java.util.concurrent.Exchanger应用范例与原理浅析--转载
一、简介
Exchanger是自jdk1.5起开始提供的工具套件,一般用于两个工作线程之间交换数据。在本文中我将采取由浅入深的方式来介绍分析这个工具类。首先我们来看看官方的api文档中的叙述:
A synchronization point at which threads can pair and swap elements within pairs. Each thread presents some object on entry to the exchange method, matches with a partner thread, and receives its partner's object on return. An Exchanger may be viewed as a bidirectional form of a SynchronousQueue. Exchangers may be useful in applications such as genetic algorithms and pipeline designs.
在以上的描述中,有几个要点:
- 此类提供对外的操作是同步的;
- 用于成对出现的线程之间交换数据;
- 可以视作双向的同步队列;
- 可应用于基因算法、流水线设计等场景。
接着看api文档,这个类提供对外的接口非常简洁,一个无参构造函数,两个重载的范型exchange方法:
public V exchange(V x) throws InterruptedException
public V exchange(V x, long timeout, TimeUnit unit) throws InterruptedException, TimeoutException
从官方的javadoc可以知道,当一个线程到达exchange调用点时,如果它的伙伴线程此前已经调用了此方法,那么它的伙伴会被调度唤醒并与之进行对象交换,然后各自返回。如果它的伙伴还没到达交换点,那么当前线程将会被挂起,直至伙伴线程到达——完成交换正常返回;或者当前线程被中断——抛出中断异常;又或者是等候超时——抛出超时异常。
二、一个简单的例子
按照某大师的观点,行为知之先,在知道了Exchanger的大致用途并参阅了使用说明后,我们马上动手写个例子来跑一跑:
import java.util.concurrent.Exchanger;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.TimeUnit;
import org.apache.log4j.Logger;
/**
* @Title: ExchangerTest
* @Description: Test class for Exchanger
* @Company: CSAIR
* @Author: lixuanbin
* @Creation: 2014年12月14日
* @Version:1.0
*/
public class ExchangerTest {
protected static final Logger log = Logger.getLogger(ExchangerTest.class);
private static volatile boolean isDone = false;
static class ExchangerProducer implements Runnable {
private Exchanger<Integer> exchanger;
private static int data = 1;
ExchangerProducer(Exchanger<Integer> exchanger) {
this.exchanger = exchanger;
}
@Override
public void run() {
while (!Thread.interrupted() && !isDone) {
for (int i = 1; i <= 3; i++) {
try {
TimeUnit.SECONDS.sleep(1);
data = i;
System.out.println("producer before: " + data);
data = exchanger.exchange(data);
System.out.println("producer after: " + data);
} catch (InterruptedException e) {
log.error(e, e);
}
}
isDone = true;
}
}
}
static class ExchangerConsumer implements Runnable {
private Exchanger<Integer> exchanger;
private static int data = 0;
ExchangerConsumer(Exchanger<Integer> exchanger) {
this.exchanger = exchanger;
}
@Override
public void run() {
while (!Thread.interrupted() && !isDone) {
data = 0;
System.out.println("consumer before : " + data);
try {
TimeUnit.SECONDS.sleep(1);
data = exchanger.exchange(data);
} catch (InterruptedException e) {
log.error(e, e);
}
System.out.println("consumer after : " + data);
}
}
}
/**
* @param args
*/
public static void main(String[] args) {
ExecutorService exec = Executors.newCachedThreadPool();
Exchanger<Integer> exchanger = new Exchanger<Integer>();
ExchangerProducer producer = new ExchangerProducer(exchanger);
ExchangerConsumer consumer = new ExchangerConsumer(exchanger);
exec.execute(producer);
exec.execute(consumer);
exec.shutdown();
try {
exec.awaitTermination(30, TimeUnit.SECONDS);
} catch (InterruptedException e) {
log.error(e, e);
}
}
} 这大致可以看作是一个简易的生产者消费者模型,有两个任务类,一个递增地产生整数,一个产生整数0,然后双方进行交易。每次交易前的生产者和每次交易后的消费者都会sleep 1秒来模拟数据处理的消耗,并在交易前后把整数值打印到控制台以便检测结果。在这个例子里交易循环只执行三次,采用一个volatile boolean来控制交易双方线程的退出。
我们来看看程序的输出:
consumer before : 0
producer before: 1
consumer after : 1
producer after: 0
consumer before : 0
producer before: 2
producer after: 0
consumer after : 2
consumer before : 0
producer before: 3
producer after: 0
consumer after : 3
输出结果验证了以下两件事情:
- exchange方法真的帮一对线程交换了数据;
- exchange方法真的会阻塞调用方线程直至另一方线程参与交易。
那么在中断和超时两种情况下程序的运行表现会是怎样呢?作为一个小练习,有兴趣的观众可以设想并编写测试用例覆盖验证之。接下来谈谈最近我在生产场景中对Exchanger的应用。