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//
// ========================================================================
// Copyright (c) 1995 Mort Bay Consulting Pty Ltd and others.
//
// This program and the accompanying materials are made available under the
// terms of the Eclipse Public License v. 2.0 which is available at
// https://www.eclipse.org/legal/epl-2.0, or the Apache License, Version 2.0
// which is available at https://www.apache.org/licenses/LICENSE-2.0.
//
// SPDX-License-Identifier: EPL-2.0 OR Apache-2.0
// ========================================================================
//

package org.eclipse.jetty.util.thread.strategy;

import java.util.concurrent.Executor;

import org.eclipse.jetty.util.thread.AutoLock;
import org.eclipse.jetty.util.thread.ExecutionStrategy;
import org.eclipse.jetty.util.thread.Invocable;
import org.eclipse.jetty.util.thread.Invocable.InvocationType;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

/**
 * 

A strategy where the thread that produces will always run the resulting task.

*

The strategy may then dispatch another thread to continue production.

*

The strategy is also known by the nickname 'eat what you kill', which comes from * the hunting ethic that says a person should not kill anything he or she does not * plan on eating. In this case, the phrase is used to mean that a thread should * not produce a task that it does not intend to run. By making producers run the * task that they have just produced avoids execution delays and avoids parallel slow * down by running the task in the same core, with good chances of having a hot CPU * cache. It also avoids the creation of a queue of produced tasks that the system * does not yet have capacity to consume, which can save memory and exert back * pressure on producers.

*/ public class ExecuteProduceConsume implements ExecutionStrategy, Runnable { private static final Logger LOG = LoggerFactory.getLogger(ExecuteProduceConsume.class); private final AutoLock _lock = new AutoLock(); private final Runnable _runProduce = new RunProduce(); private final Producer _producer; private final Executor _executor; private boolean _idle = true; private boolean _execute; private boolean _producing; private boolean _pending; public ExecuteProduceConsume(Producer producer, Executor executor) { this._producer = producer; _executor = executor; } @Override public void produce() { if (LOG.isDebugEnabled()) LOG.debug("{} execute", this); boolean produce = false; try (AutoLock lock = _lock.lock()) { // If we are idle and a thread is not producing if (_idle) { if (_producing) throw new IllegalStateException(); // Then this thread will do the producing produce = _producing = true; // and we are no longer idle _idle = false; } else { // Otherwise, lets tell the producing thread // that it should call produce again before going idle _execute = true; } } if (produce) produceConsume(); } @Override public void dispatch() { if (LOG.isDebugEnabled()) LOG.debug("{} spawning", this); boolean dispatch = false; try (AutoLock lock = _lock.lock()) { if (_idle) dispatch = true; else _execute = true; } if (dispatch) _executor.execute(_runProduce); } @Override public void run() { if (LOG.isDebugEnabled()) LOG.debug("{} run", this); boolean produce = false; try (AutoLock lock = _lock.lock()) { _pending = false; if (!_idle && !_producing) { produce = _producing = true; } } if (produce) produceConsume(); } private void produceConsume() { if (LOG.isDebugEnabled()) LOG.debug("{} produce enter", this); while (true) { // If we got here, then we are the thread that is producing. if (LOG.isDebugEnabled()) LOG.debug("{} producing", this); Runnable task = _producer.produce(); if (LOG.isDebugEnabled()) LOG.debug("{} produced {}", this, task); boolean dispatch = false; try (AutoLock lock = _lock.lock()) { // Finished producing _producing = false; // Did we produced a task? if (task == null) { // There is no task. // Could another one just have been queued with an execute? if (_execute) { _idle = false; _producing = true; _execute = false; continue; } // ... and no additional calls to execute, so we are idle _idle = true; break; } // We have a task, which we will run ourselves, // so if we don't have another thread pending if (!_pending) { // dispatch one dispatch = _pending = Invocable.getInvocationType(task) != InvocationType.NON_BLOCKING; } _execute = false; } // If we became pending if (dispatch) { // Spawn a new thread to continue production by running the produce loop. if (LOG.isDebugEnabled()) LOG.debug("{} dispatch", this); _executor.execute(this); } // Run the task. if (LOG.isDebugEnabled()) LOG.debug("{} run {}", this, task); task.run(); if (LOG.isDebugEnabled()) LOG.debug("{} ran {}", this, task); // Once we have run the task, we can try producing again. try (AutoLock lock = _lock.lock()) { // Is another thread already producing or we are now idle? if (_producing || _idle) break; _producing = true; } } if (LOG.isDebugEnabled()) LOG.debug("{} produce exit", this); } public Boolean isIdle() { try (AutoLock lock = _lock.lock()) { return _idle; } } @Override public String toString() { StringBuilder builder = new StringBuilder(); builder.append("EPC "); try (AutoLock lock = _lock.lock()) { builder.append(_idle ? "Idle/" : ""); builder.append(_producing ? "Prod/" : ""); builder.append(_pending ? "Pend/" : ""); builder.append(_execute ? "Exec/" : ""); } builder.append(_producer); return builder.toString(); } private class RunProduce implements Runnable { @Override public void run() { produce(); } } }




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