/*
* 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.checkArgument;
import static com.google.common.base.Preconditions.checkNotNull;
import static com.google.common.util.concurrent.Internal.toNanosSaturated;
import com.google.common.annotations.Beta;
import com.google.common.annotations.GwtCompatible;
import com.google.common.annotations.GwtIncompatible;
import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Supplier;
import com.google.common.base.Throwables;
import com.google.common.collect.Lists;
import com.google.common.collect.Queues;
import com.google.common.util.concurrent.ForwardingListenableFuture.SimpleForwardingListenableFuture;
import com.google.errorprone.annotations.CanIgnoreReturnValue;
import com.google.errorprone.annotations.concurrent.GuardedBy;
import java.lang.reflect.InvocationTargetException;
import java.time.Duration;
import java.util.Collection;
import java.util.Collections;
import java.util.Iterator;
import java.util.List;
import java.util.concurrent.BlockingQueue;
import java.util.concurrent.Callable;
import java.util.concurrent.Delayed;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.Executor;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Future;
import java.util.concurrent.RejectedExecutionException;
import java.util.concurrent.ScheduledExecutorService;
import java.util.concurrent.ScheduledFuture;
import java.util.concurrent.ScheduledThreadPoolExecutor;
import java.util.concurrent.ThreadFactory;
import java.util.concurrent.ThreadPoolExecutor;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.TimeoutException;
Author: Eric Fellheimer, Kyle Littlefield, Justin Mahoney Since: 3.0
/**
* Factory and utility methods for {@link java.util.concurrent.Executor}, {@link ExecutorService},
* and {@link java.util.concurrent.ThreadFactory}.
*
* @author Eric Fellheimer
* @author Kyle Littlefield
* @author Justin Mahoney
* @since 3.0
*/
@GwtCompatible(emulated = true)
public final class MoreExecutors {
private MoreExecutors() {}
Converts the given ThreadPoolExecutor into an ExecutorService that exits when the application
is complete. It does so by using daemon threads and adding a shutdown hook to wait for their
completion.
This is mainly for fixed thread pools. See Executors.newFixedThreadPool(int)
.
Params: - executor – the executor to modify to make sure it exits when the application is finished
- terminationTimeout – how long to wait for the executor to finish before terminating the
JVM
Returns: an unmodifiable version of the input which will not hang the JVM Since: 28.0
/**
* Converts the given ThreadPoolExecutor into an ExecutorService that exits when the application
* is complete. It does so by using daemon threads and adding a shutdown hook to wait for their
* completion.
*
* <p>This is mainly for fixed thread pools. See {@link Executors#newFixedThreadPool(int)}.
*
* @param executor the executor to modify to make sure it exits when the application is finished
* @param terminationTimeout how long to wait for the executor to finish before terminating the
* JVM
* @return an unmodifiable version of the input which will not hang the JVM
* @since 28.0
*/
@Beta
@GwtIncompatible // TODO
public static ExecutorService getExitingExecutorService(
ThreadPoolExecutor executor, Duration terminationTimeout) {
return getExitingExecutorService(
executor, toNanosSaturated(terminationTimeout), TimeUnit.NANOSECONDS);
}
Converts the given ThreadPoolExecutor into an ExecutorService that exits when the application
is complete. It does so by using daemon threads and adding a shutdown hook to wait for their
completion.
This is mainly for fixed thread pools. See Executors.newFixedThreadPool(int)
.
Params: - executor – the executor to modify to make sure it exits when the application is finished
- terminationTimeout – how long to wait for the executor to finish before terminating the
JVM
- timeUnit – unit of time for the time parameter
Returns: an unmodifiable version of the input which will not hang the JVM
/**
* Converts the given ThreadPoolExecutor into an ExecutorService that exits when the application
* is complete. It does so by using daemon threads and adding a shutdown hook to wait for their
* completion.
*
* <p>This is mainly for fixed thread pools. See {@link Executors#newFixedThreadPool(int)}.
*
* @param executor the executor to modify to make sure it exits when the application is finished
* @param terminationTimeout how long to wait for the executor to finish before terminating the
* JVM
* @param timeUnit unit of time for the time parameter
* @return an unmodifiable version of the input which will not hang the JVM
*/
@Beta
@GwtIncompatible // TODO
@SuppressWarnings("GoodTime") // should accept a java.time.Duration
public static ExecutorService getExitingExecutorService(
ThreadPoolExecutor executor, long terminationTimeout, TimeUnit timeUnit) {
return new Application().getExitingExecutorService(executor, terminationTimeout, timeUnit);
}
Converts the given ThreadPoolExecutor into an ExecutorService that exits when the application
is complete. It does so by using daemon threads and adding a shutdown hook to wait for their
completion.
This method waits 120 seconds before continuing with JVM termination, even if the executor
has not finished its work.
This is mainly for fixed thread pools. See Executors.newFixedThreadPool(int)
.
Params: - executor – the executor to modify to make sure it exits when the application is finished
Returns: an unmodifiable version of the input which will not hang the JVM
/**
* Converts the given ThreadPoolExecutor into an ExecutorService that exits when the application
* is complete. It does so by using daemon threads and adding a shutdown hook to wait for their
* completion.
*
* <p>This method waits 120 seconds before continuing with JVM termination, even if the executor
* has not finished its work.
*
* <p>This is mainly for fixed thread pools. See {@link Executors#newFixedThreadPool(int)}.
*
* @param executor the executor to modify to make sure it exits when the application is finished
* @return an unmodifiable version of the input which will not hang the JVM
*/
@Beta
@GwtIncompatible // concurrency
public static ExecutorService getExitingExecutorService(ThreadPoolExecutor executor) {
return new Application().getExitingExecutorService(executor);
}
Converts the given ScheduledThreadPoolExecutor into a ScheduledExecutorService that exits when
the application is complete. It does so by using daemon threads and adding a shutdown hook to
wait for their completion.
This is mainly for fixed thread pools. See Executors.newScheduledThreadPool(int)
.
Params: - executor – the executor to modify to make sure it exits when the application is finished
- terminationTimeout – how long to wait for the executor to finish before terminating the
JVM
Returns: an unmodifiable version of the input which will not hang the JVM Since: 28.0
/**
* Converts the given ScheduledThreadPoolExecutor into a ScheduledExecutorService that exits when
* the application is complete. It does so by using daemon threads and adding a shutdown hook to
* wait for their completion.
*
* <p>This is mainly for fixed thread pools. See {@link Executors#newScheduledThreadPool(int)}.
*
* @param executor the executor to modify to make sure it exits when the application is finished
* @param terminationTimeout how long to wait for the executor to finish before terminating the
* JVM
* @return an unmodifiable version of the input which will not hang the JVM
* @since 28.0
*/
@Beta
@GwtIncompatible // java.time.Duration
public static ScheduledExecutorService getExitingScheduledExecutorService(
ScheduledThreadPoolExecutor executor, Duration terminationTimeout) {
return getExitingScheduledExecutorService(
executor, toNanosSaturated(terminationTimeout), TimeUnit.NANOSECONDS);
}
Converts the given ScheduledThreadPoolExecutor into a ScheduledExecutorService that exits when
the application is complete. It does so by using daemon threads and adding a shutdown hook to
wait for their completion.
This is mainly for fixed thread pools. See Executors.newScheduledThreadPool(int)
.
Params: - executor – the executor to modify to make sure it exits when the application is finished
- terminationTimeout – how long to wait for the executor to finish before terminating the
JVM
- timeUnit – unit of time for the time parameter
Returns: an unmodifiable version of the input which will not hang the JVM
/**
* Converts the given ScheduledThreadPoolExecutor into a ScheduledExecutorService that exits when
* the application is complete. It does so by using daemon threads and adding a shutdown hook to
* wait for their completion.
*
* <p>This is mainly for fixed thread pools. See {@link Executors#newScheduledThreadPool(int)}.
*
* @param executor the executor to modify to make sure it exits when the application is finished
* @param terminationTimeout how long to wait for the executor to finish before terminating the
* JVM
* @param timeUnit unit of time for the time parameter
* @return an unmodifiable version of the input which will not hang the JVM
*/
@Beta
@GwtIncompatible // TODO
@SuppressWarnings("GoodTime") // should accept a java.time.Duration
public static ScheduledExecutorService getExitingScheduledExecutorService(
ScheduledThreadPoolExecutor executor, long terminationTimeout, TimeUnit timeUnit) {
return new Application()
.getExitingScheduledExecutorService(executor, terminationTimeout, timeUnit);
}
Converts the given ScheduledThreadPoolExecutor into a ScheduledExecutorService that exits when
the application is complete. It does so by using daemon threads and adding a shutdown hook to
wait for their completion.
This method waits 120 seconds before continuing with JVM termination, even if the executor
has not finished its work.
This is mainly for fixed thread pools. See Executors.newScheduledThreadPool(int)
.
Params: - executor – the executor to modify to make sure it exits when the application is finished
Returns: an unmodifiable version of the input which will not hang the JVM
/**
* Converts the given ScheduledThreadPoolExecutor into a ScheduledExecutorService that exits when
* the application is complete. It does so by using daemon threads and adding a shutdown hook to
* wait for their completion.
*
* <p>This method waits 120 seconds before continuing with JVM termination, even if the executor
* has not finished its work.
*
* <p>This is mainly for fixed thread pools. See {@link Executors#newScheduledThreadPool(int)}.
*
* @param executor the executor to modify to make sure it exits when the application is finished
* @return an unmodifiable version of the input which will not hang the JVM
*/
@Beta
@GwtIncompatible // TODO
public static ScheduledExecutorService getExitingScheduledExecutorService(
ScheduledThreadPoolExecutor executor) {
return new Application().getExitingScheduledExecutorService(executor);
}
Add a shutdown hook to wait for thread completion in the given service
. This is useful if the given service uses daemon threads, and we want to keep the JVM from exiting immediately on shutdown, instead giving these daemon threads a chance to terminate normally. Params: - service – ExecutorService which uses daemon threads
- terminationTimeout – how long to wait for the executor to finish before terminating the
JVM
Since: 28.0
/**
* Add a shutdown hook to wait for thread completion in the given {@link ExecutorService service}.
* This is useful if the given service uses daemon threads, and we want to keep the JVM from
* exiting immediately on shutdown, instead giving these daemon threads a chance to terminate
* normally.
*
* @param service ExecutorService which uses daemon threads
* @param terminationTimeout how long to wait for the executor to finish before terminating the
* JVM
* @since 28.0
*/
@Beta
@GwtIncompatible // java.time.Duration
public static void addDelayedShutdownHook(ExecutorService service, Duration terminationTimeout) {
addDelayedShutdownHook(service, toNanosSaturated(terminationTimeout), TimeUnit.NANOSECONDS);
}
Add a shutdown hook to wait for thread completion in the given service
. This is useful if the given service uses daemon threads, and we want to keep the JVM from exiting immediately on shutdown, instead giving these daemon threads a chance to terminate normally. Params: - service – ExecutorService which uses daemon threads
- terminationTimeout – how long to wait for the executor to finish before terminating the
JVM
- timeUnit – unit of time for the time parameter
/**
* Add a shutdown hook to wait for thread completion in the given {@link ExecutorService service}.
* This is useful if the given service uses daemon threads, and we want to keep the JVM from
* exiting immediately on shutdown, instead giving these daemon threads a chance to terminate
* normally.
*
* @param service ExecutorService which uses daemon threads
* @param terminationTimeout how long to wait for the executor to finish before terminating the
* JVM
* @param timeUnit unit of time for the time parameter
*/
@Beta
@GwtIncompatible // TODO
@SuppressWarnings("GoodTime") // should accept a java.time.Duration
public static void addDelayedShutdownHook(
ExecutorService service, long terminationTimeout, TimeUnit timeUnit) {
new Application().addDelayedShutdownHook(service, terminationTimeout, timeUnit);
}
Represents the current application to register shutdown hooks. /** Represents the current application to register shutdown hooks. */
@GwtIncompatible // TODO
@VisibleForTesting
static class Application {
final ExecutorService getExitingExecutorService(
ThreadPoolExecutor executor, long terminationTimeout, TimeUnit timeUnit) {
useDaemonThreadFactory(executor);
ExecutorService service = Executors.unconfigurableExecutorService(executor);
addDelayedShutdownHook(executor, terminationTimeout, timeUnit);
return service;
}
final ExecutorService getExitingExecutorService(ThreadPoolExecutor executor) {
return getExitingExecutorService(executor, 120, TimeUnit.SECONDS);
}
final ScheduledExecutorService getExitingScheduledExecutorService(
ScheduledThreadPoolExecutor executor, long terminationTimeout, TimeUnit timeUnit) {
useDaemonThreadFactory(executor);
ScheduledExecutorService service = Executors.unconfigurableScheduledExecutorService(executor);
addDelayedShutdownHook(executor, terminationTimeout, timeUnit);
return service;
}
final ScheduledExecutorService getExitingScheduledExecutorService(
ScheduledThreadPoolExecutor executor) {
return getExitingScheduledExecutorService(executor, 120, TimeUnit.SECONDS);
}
final void addDelayedShutdownHook(
final ExecutorService service, final long terminationTimeout, final TimeUnit timeUnit) {
checkNotNull(service);
checkNotNull(timeUnit);
addShutdownHook(
MoreExecutors.newThread(
"DelayedShutdownHook-for-" + service,
new Runnable() {
@Override
public void run() {
try {
// We'd like to log progress and failures that may arise in the
// following code, but unfortunately the behavior of logging
// is undefined in shutdown hooks.
// This is because the logging code installs a shutdown hook of its
// own. See Cleaner class inside {@link LogManager}.
service.shutdown();
service.awaitTermination(terminationTimeout, timeUnit);
} catch (InterruptedException ignored) {
// We're shutting down anyway, so just ignore.
}
}
}));
}
@VisibleForTesting
void addShutdownHook(Thread hook) {
Runtime.getRuntime().addShutdownHook(hook);
}
}
@GwtIncompatible // TODO
private static void useDaemonThreadFactory(ThreadPoolExecutor executor) {
executor.setThreadFactory(
new ThreadFactoryBuilder()
.setDaemon(true)
.setThreadFactory(executor.getThreadFactory())
.build());
}
// See newDirectExecutorService javadoc for behavioral notes.
@GwtIncompatible // TODO
private static final class DirectExecutorService extends AbstractListeningExecutorService {
Lock used whenever accessing the state variables (runningTasks, shutdown) of the executor /** Lock used whenever accessing the state variables (runningTasks, shutdown) of the executor */
private final Object lock = new Object();
/*
* Conceptually, these two variables describe the executor being in
* one of three states:
* - Active: shutdown == false
* - Shutdown: runningTasks > 0 and shutdown == true
* - Terminated: runningTasks == 0 and shutdown == true
*/
@GuardedBy("lock")
private int runningTasks = 0;
@GuardedBy("lock")
private boolean shutdown = false;
@Override
public void execute(Runnable command) {
startTask();
try {
command.run();
} finally {
endTask();
}
}
@Override
public boolean isShutdown() {
synchronized (lock) {
return shutdown;
}
}
@Override
public void shutdown() {
synchronized (lock) {
shutdown = true;
if (runningTasks == 0) {
lock.notifyAll();
}
}
}
// See newDirectExecutorService javadoc for unusual behavior of this method.
@Override
public List<Runnable> shutdownNow() {
shutdown();
return Collections.emptyList();
}
@Override
public boolean isTerminated() {
synchronized (lock) {
return shutdown && runningTasks == 0;
}
}
@Override
public boolean awaitTermination(long timeout, TimeUnit unit) throws InterruptedException {
long nanos = unit.toNanos(timeout);
synchronized (lock) {
while (true) {
if (shutdown && runningTasks == 0) {
return true;
} else if (nanos <= 0) {
return false;
} else {
long now = System.nanoTime();
TimeUnit.NANOSECONDS.timedWait(lock, nanos);
nanos -= System.nanoTime() - now; // subtract the actual time we waited
}
}
}
}
Checks if the executor has been shut down and increments the running task count.
Throws: - RejectedExecutionException – if the executor has been previously shutdown
/**
* Checks if the executor has been shut down and increments the running task count.
*
* @throws RejectedExecutionException if the executor has been previously shutdown
*/
private void startTask() {
synchronized (lock) {
if (shutdown) {
throw new RejectedExecutionException("Executor already shutdown");
}
runningTasks++;
}
}
Decrements the running task count. /** Decrements the running task count. */
private void endTask() {
synchronized (lock) {
int numRunning = --runningTasks;
if (numRunning == 0) {
lock.notifyAll();
}
}
}
}
Creates an executor service that runs each task in the thread that invokes
execute/submit
, as in ThreadPoolExecutor.CallerRunsPolicy
. This applies both to individually submitted tasks and to collections of tasks submitted via invokeAll
or invokeAny
. In the latter case, tasks will run serially on the calling thread. Tasks are run to completion before a Future
is returned to the caller (unless the executor has been shutdown). Although all tasks are immediately executed in the thread that submitted the task, this ExecutorService
imposes a small locking overhead on each task submission in order to implement shutdown and termination behavior.
The implementation deviates from the ExecutorService
specification with regards to the shutdownNow
method. First, "best-effort" with regards to canceling running tasks is implemented as "no-effort". No interrupts or other attempts are made to stop threads executing tasks. Second, the returned list will always be empty, as any submitted task is considered to have started execution. This applies also to tasks given to invokeAll
or
invokeAny
which are pending serial execution, even the subset of the tasks that have not yet started execution. It is unclear from the ExecutorService
specification if these should be included, and it's much easier to implement the interpretation that they not be. Finally, a call to shutdown
or shutdownNow
may result in concurrent calls to
invokeAll/invokeAny
throwing RejectedExecutionException, although a subset of the tasks may already have been executed.
Since: 18.0 (present as MoreExecutors.sameThreadExecutor() since 10.0)
/**
* Creates an executor service that runs each task in the thread that invokes {@code
* execute/submit}, as in {@code ThreadPoolExecutor.CallerRunsPolicy}. This applies both to
* individually submitted tasks and to collections of tasks submitted via {@code invokeAll} or
* {@code invokeAny}. In the latter case, tasks will run serially on the calling thread. Tasks are
* run to completion before a {@code Future} is returned to the caller (unless the executor has
* been shutdown).
*
* <p>Although all tasks are immediately executed in the thread that submitted the task, this
* {@code ExecutorService} imposes a small locking overhead on each task submission in order to
* implement shutdown and termination behavior.
*
* <p>The implementation deviates from the {@code ExecutorService} specification with regards to
* the {@code shutdownNow} method. First, "best-effort" with regards to canceling running tasks is
* implemented as "no-effort". No interrupts or other attempts are made to stop threads executing
* tasks. Second, the returned list will always be empty, as any submitted task is considered to
* have started execution. This applies also to tasks given to {@code invokeAll} or {@code
* invokeAny} which are pending serial execution, even the subset of the tasks that have not yet
* started execution. It is unclear from the {@code ExecutorService} specification if these should
* be included, and it's much easier to implement the interpretation that they not be. Finally, a
* call to {@code shutdown} or {@code shutdownNow} may result in concurrent calls to {@code
* invokeAll/invokeAny} throwing RejectedExecutionException, although a subset of the tasks may
* already have been executed.
*
* @since 18.0 (present as MoreExecutors.sameThreadExecutor() since 10.0)
*/
@GwtIncompatible // TODO
public static ListeningExecutorService newDirectExecutorService() {
return new DirectExecutorService();
}
Returns an Executor
that runs each task in the thread that invokes execute
, as in ThreadPoolExecutor.CallerRunsPolicy
. This executor is appropriate for tasks that are lightweight and not deeply chained. Inappropriate directExecutor
usage can cause problems, and these problems can be difficult to reproduce because they depend on timing. For example:
- A call like
future.transform(function, directExecutor())
may execute the function immediately in the thread that is calling transform
. (This specific case happens if the future is already completed.) If transform
call was made from a UI thread or other latency-sensitive thread, a heavyweight function can harm responsiveness. - If the task will be executed later, consider which thread will trigger the execution --
since that thread will execute the task inline. If the thread is a shared system thread
like an RPC network thread, a heavyweight task can stall progress of the whole system or
even deadlock it.
- If many tasks will be triggered by the same event, one heavyweight task may delay other tasks -- even tasks that are not themselves
directExecutor
tasks. - If many such tasks are chained together (such as with
future.transform(...).transform(...).transform(...)....
), they may overflow the stack. (In simple cases, callers can avoid this by registering all tasks with the same newSequentialExecutor
wrapper around directExecutor()
. More complex cases may require using thread pools or making deeper changes.)
Additionally, beware of executing tasks with directExecutor
while holding a lock. Since the task you submit to the executor (or any other arbitrary work the executor does) may do slow work or acquire other locks, you risk deadlocks. This instance is equivalent to:
final class DirectExecutor implements Executor {
public void execute(Runnable r) {
r.run();
}
}
This should be preferred to newDirectExecutorService()
because implementing the ExecutorService
subinterface necessitates significant performance overhead.
Since: 18.0
/**
* Returns an {@link Executor} that runs each task in the thread that invokes {@link
* Executor#execute execute}, as in {@code ThreadPoolExecutor.CallerRunsPolicy}.
*
* <p>This executor is appropriate for tasks that are lightweight and not deeply chained.
* Inappropriate {@code directExecutor} usage can cause problems, and these problems can be
* difficult to reproduce because they depend on timing. For example:
*
* <ul>
* <li>A call like {@code future.transform(function, directExecutor())} may execute the function
* immediately in the thread that is calling {@code transform}. (This specific case happens
* if the future is already completed.) If {@code transform} call was made from a UI thread
* or other latency-sensitive thread, a heavyweight function can harm responsiveness.
* <li>If the task will be executed later, consider which thread will trigger the execution --
* since that thread will execute the task inline. If the thread is a shared system thread
* like an RPC network thread, a heavyweight task can stall progress of the whole system or
* even deadlock it.
* <li>If many tasks will be triggered by the same event, one heavyweight task may delay other
* tasks -- even tasks that are not themselves {@code directExecutor} tasks.
* <li>If many such tasks are chained together (such as with {@code
* future.transform(...).transform(...).transform(...)....}), they may overflow the stack.
* (In simple cases, callers can avoid this by registering all tasks with the same {@link
* MoreExecutors#newSequentialExecutor} wrapper around {@code directExecutor()}. More
* complex cases may require using thread pools or making deeper changes.)
* </ul>
*
* Additionally, beware of executing tasks with {@code directExecutor} while holding a lock. Since
* the task you submit to the executor (or any other arbitrary work the executor does) may do slow
* work or acquire other locks, you risk deadlocks.
*
* <p>This instance is equivalent to:
*
* <pre>{@code
* final class DirectExecutor implements Executor {
* public void execute(Runnable r) {
* r.run();
* }
* }
* }</pre>
*
* <p>This should be preferred to {@link #newDirectExecutorService()} because implementing the
* {@link ExecutorService} subinterface necessitates significant performance overhead.
*
*
* @since 18.0
*/
public static Executor directExecutor() {
return DirectExecutor.INSTANCE;
}
Returns an Executor
that runs each task executed sequentially, such that no two tasks are running concurrently. Submitted tasks have a happens-before order as defined in the Java Language Specification. The executor uses delegate
in order to execute
each task in turn, and does not create any threads of its own.
After execution begins on a thread from the delegate
Executor
, tasks are polled and executed from a task queue until there are no more tasks. The thread will not be released until there are no more tasks to run.
If a task is submitted while a thread is executing tasks from the task queue, the thread
will not be released until that submitted task is also complete.
If a task is interrupted while a task is running:
- execution will not stop until the task queue is empty.
- tasks will begin execution with the thread marked as not interrupted - any interruption
applies only to the task that was running at the point of interruption.
- if the thread was interrupted before the SequentialExecutor's worker begins execution, the interrupt will be restored to the thread after it completes so that its
delegate
Executor may process the interrupt. - subtasks are run with the thread uninterrupted and interrupts received during execution
of a task are ignored.
RuntimeException
s thrown by tasks are simply logged and the executor keeps trucking. If an Error
is thrown, the error will propagate and execution will stop until the next time a task is submitted.
When an Error
is thrown by an executed task, previously submitted tasks may never run. An attempt will be made to restart execution on the next call to execute
. If the delegate
has begun to reject execution, the previously submitted tasks may never run, despite not throwing a RejectedExecutionException synchronously with the call to
execute
. If this behaviour is problematic, use an Executor with a single thread (e.g. Executors.newSingleThreadExecutor
).
Since: 23.3 (since 23.1 as sequentialExecutor
)
/**
* Returns an {@link Executor} that runs each task executed sequentially, such that no two tasks
* are running concurrently. Submitted tasks have a happens-before order as defined in the Java
* Language Specification.
*
* <p>The executor uses {@code delegate} in order to {@link Executor#execute execute} each task in
* turn, and does not create any threads of its own.
*
* <p>After execution begins on a thread from the {@code delegate} {@link Executor}, tasks are
* polled and executed from a task queue until there are no more tasks. The thread will not be
* released until there are no more tasks to run.
*
* <p>If a task is submitted while a thread is executing tasks from the task queue, the thread
* will not be released until that submitted task is also complete.
*
* <p>If a task is {@linkplain Thread#interrupt interrupted} while a task is running:
*
* <ol>
* <li>execution will not stop until the task queue is empty.
* <li>tasks will begin execution with the thread marked as not interrupted - any interruption
* applies only to the task that was running at the point of interruption.
* <li>if the thread was interrupted before the SequentialExecutor's worker begins execution,
* the interrupt will be restored to the thread after it completes so that its {@code
* delegate} Executor may process the interrupt.
* <li>subtasks are run with the thread uninterrupted and interrupts received during execution
* of a task are ignored.
* </ol>
*
* <p>{@code RuntimeException}s thrown by tasks are simply logged and the executor keeps trucking.
* If an {@code Error} is thrown, the error will propagate and execution will stop until the next
* time a task is submitted.
*
* <p>When an {@code Error} is thrown by an executed task, previously submitted tasks may never
* run. An attempt will be made to restart execution on the next call to {@code execute}. If the
* {@code delegate} has begun to reject execution, the previously submitted tasks may never run,
* despite not throwing a RejectedExecutionException synchronously with the call to {@code
* execute}. If this behaviour is problematic, use an Executor with a single thread (e.g. {@link
* Executors#newSingleThreadExecutor}).
*
* @since 23.3 (since 23.1 as {@code sequentialExecutor})
*/
@Beta
@GwtIncompatible
public static Executor newSequentialExecutor(Executor delegate) {
return new SequentialExecutor(delegate);
}
Creates an ExecutorService
whose submit
and invokeAll
methods submit ListenableFutureTask
instances to the given delegate executor. Those methods, as well as execute
and invokeAny
, are implemented in terms of calls to
delegate.execute
. All other methods are forwarded unchanged to the delegate. This implies that the returned ListeningExecutorService
never calls the delegate's submit
,
invokeAll
, and invokeAny
methods, so any special handling of tasks must be implemented in the delegate's execute
method or by wrapping the returned
ListeningExecutorService
. If the delegate executor was already an instance of ListeningExecutorService
, it is returned untouched, and the rest of this documentation does not apply.
Since: 10.0
/**
* Creates an {@link ExecutorService} whose {@code submit} and {@code invokeAll} methods submit
* {@link ListenableFutureTask} instances to the given delegate executor. Those methods, as well
* as {@code execute} and {@code invokeAny}, are implemented in terms of calls to {@code
* delegate.execute}. All other methods are forwarded unchanged to the delegate. This implies that
* the returned {@code ListeningExecutorService} never calls the delegate's {@code submit}, {@code
* invokeAll}, and {@code invokeAny} methods, so any special handling of tasks must be implemented
* in the delegate's {@code execute} method or by wrapping the returned {@code
* ListeningExecutorService}.
*
* <p>If the delegate executor was already an instance of {@code ListeningExecutorService}, it is
* returned untouched, and the rest of this documentation does not apply.
*
* @since 10.0
*/
@GwtIncompatible // TODO
public static ListeningExecutorService listeningDecorator(ExecutorService delegate) {
return (delegate instanceof ListeningExecutorService)
? (ListeningExecutorService) delegate
: (delegate instanceof ScheduledExecutorService)
? new ScheduledListeningDecorator((ScheduledExecutorService) delegate)
: new ListeningDecorator(delegate);
}
Creates a ScheduledExecutorService
whose submit
and invokeAll
methods submit ListenableFutureTask
instances to the given delegate executor. Those methods, as well as execute
and invokeAny
, are implemented in terms of calls to
delegate.execute
. All other methods are forwarded unchanged to the delegate. This implies that the returned ListeningScheduledExecutorService
never calls the delegate's
submit
, invokeAll
, and invokeAny
methods, so any special handling of tasks must be implemented in the delegate's execute
method or by wrapping the returned
ListeningScheduledExecutorService
. If the delegate executor was already an instance of
ListeningScheduledExecutorService
, it is returned untouched, and the rest of this documentation does not apply.
Since: 10.0
/**
* Creates a {@link ScheduledExecutorService} whose {@code submit} and {@code invokeAll} methods
* submit {@link ListenableFutureTask} instances to the given delegate executor. Those methods, as
* well as {@code execute} and {@code invokeAny}, are implemented in terms of calls to {@code
* delegate.execute}. All other methods are forwarded unchanged to the delegate. This implies that
* the returned {@code ListeningScheduledExecutorService} never calls the delegate's {@code
* submit}, {@code invokeAll}, and {@code invokeAny} methods, so any special handling of tasks
* must be implemented in the delegate's {@code execute} method or by wrapping the returned {@code
* ListeningScheduledExecutorService}.
*
* <p>If the delegate executor was already an instance of {@code
* ListeningScheduledExecutorService}, it is returned untouched, and the rest of this
* documentation does not apply.
*
* @since 10.0
*/
@GwtIncompatible // TODO
public static ListeningScheduledExecutorService listeningDecorator(
ScheduledExecutorService delegate) {
return (delegate instanceof ListeningScheduledExecutorService)
? (ListeningScheduledExecutorService) delegate
: new ScheduledListeningDecorator(delegate);
}
@GwtIncompatible // TODO
private static class ListeningDecorator extends AbstractListeningExecutorService {
private final ExecutorService delegate;
ListeningDecorator(ExecutorService delegate) {
this.delegate = checkNotNull(delegate);
}
@Override
public final boolean awaitTermination(long timeout, TimeUnit unit) throws InterruptedException {
return delegate.awaitTermination(timeout, unit);
}
@Override
public final boolean isShutdown() {
return delegate.isShutdown();
}
@Override
public final boolean isTerminated() {
return delegate.isTerminated();
}
@Override
public final void shutdown() {
delegate.shutdown();
}
@Override
public final List<Runnable> shutdownNow() {
return delegate.shutdownNow();
}
@Override
public final void execute(Runnable command) {
delegate.execute(command);
}
}
@GwtIncompatible // TODO
private static final class ScheduledListeningDecorator extends ListeningDecorator
implements ListeningScheduledExecutorService {
@SuppressWarnings("hiding")
final ScheduledExecutorService delegate;
ScheduledListeningDecorator(ScheduledExecutorService delegate) {
super(delegate);
this.delegate = checkNotNull(delegate);
}
@Override
public ListenableScheduledFuture<?> schedule(Runnable command, long delay, TimeUnit unit) {
TrustedListenableFutureTask<Void> task = TrustedListenableFutureTask.create(command, null);
ScheduledFuture<?> scheduled = delegate.schedule(task, delay, unit);
return new ListenableScheduledTask<>(task, scheduled);
}
@Override
public <V> ListenableScheduledFuture<V> schedule(
Callable<V> callable, long delay, TimeUnit unit) {
TrustedListenableFutureTask<V> task = TrustedListenableFutureTask.create(callable);
ScheduledFuture<?> scheduled = delegate.schedule(task, delay, unit);
return new ListenableScheduledTask<V>(task, scheduled);
}
@Override
public ListenableScheduledFuture<?> scheduleAtFixedRate(
Runnable command, long initialDelay, long period, TimeUnit unit) {
NeverSuccessfulListenableFutureTask task = new NeverSuccessfulListenableFutureTask(command);
ScheduledFuture<?> scheduled = delegate.scheduleAtFixedRate(task, initialDelay, period, unit);
return new ListenableScheduledTask<>(task, scheduled);
}
@Override
public ListenableScheduledFuture<?> scheduleWithFixedDelay(
Runnable command, long initialDelay, long delay, TimeUnit unit) {
NeverSuccessfulListenableFutureTask task = new NeverSuccessfulListenableFutureTask(command);
ScheduledFuture<?> scheduled =
delegate.scheduleWithFixedDelay(task, initialDelay, delay, unit);
return new ListenableScheduledTask<>(task, scheduled);
}
private static final class ListenableScheduledTask<V>
extends SimpleForwardingListenableFuture<V> implements ListenableScheduledFuture<V> {
private final ScheduledFuture<?> scheduledDelegate;
public ListenableScheduledTask(
ListenableFuture<V> listenableDelegate, ScheduledFuture<?> scheduledDelegate) {
super(listenableDelegate);
this.scheduledDelegate = scheduledDelegate;
}
@Override
public boolean cancel(boolean mayInterruptIfRunning) {
boolean cancelled = super.cancel(mayInterruptIfRunning);
if (cancelled) {
// Unless it is cancelled, the delegate may continue being scheduled
scheduledDelegate.cancel(mayInterruptIfRunning);
// TODO(user): Cancel "this" if "scheduledDelegate" is cancelled.
}
return cancelled;
}
@Override
public long getDelay(TimeUnit unit) {
return scheduledDelegate.getDelay(unit);
}
@Override
public int compareTo(Delayed other) {
return scheduledDelegate.compareTo(other);
}
}
@GwtIncompatible // TODO
private static final class NeverSuccessfulListenableFutureTask
extends AbstractFuture.TrustedFuture<Void> implements Runnable {
private final Runnable delegate;
public NeverSuccessfulListenableFutureTask(Runnable delegate) {
this.delegate = checkNotNull(delegate);
}
@Override
public void run() {
try {
delegate.run();
} catch (Throwable t) {
setException(t);
throw Throwables.propagate(t);
}
}
}
}
/*
* This following method is a modified version of one found in
* http://gee.cs.oswego.edu/cgi-bin/viewcvs.cgi/jsr166/src/test/tck/AbstractExecutorServiceTest.java?revision=1.30
* which contained the following notice:
*
* Written by Doug Lea with assistance from members of JCP JSR-166 Expert Group and released to
* the public domain, as explained at http://creativecommons.org/publicdomain/zero/1.0/
*
* Other contributors include Andrew Wright, Jeffrey Hayes, Pat Fisher, Mike Judd.
*/
An implementation of ExecutorService.invokeAny
for ListeningExecutorService
implementations. /**
* An implementation of {@link ExecutorService#invokeAny} for {@link ListeningExecutorService}
* implementations.
*/
@GwtIncompatible static <T> T invokeAnyImpl(
ListeningExecutorService executorService,
Collection<? extends Callable<T>> tasks,
boolean timed,
Duration timeout)
throws InterruptedException, ExecutionException, TimeoutException {
return invokeAnyImpl(
executorService, tasks, timed, toNanosSaturated(timeout), TimeUnit.NANOSECONDS);
}
An implementation of ExecutorService.invokeAny
for ListeningExecutorService
implementations. /**
* An implementation of {@link ExecutorService#invokeAny} for {@link ListeningExecutorService}
* implementations.
*/
@SuppressWarnings("GoodTime") // should accept a java.time.Duration
@GwtIncompatible static <T> T invokeAnyImpl(
ListeningExecutorService executorService,
Collection<? extends Callable<T>> tasks,
boolean timed,
long timeout,
TimeUnit unit)
throws InterruptedException, ExecutionException, TimeoutException {
checkNotNull(executorService);
checkNotNull(unit);
int ntasks = tasks.size();
checkArgument(ntasks > 0);
List<Future<T>> futures = Lists.newArrayListWithCapacity(ntasks);
BlockingQueue<Future<T>> futureQueue = Queues.newLinkedBlockingQueue();
long timeoutNanos = unit.toNanos(timeout);
// For efficiency, especially in executors with limited
// parallelism, check to see if previously submitted tasks are
// done before submitting more of them. This interleaving
// plus the exception mechanics account for messiness of main
// loop.
try {
// Record exceptions so that if we fail to obtain any
// result, we can throw the last exception we got.
ExecutionException ee = null;
long lastTime = timed ? System.nanoTime() : 0;
Iterator<? extends Callable<T>> it = tasks.iterator();
futures.add(submitAndAddQueueListener(executorService, it.next(), futureQueue));
--ntasks;
int active = 1;
while (true) {
Future<T> f = futureQueue.poll();
if (f == null) {
if (ntasks > 0) {
--ntasks;
futures.add(submitAndAddQueueListener(executorService, it.next(), futureQueue));
++active;
} else if (active == 0) {
break;
} else if (timed) {
f = futureQueue.poll(timeoutNanos, TimeUnit.NANOSECONDS);
if (f == null) {
throw new TimeoutException();
}
long now = System.nanoTime();
timeoutNanos -= now - lastTime;
lastTime = now;
} else {
f = futureQueue.take();
}
}
if (f != null) {
--active;
try {
return f.get();
} catch (ExecutionException eex) {
ee = eex;
} catch (RuntimeException rex) {
ee = new ExecutionException(rex);
}
}
}
if (ee == null) {
ee = new ExecutionException(null);
}
throw ee;
} finally {
for (Future<T> f : futures) {
f.cancel(true);
}
}
}
Submits the task and adds a listener that adds the future to queue
when it completes. /**
* Submits the task and adds a listener that adds the future to {@code queue} when it completes.
*/
@GwtIncompatible // TODO
private static <T> ListenableFuture<T> submitAndAddQueueListener(
ListeningExecutorService executorService,
Callable<T> task,
final BlockingQueue<Future<T>> queue) {
final ListenableFuture<T> future = executorService.submit(task);
future.addListener(
new Runnable() {
@Override
public void run() {
queue.add(future);
}
},
directExecutor());
return future;
}
Returns a default thread factory used to create new threads.
When running on AppEngine with access to AppEngine legacy
APIs, this method returns ThreadManager.currentRequestThreadFactory()
. Otherwise, it returns Executors.defaultThreadFactory()
.
Since: 14.0
/**
* Returns a default thread factory used to create new threads.
*
* <p>When running on AppEngine with access to <a
* href="https://cloud.google.com/appengine/docs/standard/java/javadoc/">AppEngine legacy
* APIs</a>, this method returns {@code ThreadManager.currentRequestThreadFactory()}. Otherwise,
* it returns {@link Executors#defaultThreadFactory()}.
*
* @since 14.0
*/
@Beta
@GwtIncompatible // concurrency
public static ThreadFactory platformThreadFactory() {
if (!isAppEngineWithApiClasses()) {
return Executors.defaultThreadFactory();
}
try {
return (ThreadFactory)
Class.forName("com.google.appengine.api.ThreadManager")
.getMethod("currentRequestThreadFactory")
.invoke(null);
/*
* Do not merge the 3 catch blocks below. javac would infer a type of
* ReflectiveOperationException, which Animal Sniffer would reject. (Old versions of Android
* don't *seem* to mind, but there might be edge cases of which we're unaware.)
*/
} catch (IllegalAccessException e) {
throw new RuntimeException("Couldn't invoke ThreadManager.currentRequestThreadFactory", e);
} catch (ClassNotFoundException e) {
throw new RuntimeException("Couldn't invoke ThreadManager.currentRequestThreadFactory", e);
} catch (NoSuchMethodException e) {
throw new RuntimeException("Couldn't invoke ThreadManager.currentRequestThreadFactory", e);
} catch (InvocationTargetException e) {
throw Throwables.propagate(e.getCause());
}
}
@GwtIncompatible // TODO
private static boolean isAppEngineWithApiClasses() {
if (System.getProperty("com.google.appengine.runtime.environment") == null) {
return false;
}
try {
Class.forName("com.google.appengine.api.utils.SystemProperty");
} catch (ClassNotFoundException e) {
return false;
}
try {
// If the current environment is null, we're not inside AppEngine.
return Class.forName("com.google.apphosting.api.ApiProxy")
.getMethod("getCurrentEnvironment")
.invoke(null)
!= null;
} catch (ClassNotFoundException e) {
// If ApiProxy doesn't exist, we're not on AppEngine at all.
return false;
} catch (InvocationTargetException e) {
// If ApiProxy throws an exception, we're not in a proper AppEngine environment.
return false;
} catch (IllegalAccessException e) {
// If the method isn't accessible, we're not on a supported version of AppEngine;
return false;
} catch (NoSuchMethodException e) {
// If the method doesn't exist, we're not on a supported version of AppEngine;
return false;
}
}
Creates a thread using platformThreadFactory
, and sets its name to name
unless changing the name is forbidden by the security manager. /**
* Creates a thread using {@link #platformThreadFactory}, and sets its name to {@code name} unless
* changing the name is forbidden by the security manager.
*/
@GwtIncompatible // concurrency
static Thread newThread(String name, Runnable runnable) {
checkNotNull(name);
checkNotNull(runnable);
Thread result = platformThreadFactory().newThread(runnable);
try {
result.setName(name);
} catch (SecurityException e) {
// OK if we can't set the name in this environment.
}
return result;
}
// TODO(lukes): provide overloads for ListeningExecutorService? ListeningScheduledExecutorService?
// TODO(lukes): provide overloads that take constant strings? Function<Runnable, String>s to
// calculate names?
Creates an Executor
that renames the threads
that its tasks run in. The names are retrieved from the nameSupplier
on the thread that is being renamed right before each task is run. The renaming is best effort, if a SecurityManager
prevents the renaming then it will be skipped but the tasks will still execute.
Params: - executor – The executor to decorate
- nameSupplier – The source of names for each task
/**
* Creates an {@link Executor} that renames the {@link Thread threads} that its tasks run in.
*
* <p>The names are retrieved from the {@code nameSupplier} on the thread that is being renamed
* right before each task is run. The renaming is best effort, if a {@link SecurityManager}
* prevents the renaming then it will be skipped but the tasks will still execute.
*
*
* @param executor The executor to decorate
* @param nameSupplier The source of names for each task
*/
@GwtIncompatible // concurrency
static Executor renamingDecorator(final Executor executor, final Supplier<String> nameSupplier) {
checkNotNull(executor);
checkNotNull(nameSupplier);
return new Executor() {
@Override
public void execute(Runnable command) {
executor.execute(Callables.threadRenaming(command, nameSupplier));
}
};
}
Creates an ExecutorService
that renames the threads
that its tasks run in. The names are retrieved from the nameSupplier
on the thread that is being renamed right before each task is run. The renaming is best effort, if a SecurityManager
prevents the renaming then it will be skipped but the tasks will still execute.
Params: - service – The executor to decorate
- nameSupplier – The source of names for each task
/**
* Creates an {@link ExecutorService} that renames the {@link Thread threads} that its tasks run
* in.
*
* <p>The names are retrieved from the {@code nameSupplier} on the thread that is being renamed
* right before each task is run. The renaming is best effort, if a {@link SecurityManager}
* prevents the renaming then it will be skipped but the tasks will still execute.
*
*
* @param service The executor to decorate
* @param nameSupplier The source of names for each task
*/
@GwtIncompatible // concurrency
static ExecutorService renamingDecorator(
final ExecutorService service, final Supplier<String> nameSupplier) {
checkNotNull(service);
checkNotNull(nameSupplier);
return new WrappingExecutorService(service) {
@Override
protected <T> Callable<T> wrapTask(Callable<T> callable) {
return Callables.threadRenaming(callable, nameSupplier);
}
@Override
protected Runnable wrapTask(Runnable command) {
return Callables.threadRenaming(command, nameSupplier);
}
};
}
Creates a ScheduledExecutorService
that renames the threads
that its tasks run in. The names are retrieved from the nameSupplier
on the thread that is being renamed right before each task is run. The renaming is best effort, if a SecurityManager
prevents the renaming then it will be skipped but the tasks will still execute.
Params: - service – The executor to decorate
- nameSupplier – The source of names for each task
/**
* Creates a {@link ScheduledExecutorService} that renames the {@link Thread threads} that its
* tasks run in.
*
* <p>The names are retrieved from the {@code nameSupplier} on the thread that is being renamed
* right before each task is run. The renaming is best effort, if a {@link SecurityManager}
* prevents the renaming then it will be skipped but the tasks will still execute.
*
*
* @param service The executor to decorate
* @param nameSupplier The source of names for each task
*/
@GwtIncompatible // concurrency
static ScheduledExecutorService renamingDecorator(
final ScheduledExecutorService service, final Supplier<String> nameSupplier) {
checkNotNull(service);
checkNotNull(nameSupplier);
return new WrappingScheduledExecutorService(service) {
@Override
protected <T> Callable<T> wrapTask(Callable<T> callable) {
return Callables.threadRenaming(callable, nameSupplier);
}
@Override
protected Runnable wrapTask(Runnable command) {
return Callables.threadRenaming(command, nameSupplier);
}
};
}
Shuts down the given executor service gradually, first disabling new submissions and later, if
necessary, cancelling remaining tasks.
The method takes the following steps:
- calls
ExecutorService.shutdown()
, disabling acceptance of new submitted tasks. - awaits executor service termination for half of the specified timeout.
- if the timeout expires, it calls
ExecutorService.shutdownNow()
, cancelling pending tasks and interrupting running tasks. - awaits executor service termination for the other half of the specified timeout.
If, at any step of the process, the calling thread is interrupted, the method calls ExecutorService.shutdownNow()
and returns.
Params: - service – the
ExecutorService
to shut down - timeout – the maximum time to wait for the
ExecutorService
to terminate
Returns: true
if the ExecutorService
was terminated successfully, false
if the call timed out or was interruptedSince: 28.0
/**
* Shuts down the given executor service gradually, first disabling new submissions and later, if
* necessary, cancelling remaining tasks.
*
* <p>The method takes the following steps:
*
* <ol>
* <li>calls {@link ExecutorService#shutdown()}, disabling acceptance of new submitted tasks.
* <li>awaits executor service termination for half of the specified timeout.
* <li>if the timeout expires, it calls {@link ExecutorService#shutdownNow()}, cancelling
* pending tasks and interrupting running tasks.
* <li>awaits executor service termination for the other half of the specified timeout.
* </ol>
*
* <p>If, at any step of the process, the calling thread is interrupted, the method calls {@link
* ExecutorService#shutdownNow()} and returns.
*
* @param service the {@code ExecutorService} to shut down
* @param timeout the maximum time to wait for the {@code ExecutorService} to terminate
* @return {@code true} if the {@code ExecutorService} was terminated successfully, {@code false}
* if the call timed out or was interrupted
* @since 28.0
*/
@Beta
@CanIgnoreReturnValue
@GwtIncompatible // java.time.Duration
public static boolean shutdownAndAwaitTermination(ExecutorService service, Duration timeout) {
return shutdownAndAwaitTermination(service, toNanosSaturated(timeout), TimeUnit.NANOSECONDS);
}
Shuts down the given executor service gradually, first disabling new submissions and later, if
necessary, cancelling remaining tasks.
The method takes the following steps:
- calls
ExecutorService.shutdown()
, disabling acceptance of new submitted tasks. - awaits executor service termination for half of the specified timeout.
- if the timeout expires, it calls
ExecutorService.shutdownNow()
, cancelling pending tasks and interrupting running tasks. - awaits executor service termination for the other half of the specified timeout.
If, at any step of the process, the calling thread is interrupted, the method calls ExecutorService.shutdownNow()
and returns.
Params: - service – the
ExecutorService
to shut down - timeout – the maximum time to wait for the
ExecutorService
to terminate - unit – the time unit of the timeout argument
Returns: true
if the ExecutorService
was terminated successfully, false
if the call timed out or was interruptedSince: 17.0
/**
* Shuts down the given executor service gradually, first disabling new submissions and later, if
* necessary, cancelling remaining tasks.
*
* <p>The method takes the following steps:
*
* <ol>
* <li>calls {@link ExecutorService#shutdown()}, disabling acceptance of new submitted tasks.
* <li>awaits executor service termination for half of the specified timeout.
* <li>if the timeout expires, it calls {@link ExecutorService#shutdownNow()}, cancelling
* pending tasks and interrupting running tasks.
* <li>awaits executor service termination for the other half of the specified timeout.
* </ol>
*
* <p>If, at any step of the process, the calling thread is interrupted, the method calls {@link
* ExecutorService#shutdownNow()} and returns.
*
* @param service the {@code ExecutorService} to shut down
* @param timeout the maximum time to wait for the {@code ExecutorService} to terminate
* @param unit the time unit of the timeout argument
* @return {@code true} if the {@code ExecutorService} was terminated successfully, {@code false}
* if the call timed out or was interrupted
* @since 17.0
*/
@Beta
@CanIgnoreReturnValue
@GwtIncompatible // concurrency
@SuppressWarnings("GoodTime") // should accept a java.time.Duration
public static boolean shutdownAndAwaitTermination(
ExecutorService service, long timeout, TimeUnit unit) {
long halfTimeoutNanos = unit.toNanos(timeout) / 2;
// Disable new tasks from being submitted
service.shutdown();
try {
// Wait for half the duration of the timeout for existing tasks to terminate
if (!service.awaitTermination(halfTimeoutNanos, TimeUnit.NANOSECONDS)) {
// Cancel currently executing tasks
service.shutdownNow();
// Wait the other half of the timeout for tasks to respond to being cancelled
service.awaitTermination(halfTimeoutNanos, TimeUnit.NANOSECONDS);
}
} catch (InterruptedException ie) {
// Preserve interrupt status
Thread.currentThread().interrupt();
// (Re-)Cancel if current thread also interrupted
service.shutdownNow();
}
return service.isTerminated();
}
Returns an Executor that will propagate RejectedExecutionException
from the delegate executor to the given future
. Note, the returned executor can only be used once.
/**
* Returns an Executor that will propagate {@link RejectedExecutionException} from the delegate
* executor to the given {@code future}.
*
* <p>Note, the returned executor can only be used once.
*/
static Executor rejectionPropagatingExecutor(
final Executor delegate, final AbstractFuture<?> future) {
checkNotNull(delegate);
checkNotNull(future);
if (delegate == directExecutor()) {
// directExecutor() cannot throw RejectedExecutionException
return delegate;
}
return new Executor() {
@Override
public void execute(Runnable command) {
try {
delegate.execute(command);
} catch (RejectedExecutionException e) {
future.setException(e);
}
}
};
}
}