java并发包——CyclicBarrier（可重用栅栏）

1. CyclicBarrier的介绍与源码分析

CyclicBarrier 的字面意思是可循环（Cyclic）使用的屏障（Barrier）。它要做的事情是，让一组线程到达一个屏障（也可以叫同步点）时被阻塞，直到最后一个线程到达屏障时，屏障才会开门，所有被屏障拦截的线程才会继续干活。线程进入屏障通过CyclicBarrier的await()方法。

CyclicBarrier默认的构造方法是CyclicBarrier(int parties)，其参数表示屏障拦截的线程数量，每个线程调用await方法告诉CyclicBarrier我已经到达了屏障，然后当前线程被阻塞。

CyclicBarrier还提供一个更高级的构造函数CyclicBarrier(int parties, Runnable barrierAction)，用于在线程到达屏障时，优先执行barrierAction这个Runnable对象，方便处理更复杂的业务场景。

构造函数

 

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public CyclicBarrier(int parties) {     this(parties, null); } public int getParties() {     return parties; }

实现原理：在CyclicBarrier的内部定义了一个Lock对象，每当一个线程调用CyclicBarrier的await方法时，将剩余拦截的线程数减1，然后判断剩余拦截数是否为0，如果不是，进入Lock对象的条件队列等待。如果是，执行barrierAction对象的Runnable方法，然后将锁的条件队列中的所有线程放入锁等待队列中，这些线程会依次的获取锁、释放锁，接着先从await方法返回，再从CyclicBarrier的await方法中返回。

await源码

 

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public int await() throws InterruptedException, BrokenBarrierException {     try {         return dowait(false, 0L);     } catch (TimeoutException toe) {         throw new Error(toe); // cannot happen     } }

 

dowait源码

 

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private int dowait(boolean timed, long nanos)     throws InterruptedException, BrokenBarrierException,            TimeoutException {     final ReentrantLock lock = this.lock;     lock.lock();     try {         final Generation g = generation;           if (g.broken)             throw new BrokenBarrierException();           if (Thread.interrupted()) {             breakBarrier();             throw new InterruptedException();         }           int index = --count;         if (index == 0) {  // tripped             boolean ranAction = false;             try {                 final Runnable command = barrierCommand;                 if (command != null)                     command.run();                 ranAction = true;                 nextGeneration();                 return 0;             } finally {                 if (!ranAction)                     breakBarrier();             }         }           // loop until tripped, broken, interrupted, or timed out         for (;;) {             try {                 if (!timed)                     trip.await();                 else if (nanos > 0L)                     nanos = trip.awaitNanos(nanos);             } catch (InterruptedException ie) {                 if (g == generation && ! g.broken) {                     breakBarrier();                     throw ie;                 } else {                     // We're about to finish waiting even if we had not                     // been interrupted, so this interrupt is deemed to                     // "belong" to subsequent execution.                     Thread.currentThread().interrupt();                 }             }               if (g.broken)                 throw new BrokenBarrierException();               if (g != generation)                 return index;               if (timed && nanos <= 0L) {                 breakBarrier();                 throw new TimeoutException();             }         }     } finally {         lock.unlock();     } }

当最后一个线程到达屏障点，也就是执行dowait方法时，会在return 0 返回之前调用finally块中的breakBarrier方法。

breakBarrier源代码

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private void breakBarrier() {     generation.broken = true;     count = parties;     trip.signalAll(); }

 

CyclicBarrier主要用于一组线程之间的相互等待，而CountDownLatch一般用于一组线程等待另一组些线程。实际上可以通过CountDownLatch的countDown()和await()来实现CyclicBarrier的功能。即 CountDownLatch中的countDown()+await() = CyclicBarrier中的await()。注意：在一个线程中先调用countDown()，然后调用await()。

其它方法：CycliBarrier对象可以重复使用，重用之前应当调用CyclicBarrier对象的reset方法。

reset源码

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public void reset() {     final ReentrantLock lock = this.lock;     lock.lock();     try {         breakBarrier();   // break the current generation         nextGeneration(); // start a new generation     } finally {         lock.unlock();     } }

 

2. 使用示例

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package javalearning;   import java.util.Random; import java.util.concurrent.BrokenBarrierException; import java.util.concurrent.CyclicBarrier; import java.util.concurrent.ExecutorService; import java.util.concurrent.Executors;   public class CyclicBarrierDemo {     private CyclicBarrier cb = new CyclicBarrier(4);     private Random rnd = new Random();           class TaskDemo implements Runnable{         private String id;         TaskDemo(String id){             this.id = id;         }         @Override         public void run(){             try {                 Thread.sleep(rnd.nextInt(1000));                 System.out.println("Thread " + id + " will wait");                 cb.await();                 System.out.println("-------Thread " + id + " is over");             } catch (InterruptedException e) {             } catch (BrokenBarrierException e) {             }         }     }           public static void main(String[] args){         CyclicBarrierDemo cbd = new CyclicBarrierDemo();         ExecutorService es = Executors.newCachedThreadPool();         es.submit(cbd.new TaskDemo("a"));         es.submit(cbd.new TaskDemo("b"));         es.submit(cbd.new TaskDemo("c"));         es.submit(cbd.new TaskDemo("d"));         es.shutdown();     } }

 

在这个示例中，我们创建了四个线程a、b、c、d，这四个线程提交给了线程池。四个线程不同时间到达cb.await()语句，当四个线程都输出“Thread x will wait”以后才会输出“Thread x is over”。

运行结果

Thread d will wait

Thread a will wait

Thread c will wait

Thread b will wait

-------Thread b is over

-------Thread d is over

-------Thread a is over

-------Thread c is over

 

原文

https://www.cnblogs.com/nullzx/p/5271964.html