001/*
002 * Copyright (C) 2011 The Guava Authors
003 *
004 * Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
005 * in compliance with the License. You may obtain a copy of the License at
006 *
007 * http://www.apache.org/licenses/LICENSE-2.0
008 *
009 * Unless required by applicable law or agreed to in writing, software distributed under the License
010 * is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express
011 * or implied. See the License for the specific language governing permissions and limitations under
012 * the License.
013 */
014
015package com.google.common.util.concurrent;
016
017import static com.google.common.base.Preconditions.checkArgument;
018import static com.google.common.base.Preconditions.checkNotNull;
019import static com.google.common.util.concurrent.Futures.immediateCancelledFuture;
020import static com.google.common.util.concurrent.Internal.toNanosSaturated;
021import static com.google.common.util.concurrent.MoreExecutors.directExecutor;
022import static java.util.Objects.requireNonNull;
023
024import com.google.common.annotations.GwtIncompatible;
025import com.google.common.base.Supplier;
026import com.google.errorprone.annotations.CanIgnoreReturnValue;
027import com.google.errorprone.annotations.concurrent.GuardedBy;
028import com.google.j2objc.annotations.WeakOuter;
029import java.time.Duration;
030import java.util.concurrent.Callable;
031import java.util.concurrent.Executor;
032import java.util.concurrent.Executors;
033import java.util.concurrent.Future;
034import java.util.concurrent.ScheduledExecutorService;
035import java.util.concurrent.ScheduledFuture;
036import java.util.concurrent.ThreadFactory;
037import java.util.concurrent.TimeUnit;
038import java.util.concurrent.TimeoutException;
039import java.util.concurrent.locks.ReentrantLock;
040import java.util.logging.Level;
041import java.util.logging.Logger;
042import javax.annotation.CheckForNull;
043import org.checkerframework.checker.nullness.qual.Nullable;
044
045/**
046 * Base class for services that can implement {@link #startUp} and {@link #shutDown} but while in
047 * the "running" state need to perform a periodic task. Subclasses can implement {@link #startUp},
048 * {@link #shutDown} and also a {@link #runOneIteration} method that will be executed periodically.
049 *
050 * <p>This class uses the {@link ScheduledExecutorService} returned from {@link #executor} to run
051 * the {@link #startUp} and {@link #shutDown} methods and also uses that service to schedule the
052 * {@link #runOneIteration} that will be executed periodically as specified by its {@link
053 * Scheduler}. When this service is asked to stop via {@link #stopAsync} it will cancel the periodic
054 * task (but not interrupt it) and wait for it to stop before running the {@link #shutDown} method.
055 *
056 * <p>Subclasses are guaranteed that the life cycle methods ({@link #runOneIteration}, {@link
057 * #startUp} and {@link #shutDown}) will never run concurrently. Notably, if any execution of {@link
058 * #runOneIteration} takes longer than its schedule defines, then subsequent executions may start
059 * late. Also, all life cycle methods are executed with a lock held, so subclasses can safely modify
060 * shared state without additional synchronization necessary for visibility to later executions of
061 * the life cycle methods.
062 *
063 * <h3>Usage Example</h3>
064 *
065 * <p>Here is a sketch of a service which crawls a website and uses the scheduling capabilities to
066 * rate limit itself.
067 *
068 * <pre>{@code
069 * class CrawlingService extends AbstractScheduledService {
070 *   private Set<Uri> visited;
071 *   private Queue<Uri> toCrawl;
072 *   protected void startUp() throws Exception {
073 *     toCrawl = readStartingUris();
074 *   }
075 *
076 *   protected void runOneIteration() throws Exception {
077 *     Uri uri = toCrawl.remove();
078 *     Collection<Uri> newUris = crawl(uri);
079 *     visited.add(uri);
080 *     for (Uri newUri : newUris) {
081 *       if (!visited.contains(newUri)) { toCrawl.add(newUri); }
082 *     }
083 *   }
084 *
085 *   protected void shutDown() throws Exception {
086 *     saveUris(toCrawl);
087 *   }
088 *
089 *   protected Scheduler scheduler() {
090 *     return Scheduler.newFixedRateSchedule(0, 1, TimeUnit.SECONDS);
091 *   }
092 * }
093 * }</pre>
094 *
095 * <p>This class uses the life cycle methods to read in a list of starting URIs and save the set of
096 * outstanding URIs when shutting down. Also, it takes advantage of the scheduling functionality to
097 * rate limit the number of queries we perform.
098 *
099 * @author Luke Sandberg
100 * @since 11.0
101 */
102@GwtIncompatible
103@ElementTypesAreNonnullByDefault
104public abstract class AbstractScheduledService implements Service {
105  private static final Logger logger = Logger.getLogger(AbstractScheduledService.class.getName());
106
107  /**
108   * A scheduler defines the policy for how the {@link AbstractScheduledService} should run its
109   * task.
110   *
111   * <p>Consider using the {@link #newFixedDelaySchedule} and {@link #newFixedRateSchedule} factory
112   * methods, these provide {@link Scheduler} instances for the common use case of running the
113   * service with a fixed schedule. If more flexibility is needed then consider subclassing {@link
114   * CustomScheduler}.
115   *
116   * @author Luke Sandberg
117   * @since 11.0
118   */
119  public abstract static class Scheduler {
120    /**
121     * Returns a {@link Scheduler} that schedules the task using the {@link
122     * ScheduledExecutorService#scheduleWithFixedDelay} method.
123     *
124     * @param initialDelay the time to delay first execution
125     * @param delay the delay between the termination of one execution and the commencement of the
126     *     next
127     * @since 28.0
128     */
129    public static Scheduler newFixedDelaySchedule(Duration initialDelay, Duration delay) {
130      return newFixedDelaySchedule(
131          toNanosSaturated(initialDelay), toNanosSaturated(delay), TimeUnit.NANOSECONDS);
132    }
133
134    /**
135     * Returns a {@link Scheduler} that schedules the task using the {@link
136     * ScheduledExecutorService#scheduleWithFixedDelay} method.
137     *
138     * @param initialDelay the time to delay first execution
139     * @param delay the delay between the termination of one execution and the commencement of the
140     *     next
141     * @param unit the time unit of the initialDelay and delay parameters
142     */
143    @SuppressWarnings("GoodTime") // should accept a java.time.Duration
144    public static Scheduler newFixedDelaySchedule(
145        final long initialDelay, final long delay, final TimeUnit unit) {
146      checkNotNull(unit);
147      checkArgument(delay > 0, "delay must be > 0, found %s", delay);
148      return new Scheduler() {
149        @Override
150        public Cancellable schedule(
151            AbstractService service, ScheduledExecutorService executor, Runnable task) {
152          return new FutureAsCancellable(
153              executor.scheduleWithFixedDelay(task, initialDelay, delay, unit));
154        }
155      };
156    }
157
158    /**
159     * Returns a {@link Scheduler} that schedules the task using the {@link
160     * ScheduledExecutorService#scheduleAtFixedRate} method.
161     *
162     * @param initialDelay the time to delay first execution
163     * @param period the period between successive executions of the task
164     * @since 28.0
165     */
166    public static Scheduler newFixedRateSchedule(Duration initialDelay, Duration period) {
167      return newFixedRateSchedule(
168          toNanosSaturated(initialDelay), toNanosSaturated(period), TimeUnit.NANOSECONDS);
169    }
170
171    /**
172     * Returns a {@link Scheduler} that schedules the task using the {@link
173     * ScheduledExecutorService#scheduleAtFixedRate} method.
174     *
175     * @param initialDelay the time to delay first execution
176     * @param period the period between successive executions of the task
177     * @param unit the time unit of the initialDelay and period parameters
178     */
179    @SuppressWarnings("GoodTime") // should accept a java.time.Duration
180    public static Scheduler newFixedRateSchedule(
181        final long initialDelay, final long period, final TimeUnit unit) {
182      checkNotNull(unit);
183      checkArgument(period > 0, "period must be > 0, found %s", period);
184      return new Scheduler() {
185        @Override
186        public Cancellable schedule(
187            AbstractService service, ScheduledExecutorService executor, Runnable task) {
188          return new FutureAsCancellable(
189              executor.scheduleAtFixedRate(task, initialDelay, period, unit));
190        }
191      };
192    }
193
194    /** Schedules the task to run on the provided executor on behalf of the service. */
195    abstract Cancellable schedule(
196        AbstractService service, ScheduledExecutorService executor, Runnable runnable);
197
198    private Scheduler() {}
199  }
200
201  /* use AbstractService for state management */
202  private final AbstractService delegate = new ServiceDelegate();
203
204  @WeakOuter
205  private final class ServiceDelegate extends AbstractService {
206
207    // A handle to the running task so that we can stop it when a shutdown has been requested.
208    // These two fields are volatile because their values will be accessed from multiple threads.
209    @CheckForNull private volatile Cancellable runningTask;
210    @CheckForNull private volatile ScheduledExecutorService executorService;
211
212    // This lock protects the task so we can ensure that none of the template methods (startUp,
213    // shutDown or runOneIteration) run concurrently with one another.
214    // TODO(lukes): why don't we use ListenableFuture to sequence things? Then we could drop the
215    // lock.
216    private final ReentrantLock lock = new ReentrantLock();
217
218    @WeakOuter
219    class Task implements Runnable {
220      @Override
221      public void run() {
222        lock.lock();
223        try {
224          /*
225           * requireNonNull is safe because Task isn't run (or at least it doesn't succeed in taking
226           * the lock) until after it's scheduled and the runningTask field is set.
227           */
228          if (requireNonNull(runningTask).isCancelled()) {
229            // task may have been cancelled while blocked on the lock.
230            return;
231          }
232          AbstractScheduledService.this.runOneIteration();
233        } catch (Throwable t) {
234          try {
235            shutDown();
236          } catch (Exception ignored) {
237            logger.log(
238                Level.WARNING,
239                "Error while attempting to shut down the service after failure.",
240                ignored);
241          }
242          notifyFailed(t);
243          // requireNonNull is safe now, just as it was above.
244          requireNonNull(runningTask).cancel(false); // prevent future invocations.
245        } finally {
246          lock.unlock();
247        }
248      }
249    }
250
251    private final Runnable task = new Task();
252
253    @Override
254    protected final void doStart() {
255      executorService =
256          MoreExecutors.renamingDecorator(
257              executor(),
258              new Supplier<String>() {
259                @Override
260                public String get() {
261                  return serviceName() + " " + state();
262                }
263              });
264      executorService.execute(
265          new Runnable() {
266            @Override
267            public void run() {
268              lock.lock();
269              try {
270                startUp();
271                runningTask = scheduler().schedule(delegate, executorService, task);
272                notifyStarted();
273              } catch (Throwable t) {
274                notifyFailed(t);
275                if (runningTask != null) {
276                  // prevent the task from running if possible
277                  runningTask.cancel(false);
278                }
279              } finally {
280                lock.unlock();
281              }
282            }
283          });
284    }
285
286    @Override
287    protected final void doStop() {
288      // Both requireNonNull calls are safe because doStop can run only after a successful doStart.
289      requireNonNull(runningTask);
290      requireNonNull(executorService);
291      runningTask.cancel(false);
292      executorService.execute(
293          new Runnable() {
294            @Override
295            public void run() {
296              try {
297                lock.lock();
298                try {
299                  if (state() != State.STOPPING) {
300                    // This means that the state has changed since we were scheduled. This implies
301                    // that an execution of runOneIteration has thrown an exception and we have
302                    // transitioned to a failed state, also this means that shutDown has already
303                    // been called, so we do not want to call it again.
304                    return;
305                  }
306                  shutDown();
307                } finally {
308                  lock.unlock();
309                }
310                notifyStopped();
311              } catch (Throwable t) {
312                notifyFailed(t);
313              }
314            }
315          });
316    }
317
318    @Override
319    public String toString() {
320      return AbstractScheduledService.this.toString();
321    }
322  }
323
324  /** Constructor for use by subclasses. */
325  protected AbstractScheduledService() {}
326
327  /**
328   * Run one iteration of the scheduled task. If any invocation of this method throws an exception,
329   * the service will transition to the {@link Service.State#FAILED} state and this method will no
330   * longer be called.
331   */
332  protected abstract void runOneIteration() throws Exception;
333
334  /**
335   * Start the service.
336   *
337   * <p>By default this method does nothing.
338   */
339  protected void startUp() throws Exception {}
340
341  /**
342   * Stop the service. This is guaranteed not to run concurrently with {@link #runOneIteration}.
343   *
344   * <p>By default this method does nothing.
345   */
346  protected void shutDown() throws Exception {}
347
348  /**
349   * Returns the {@link Scheduler} object used to configure this service. This method will only be
350   * called once.
351   */
352  // TODO(cpovirk): @ForOverride
353  protected abstract Scheduler scheduler();
354
355  /**
356   * Returns the {@link ScheduledExecutorService} that will be used to execute the {@link #startUp},
357   * {@link #runOneIteration} and {@link #shutDown} methods. If this method is overridden the
358   * executor will not be {@linkplain ScheduledExecutorService#shutdown shutdown} when this service
359   * {@linkplain Service.State#TERMINATED terminates} or {@linkplain Service.State#TERMINATED
360   * fails}. Subclasses may override this method to supply a custom {@link ScheduledExecutorService}
361   * instance. This method is guaranteed to only be called once.
362   *
363   * <p>By default this returns a new {@link ScheduledExecutorService} with a single thread pool
364   * that sets the name of the thread to the {@linkplain #serviceName() service name}. Also, the
365   * pool will be {@linkplain ScheduledExecutorService#shutdown() shut down} when the service
366   * {@linkplain Service.State#TERMINATED terminates} or {@linkplain Service.State#TERMINATED
367   * fails}.
368   */
369  protected ScheduledExecutorService executor() {
370    @WeakOuter
371    class ThreadFactoryImpl implements ThreadFactory {
372      @Override
373      public Thread newThread(Runnable runnable) {
374        return MoreExecutors.newThread(serviceName(), runnable);
375      }
376    }
377    final ScheduledExecutorService executor =
378        Executors.newSingleThreadScheduledExecutor(new ThreadFactoryImpl());
379    // Add a listener to shutdown the executor after the service is stopped. This ensures that the
380    // JVM shutdown will not be prevented from exiting after this service has stopped or failed.
381    // Technically this listener is added after start() was called so it is a little gross, but it
382    // is called within doStart() so we know that the service cannot terminate or fail concurrently
383    // with adding this listener so it is impossible to miss an event that we are interested in.
384    addListener(
385        new Listener() {
386          @Override
387          public void terminated(State from) {
388            executor.shutdown();
389          }
390
391          @Override
392          public void failed(State from, Throwable failure) {
393            executor.shutdown();
394          }
395        },
396        directExecutor());
397    return executor;
398  }
399
400  /**
401   * Returns the name of this service. {@link AbstractScheduledService} may include the name in
402   * debugging output.
403   *
404   * @since 14.0
405   */
406  protected String serviceName() {
407    return getClass().getSimpleName();
408  }
409
410  @Override
411  public String toString() {
412    return serviceName() + " [" + state() + "]";
413  }
414
415  @Override
416  public final boolean isRunning() {
417    return delegate.isRunning();
418  }
419
420  @Override
421  public final State state() {
422    return delegate.state();
423  }
424
425  /** @since 13.0 */
426  @Override
427  public final void addListener(Listener listener, Executor executor) {
428    delegate.addListener(listener, executor);
429  }
430
431  /** @since 14.0 */
432  @Override
433  public final Throwable failureCause() {
434    return delegate.failureCause();
435  }
436
437  /** @since 15.0 */
438  @CanIgnoreReturnValue
439  @Override
440  public final Service startAsync() {
441    delegate.startAsync();
442    return this;
443  }
444
445  /** @since 15.0 */
446  @CanIgnoreReturnValue
447  @Override
448  public final Service stopAsync() {
449    delegate.stopAsync();
450    return this;
451  }
452
453  /** @since 15.0 */
454  @Override
455  public final void awaitRunning() {
456    delegate.awaitRunning();
457  }
458
459  /** @since 28.0 */
460  @Override
461  public final void awaitRunning(Duration timeout) throws TimeoutException {
462    Service.super.awaitRunning(timeout);
463  }
464
465  /** @since 15.0 */
466  @Override
467  public final void awaitRunning(long timeout, TimeUnit unit) throws TimeoutException {
468    delegate.awaitRunning(timeout, unit);
469  }
470
471  /** @since 15.0 */
472  @Override
473  public final void awaitTerminated() {
474    delegate.awaitTerminated();
475  }
476
477  /** @since 28.0 */
478  @Override
479  public final void awaitTerminated(Duration timeout) throws TimeoutException {
480    Service.super.awaitTerminated(timeout);
481  }
482
483  /** @since 15.0 */
484  @Override
485  public final void awaitTerminated(long timeout, TimeUnit unit) throws TimeoutException {
486    delegate.awaitTerminated(timeout, unit);
487  }
488
489  interface Cancellable {
490    void cancel(boolean mayInterruptIfRunning);
491
492    boolean isCancelled();
493  }
494
495  private static final class FutureAsCancellable implements Cancellable {
496    private final Future<?> delegate;
497
498    FutureAsCancellable(Future<?> delegate) {
499      this.delegate = delegate;
500    }
501
502    @Override
503    public void cancel(boolean mayInterruptIfRunning) {
504      delegate.cancel(mayInterruptIfRunning);
505    }
506
507    @Override
508    public boolean isCancelled() {
509      return delegate.isCancelled();
510    }
511  }
512
513  /**
514   * A {@link Scheduler} that provides a convenient way for the {@link AbstractScheduledService} to
515   * use a dynamically changing schedule. After every execution of the task, assuming it hasn't been
516   * cancelled, the {@link #getNextSchedule} method will be called.
517   *
518   * @author Luke Sandberg
519   * @since 11.0
520   */
521  public abstract static class CustomScheduler extends Scheduler {
522
523    /** A callable class that can reschedule itself using a {@link CustomScheduler}. */
524    private final class ReschedulableCallable implements Callable<@Nullable Void> {
525
526      /** The underlying task. */
527      private final Runnable wrappedRunnable;
528
529      /** The executor on which this Callable will be scheduled. */
530      private final ScheduledExecutorService executor;
531
532      /**
533       * The service that is managing this callable. This is used so that failure can be reported
534       * properly.
535       */
536      /*
537       * This reference is part of a reference cycle, which is typically something we want to avoid
538       * under j2objc -- but it is not detected by our j2objc cycle test. The cycle:
539       *
540       * - CustomScheduler.service contains an instance of ServiceDelegate. (It needs it so that it
541       *   can call notifyFailed.)
542       *
543       * - ServiceDelegate.runningTask contains an instance of ReschedulableCallable (at least in
544       *   the case that the service is using CustomScheduler). (It needs it so that it can cancel
545       *   the task and detect whether it has been cancelled.)
546       *
547       * - ReschedulableCallable has a reference back to its enclosing CustomScheduler. (It needs it
548       *   so that it can call getNextSchedule).
549       *
550       * Maybe there is a way to avoid this cycle. But we think the cycle is safe enough to ignore:
551       * Each task is retained for only as long as it is running -- so it's retained only as long as
552       * it would already be retained by the underlying executor.
553       *
554       * If the cycle test starts reporting this cycle in the future, we should add an entry to
555       * cycle_suppress_list.txt.
556       */
557      private final AbstractService service;
558
559      /**
560       * This lock is used to ensure safe and correct cancellation, it ensures that a new task is
561       * not scheduled while a cancel is ongoing. Also it protects the currentFuture variable to
562       * ensure that it is assigned atomically with being scheduled.
563       */
564      private final ReentrantLock lock = new ReentrantLock();
565
566      /** The future that represents the next execution of this task. */
567      @GuardedBy("lock")
568      @CheckForNull
569      private SupplantableFuture cancellationDelegate;
570
571      ReschedulableCallable(
572          AbstractService service, ScheduledExecutorService executor, Runnable runnable) {
573        this.wrappedRunnable = runnable;
574        this.executor = executor;
575        this.service = service;
576      }
577
578      @Override
579      @CheckForNull
580      public Void call() throws Exception {
581        wrappedRunnable.run();
582        reschedule();
583        return null;
584      }
585
586      /**
587       * Atomically reschedules this task and assigns the new future to {@link
588       * #cancellationDelegate}.
589       */
590      @CanIgnoreReturnValue
591      public Cancellable reschedule() {
592        // invoke the callback outside the lock, prevents some shenanigans.
593        Schedule schedule;
594        try {
595          schedule = CustomScheduler.this.getNextSchedule();
596        } catch (Throwable t) {
597          service.notifyFailed(t);
598          return new FutureAsCancellable(immediateCancelledFuture());
599        }
600        // We reschedule ourselves with a lock held for two reasons. 1. we want to make sure that
601        // cancel calls cancel on the correct future. 2. we want to make sure that the assignment
602        // to currentFuture doesn't race with itself so that currentFuture is assigned in the
603        // correct order.
604        Throwable scheduleFailure = null;
605        Cancellable toReturn;
606        lock.lock();
607        try {
608          toReturn = initializeOrUpdateCancellationDelegate(schedule);
609        } catch (Throwable e) {
610          // If an exception is thrown by the subclass then we need to make sure that the service
611          // notices and transitions to the FAILED state. We do it by calling notifyFailed directly
612          // because the service does not monitor the state of the future so if the exception is not
613          // caught and forwarded to the service the task would stop executing but the service would
614          // have no idea.
615          // TODO(lukes): consider building everything in terms of ListenableScheduledFuture then
616          // the AbstractService could monitor the future directly. Rescheduling is still hard...
617          // but it would help with some of these lock ordering issues.
618          scheduleFailure = e;
619          toReturn = new FutureAsCancellable(immediateCancelledFuture());
620        } finally {
621          lock.unlock();
622        }
623        // Call notifyFailed outside the lock to avoid lock ordering issues.
624        if (scheduleFailure != null) {
625          service.notifyFailed(scheduleFailure);
626        }
627        return toReturn;
628      }
629
630      @GuardedBy("lock")
631      /*
632       * The GuardedBy checker warns us that we're not holding cancellationDelegate.lock. But in
633       * fact we are holding it because it is the same as this.lock, which we know we are holding,
634       * thanks to @GuardedBy above. (cancellationDelegate.lock is initialized to this.lock in the
635       * call to `new SupplantableFuture` below.)
636       */
637      @SuppressWarnings("GuardedBy")
638      private Cancellable initializeOrUpdateCancellationDelegate(Schedule schedule) {
639        if (cancellationDelegate == null) {
640          return cancellationDelegate = new SupplantableFuture(lock, submitToExecutor(schedule));
641        }
642        if (!cancellationDelegate.currentFuture.isCancelled()) {
643          cancellationDelegate.currentFuture = submitToExecutor(schedule);
644        }
645        return cancellationDelegate;
646      }
647
648      private ScheduledFuture<@Nullable Void> submitToExecutor(Schedule schedule) {
649        return executor.schedule(this, schedule.delay, schedule.unit);
650      }
651    }
652
653    /**
654     * Contains the most recently submitted {@code Future}, which may be cancelled or updated,
655     * always under a lock.
656     */
657    private static final class SupplantableFuture implements Cancellable {
658      private final ReentrantLock lock;
659
660      @GuardedBy("lock")
661      private Future<@Nullable Void> currentFuture;
662
663      SupplantableFuture(ReentrantLock lock, Future<@Nullable Void> currentFuture) {
664        this.lock = lock;
665        this.currentFuture = currentFuture;
666      }
667
668      @Override
669      public void cancel(boolean mayInterruptIfRunning) {
670        /*
671         * Lock to ensure that a task cannot be rescheduled while a cancel is ongoing.
672         *
673         * In theory, cancel() could execute arbitrary listeners -- bad to do while holding a lock.
674         * However, we don't expose currentFuture to users, so they can't attach listeners. And the
675         * Future might not even be a ListenableFuture, just a plain Future. That said, similar
676         * problems can exist with methods like FutureTask.done(), not to mention slow calls to
677         * Thread.interrupt() (as discussed in InterruptibleTask). At the end of the day, it's
678         * unlikely that cancel() will be slow, so we can probably get away with calling it while
679         * holding a lock. Still, it would be nice to avoid somehow.
680         */
681        lock.lock();
682        try {
683          currentFuture.cancel(mayInterruptIfRunning);
684        } finally {
685          lock.unlock();
686        }
687      }
688
689      @Override
690      public boolean isCancelled() {
691        lock.lock();
692        try {
693          return currentFuture.isCancelled();
694        } finally {
695          lock.unlock();
696        }
697      }
698    }
699
700    @Override
701    final Cancellable schedule(
702        AbstractService service, ScheduledExecutorService executor, Runnable runnable) {
703      return new ReschedulableCallable(service, executor, runnable).reschedule();
704    }
705
706    /**
707     * A value object that represents an absolute delay until a task should be invoked.
708     *
709     * @author Luke Sandberg
710     * @since 11.0
711     */
712    protected static final class Schedule {
713
714      private final long delay;
715      private final TimeUnit unit;
716
717      /**
718       * @param delay the time from now to delay execution
719       * @param unit the time unit of the delay parameter
720       */
721      public Schedule(long delay, TimeUnit unit) {
722        this.delay = delay;
723        this.unit = checkNotNull(unit);
724      }
725    }
726
727    /**
728     * Calculates the time at which to next invoke the task.
729     *
730     * <p>This is guaranteed to be called immediately after the task has completed an iteration and
731     * on the same thread as the previous execution of {@link
732     * AbstractScheduledService#runOneIteration}.
733     *
734     * @return a schedule that defines the delay before the next execution.
735     */
736    // TODO(cpovirk): @ForOverride
737    protected abstract Schedule getNextSchedule() throws Exception;
738  }
739}