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/*
 * Copyright (c) 2016-present, RxJava Contributors.
 *
 * 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 io.reactivex.rxjava3.internal.schedulers;

import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.*;

import io.reactivex.rxjava3.annotations.NonNull;
import io.reactivex.rxjava3.core.*;
import io.reactivex.rxjava3.disposables.*;
import io.reactivex.rxjava3.functions.Function;
import io.reactivex.rxjava3.internal.util.ExceptionHelper;
import io.reactivex.rxjava3.processors.*;

/**
 * Allows the use of operators for controlling the timing around when actions
 * scheduled on workers are actually done. This makes it possible to layer
 * additional behavior on this {@link Scheduler}. The only parameter is a
 * function that flattens an {@link Observable} of {@link Observable} of
 * {@link Completable}s into just one {@link Completable}. There must be a chain
 * of operators connecting the returned value to the source {@link Observable}
 * otherwise any work scheduled on the returned {@link Scheduler} will not be
 * executed.
 * 

* When {@link Scheduler#createWorker()} is invoked a {@link Observable} of * {@link Completable}s is onNext'd to the combinator to be flattened. If the * inner {@link Observable} is not immediately subscribed to an calls to * {@link Worker#schedule} are buffered. Once the {@link Observable} is * subscribed to actions are then onNext'd as {@link Completable}s. *

* Finally the actions scheduled on the parent {@link Scheduler} when the inner * most {@link Completable}s are subscribed to. *

* When the {@link io.reactivex.rxjava3.core.Scheduler.Worker Worker} is unsubscribed the {@link Completable} emits an * onComplete and triggers any behavior in the flattening operator. The * {@link Observable} and all {@link Completable}s give to the flattening * function never onError. *

* Limit the amount concurrency two at a time without creating a new fix size * thread pool: * *

 * {@code
 * Scheduler limitScheduler = Schedulers.computation().when(workers -> {
 *  // use merge max concurrent to limit the number of concurrent
 *  // callbacks two at a time
 *  return Completable.merge(Observable.merge(workers), 2);
 * });
 * }
 * 
*

* This is a slightly different way to limit the concurrency but it has some * interesting benefits and drawbacks to the method above. It works by limited * the number of concurrent {@link io.reactivex.rxjava3.core.Scheduler.Worker Worker}s rather than individual actions. * Generally each {@link Observable} uses its own {@link io.reactivex.rxjava3.core.Scheduler.Worker Worker}. This means * that this will essentially limit the number of concurrent subscribes. The * danger comes from using operators like * {@link Flowable#zip(org.reactivestreams.Publisher, org.reactivestreams.Publisher, io.reactivex.rxjava3.functions.BiFunction)} where * subscribing to the first {@link Observable} could deadlock the subscription * to the second. * *

 * {@code
 * Scheduler limitScheduler = Schedulers.computation().when(workers -> {
 *  // use merge max concurrent to limit the number of concurrent
 *  // Observables two at a time
 *  return Completable.merge(Observable.merge(workers, 2));
 * });
 * }
 * 
* * Slowing down the rate to no more than than 1 a second. This suffers from the * same problem as the one above I could find an {@link Observable} operator * that limits the rate without dropping the values (aka leaky bucket * algorithm). * *
 * {@code
 * Scheduler slowScheduler = Schedulers.computation().when(workers -> {
 *  // use concatenate to make each worker happen one at a time.
 *  return Completable.concat(workers.map(actions -> {
 *      // delay the starting of the next worker by 1 second.
 *      return Completable.merge(actions.delaySubscription(1, TimeUnit.SECONDS));
 *  }));
 * });
 * }
 * 
*

History 2.0.1 - experimental * @since 2.1 */ public class SchedulerWhen extends Scheduler implements Disposable { private final Scheduler actualScheduler; private final FlowableProcessor> workerProcessor; private Disposable disposable; public SchedulerWhen(Function>, Completable> combine, Scheduler actualScheduler) { this.actualScheduler = actualScheduler; // workers are converted into completables and put in this queue. this.workerProcessor = UnicastProcessor.>create().toSerialized(); // send it to a custom combinator to pick the order and rate at which // workers are processed. try { disposable = combine.apply(workerProcessor).subscribe(); } catch (Throwable e) { throw ExceptionHelper.wrapOrThrow(e); } } @Override public void dispose() { disposable.dispose(); } @Override public boolean isDisposed() { return disposable.isDisposed(); } @NonNull @Override public Worker createWorker() { final Worker actualWorker = actualScheduler.createWorker(); // a queue for the actions submitted while worker is waiting to get to // the subscribe to off the workerQueue. final FlowableProcessor actionProcessor = UnicastProcessor.create().toSerialized(); // convert the work of scheduling all the actions into a completable Flowable actions = actionProcessor.map(new CreateWorkerFunction(actualWorker)); // a worker that queues the action to the actionQueue subject. Worker worker = new QueueWorker(actionProcessor, actualWorker); // enqueue the completable that process actions put in reply subject workerProcessor.onNext(actions); // return the worker that adds actions to the reply subject return worker; } static final Disposable SUBSCRIBED = new SubscribedDisposable(); static final Disposable DISPOSED = Disposable.disposed(); @SuppressWarnings("serial") abstract static class ScheduledAction extends AtomicReference implements Disposable { ScheduledAction() { super(SUBSCRIBED); } void call(Worker actualWorker, CompletableObserver actionCompletable) { Disposable oldState = get(); // either SUBSCRIBED or UNSUBSCRIBED if (oldState == DISPOSED) { // no need to schedule return return; } if (oldState != SUBSCRIBED) { // has already been scheduled return // should not be able to get here but handle it anyway by not // rescheduling. return; } Disposable newState = callActual(actualWorker, actionCompletable); if (!compareAndSet(SUBSCRIBED, newState)) { // set would only fail if the new current state is some other // subscription from a concurrent call to this method. // Unsubscribe from the action just scheduled because it lost // the race. newState.dispose(); } } protected abstract Disposable callActual(Worker actualWorker, CompletableObserver actionCompletable); @Override public boolean isDisposed() { return get().isDisposed(); } @Override public void dispose() { getAndSet(DISPOSED).dispose(); } } @SuppressWarnings("serial") static class ImmediateAction extends ScheduledAction { private final Runnable action; ImmediateAction(Runnable action) { this.action = action; } @Override protected Disposable callActual(Worker actualWorker, CompletableObserver actionCompletable) { return actualWorker.schedule(new OnCompletedAction(action, actionCompletable)); } } @SuppressWarnings("serial") static class DelayedAction extends ScheduledAction { private final Runnable action; private final long delayTime; private final TimeUnit unit; DelayedAction(Runnable action, long delayTime, TimeUnit unit) { this.action = action; this.delayTime = delayTime; this.unit = unit; } @Override protected Disposable callActual(Worker actualWorker, CompletableObserver actionCompletable) { return actualWorker.schedule(new OnCompletedAction(action, actionCompletable), delayTime, unit); } } static class OnCompletedAction implements Runnable { final CompletableObserver actionCompletable; final Runnable action; OnCompletedAction(Runnable action, CompletableObserver actionCompletable) { this.action = action; this.actionCompletable = actionCompletable; } @Override public void run() { try { action.run(); } finally { actionCompletable.onComplete(); } } } static final class CreateWorkerFunction implements Function { final Worker actualWorker; CreateWorkerFunction(Worker actualWorker) { this.actualWorker = actualWorker; } @Override public Completable apply(final ScheduledAction action) { return new WorkerCompletable(action); } final class WorkerCompletable extends Completable { final ScheduledAction action; WorkerCompletable(ScheduledAction action) { this.action = action; } @Override protected void subscribeActual(CompletableObserver actionCompletable) { actionCompletable.onSubscribe(action); action.call(actualWorker, actionCompletable); } } } static final class QueueWorker extends Worker { private final AtomicBoolean unsubscribed; private final FlowableProcessor actionProcessor; private final Worker actualWorker; QueueWorker(FlowableProcessor actionProcessor, Worker actualWorker) { this.actionProcessor = actionProcessor; this.actualWorker = actualWorker; unsubscribed = new AtomicBoolean(); } @Override public void dispose() { // complete the actionQueue when worker is unsubscribed to make // room for the next worker in the workerQueue. if (unsubscribed.compareAndSet(false, true)) { actionProcessor.onComplete(); actualWorker.dispose(); } } @Override public boolean isDisposed() { return unsubscribed.get(); } @NonNull @Override public Disposable schedule(@NonNull final Runnable action, final long delayTime, @NonNull final TimeUnit unit) { // send a scheduled action to the actionQueue DelayedAction delayedAction = new DelayedAction(action, delayTime, unit); actionProcessor.onNext(delayedAction); return delayedAction; } @NonNull @Override public Disposable schedule(@NonNull final Runnable action) { // send a scheduled action to the actionQueue ImmediateAction immediateAction = new ImmediateAction(action); actionProcessor.onNext(immediateAction); return immediateAction; } } static final class SubscribedDisposable implements Disposable { @Override public void dispose() { } @Override public boolean isDisposed() { return false; } } }





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