField("waiters")); LISTENERS_OFFSET = unsafe.objectFieldOffset(abstractFuture.getDeclaredField("listeners")); VALUE_OFFSET = unsafe.objectFieldOffset(abstractFuture.getDeclaredField("value")); WAITER_THREAD_OFFSET = unsafe.objectFieldOffset(Waiter.class.getDeclaredField("thread")); WAITER_NEXT_OFFSET = unsafe.objectFieldOffset(Waiter.class.getDeclaredField("next")); UNSAFE = unsafe; } catch (NoSuchFieldException e) { throw new RuntimeException(e); } catch (RuntimeException e) { throw e; } } @Override void putThread(Waiter waiter, Thread newValue) { UNSAFE.putObject(waiter, WAITER_THREAD_OFFSET, newValue); } @Override void putNext(Waiter waiter, @CheckForNull Waiter newValue) { UNSAFE.putObject(waiter, WAITER_NEXT_OFFSET, newValue); } /** Performs a CAS operation on the {@link #waiters} field. */ @Override boolean casWaiters( AbstractFuture future, @CheckForNull Waiter expect, @CheckForNull Waiter update) { return UNSAFE.compareAndSwapObject(future, WAITERS_OFFSET, expect, update); } /** Performs a CAS operation on the {@link #listeners} field. */ @Override boolean casListeners(AbstractFuture future, @CheckForNull Listener expect, Listener update) { return UNSAFE.compareAndSwapObject(future, LISTENERS_OFFSET, expect, update); } /** Performs a GAS operation on the {@link #listeners} field. */ @Override Listener gasListeners(AbstractFuture future, Listener update) { return (Listener) UNSAFE.getAndSetObject(future, LISTENERS_OFFSET, update); } /** Performs a GAS operation on the {@link #waiters} field. */ @Override Waiter gasWaiters(AbstractFuture future, Waiter update) { return (Waiter) UNSAFE.getAndSetObject(future, WAITERS_OFFSET, update); } /** Performs a CAS operation on the {@link #value} field. */ @Override boolean casValue(AbstractFuture future, @CheckForNull Object expect, Object update) { return UNSAFE.compareAndSwapObject(future, VALUE_OFFSET, expect, update); } } /** {@link AtomicHelper} based on {@link AtomicReferenceFieldUpdater}. */ @SuppressWarnings("rawtypes") private static final class SafeAtomicHelper extends AtomicHelper { final AtomicReferenceFieldUpdater waiterThreadUpdater; final AtomicReferenceFieldUpdater waiterNextUpdater; final AtomicReferenceFieldUpdater waitersUpdater; final AtomicReferenceFieldUpdater listenersUpdater; final AtomicReferenceFieldUpdater valueUpdater; SafeAtomicHelper( AtomicReferenceFieldUpdater waiterThreadUpdater, AtomicReferenceFieldUpdater waiterNextUpdater, AtomicReferenceFieldUpdater waitersUpdater, AtomicReferenceFieldUpdater listenersUpdater, AtomicReferenceFieldUpdater valueUpdater) { this.waiterThreadUpdater = waiterThreadUpdater; this.waiterNextUpdater = waiterNextUpdater; this.waitersUpdater = waitersUpdater; this.listenersUpdater = listenersUpdater; this.valueUpdater = valueUpdater; } @Override void putThread(Waiter waiter, Thread newValue) { waiterThreadUpdater.lazySet(waiter, newValue); } @Override void putNext(Waiter waiter, @CheckForNull Waiter newValue) { waiterNextUpdater.lazySet(waiter, newValue); } @Override boolean casWaiters( AbstractFuture future, @CheckForNull Waiter expect, @CheckForNull Waiter update) { return waitersUpdater.compareAndSet(future, expect, update); } @Override boolean casListeners(AbstractFuture future, @CheckForNull Listener expect, Listener update) { return listenersUpdater.compareAndSet(future, expect, update); } /** Performs a GAS operation on the {@link #listeners} field. */ @Override Listener gasListeners(AbstractFuture future, Listener update) { return listenersUpdater.getAndSet(future, update); } /** Performs a GAS operation on the {@link #waiters} field. */ @Override Waiter gasWaiters(AbstractFuture future, Waiter update) { return waitersUpdater.getAndSet(future, update); } @Override boolean casValue(AbstractFuture future, @CheckForNull Object expect, Object update) { return valueUpdater.compareAndSet(future, expect, update); } } /** * {@link AtomicHelper} based on {@code synchronized} and volatile writes. * *

This is an implementation of last resort for when certain basic VM features are broken (like * AtomicReferenceFieldUpdater). */ private static final class SynchronizedHelper extends AtomicHelper { @Override void putThread(Waiter waiter, Thread newValue) { waiter.thread = newValue; } @Override void putNext(Waiter waiter, @CheckForNull Waiter newValue) { waiter.next = newValue; } @Override boolean casWaiters( AbstractFuture future, @CheckForNull Waiter expect, @CheckForNull Waiter update) { synchronized (future) { if (future.waiters == expect) { future.waiters = update; return true; } return false; } } @Override boolean casListeners(AbstractFuture future, @CheckForNull Listener expect, Listener update) { synchronized (future) { if (future.listeners == expect) { future.listeners = update; return true; } return false; } } /** Performs a GAS operation on the {@link #listeners} field. */ @Override Listener gasListeners(AbstractFuture future, Listener update) { synchronized (future) { Listener old = future.listeners; if (old != update) { future.listeners = update; } return old; } } /** Performs a GAS operation on the {@link #waiters} field. */ @Override Waiter gasWaiters(AbstractFuture future, Waiter update) { synchronized (future) { Waiter old = future.waiters; if (old != update) { future.waiters = update; } return old; } } @Override boolean casValue(AbstractFuture future, @CheckForNull Object expect, Object update) { synchronized (future) { if (future.value == expect) { future.value = update; return true; } return false; } } } private static CancellationException cancellationExceptionWithCause( String message, @CheckForNull Throwable cause) { CancellationException exception = new CancellationException(message); exception.initCause(cause); return exception; } }





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