Java多线程系列十——BlockingQueue

时间:2023-03-10 02:20:17
Java多线程系列十——BlockingQueue

参考资料:http://ifeve.com/java-synchronousqueue/
http://www.cnblogs.com/jackyuj/archive/2010/11/24/1886553.html
http://ifeve.com/java-blocking-queue/

BlockingQueue的几个API认识

方法 说明
boolean add(E e) 添加元素,返回true或者超出队列size上限后抛异常,若队列有大小限制时,官方更建议使用offer方法
boolean offer(E e) 添加元素,返回true或者false(超出队列size上限后)
void put(E e) throws InterruptedException 添加元素,无返回值,若空间不足则进入waiting状态直到有空间
boolean offer(E e, long timeout, TimeUnit unit) throws InterruptedException 添加元素,返回true或者false(等待时间已到但仍无可添加空间),若空间不足则等待一定时间直到成功或者放弃
E take() throws InterruptedException 获取队列头部元素,若没有可取元素则进入waiting状态
E poll(long timeout, TimeUnit unit) throws InterruptedException 获取队列头部元素,若没有可取元素则等待一定时间直到成功或者放弃
boolean remove(Object o) 删除元素

BlockingQueue派生出几个常用的类ArrayBlockingQueue/LinkedBlockingDeque/DelayQueue/PriorityBlockingQueue/SynchronousQueue,类图如下所示:

Java多线程系列十——BlockingQueue

它们的一些特性:

  • ArrayBlockingQueue:以数组保存元素,初始化时必须指定队列的容量capacity,添加元素时若达到上限进入阻塞
  • LinkedBlockingDeque:以双向链表保存元素,初始化时可指定队列的容量,若不指定,capacity默认为Integer.MAX_VALUE,添加元素时若达到上限进入阻塞
  • DelayQueue:以PriorityQueue保存元表,只能获取已到过期时间的元素,否则得到null,无容量上限,理论上可无限添加元素
  • PriorityBlockingQueue:以数组保存元素,整个队列为一棵平衡二叉树,添加元素成功后对队列内元素重排序,无容量上限,理论上可无限添加元素
  • SynchronousQueue:无缓存队列,生产者线程对其的插入操作put必须等待消费者的移除操作take,反过来也一样

ArrayBlockingQueue的使用案例可参考Java多线程系列三——实现线程同步的方法,本文测试DelayQueue的使用,代码如下:

import java.util.Arrays;

import java.util.HashMap;

import java.util.List;

import java.util.Map;

import java.util.concurrent.ArrayBlockingQueue;

import java.util.concurrent.BlockingQueue;

import java.util.concurrent.Callable;

import java.util.concurrent.DelayQueue;

import java.util.concurrent.Delayed;

import java.util.concurrent.ExecutionException;

import java.util.concurrent.ExecutorService;

import java.util.concurrent.Executors;

import java.util.concurrent.Future;

import java.util.concurrent.TimeUnit;

/**

 * @Description 利用DelayQueue清除超时请求<br/>

 *              1. 主线程从工作队列取出任务处理完成后,把任务从超时队列移除<br/>

 *              2. 超时检查线程找到超时请求后,把任务从工作队列中移除

 */

public class DelayQueueTest {

    public static void main(String[] args) throws InterruptedException, ExecutionException {

        int size = 36;

        DelayQueue<MyRequest> queue = new DelayQueue<>();// 用于记录是否超时的队列

        BlockingQueue<MyRequest> workQueue = new ArrayBlockingQueue<>(size);// 请求的队表

        Map<Integer, MyRequest> cache = new HashMap<>();// 请求与id的对照表

        for (int i = 0; i < size; i++) {// 初始化

            MyRequest impl = new MyRequest(i, System.nanoTime(), 120);

            queue.put(impl);

            workQueue.put(impl);

            cache.put(i, impl);

        }

        /**

         * 建立超时检查任务

         */

        Executors.newSingleThreadExecutor().submit(new Runnable() {

            @Override

            public void run() {

                while (queue.size() > 0) {

                    try {

                        MyRequest impl = queue.take();

                        workQueue.remove(impl);// 若请求超时则把请求从队列中移除

                        System.out.println(String.format("%s is timeout", impl));

                    } catch (InterruptedException e) {

                        e.printStackTrace();

                    }

                }

            }

        });

        /**

         * 建2个线程消费请求

         */

        ExecutorService executorService = Executors.newFixedThreadPool(2);

        while (workQueue.size() > 0) {

            List<MyRequest> tasks = Arrays.asList(new MyRequest[] { workQueue.take(), workQueue.take() });

            List<Future<Integer>> futures = executorService.invokeAll(tasks);

            for (Future<Integer> future : futures) {

                queue.remove(cache.get(future.get()));// 若请求成功,则不需要再检查是否超时

            }

        }

        executorService.awaitTermination(Integer.MAX_VALUE, TimeUnit.DAYS);

        executorService.shutdown();

    }

}

class MyRequest implements Delayed, Callable<Integer> {

    private int threadId;

    private long startTime;

    private long expiredTime;

    public MyRequest(int threadId, long startTime, long timeout) {

        this.threadId = threadId;

        this.startTime = startTime;

        this.expiredTime = TimeUnit.SECONDS.toNanos(timeout) + System.nanoTime();

    }

    @Override

    public Integer call() {

        try {

            Thread.sleep(TimeUnit.SECONDS.toMillis(10));

        } catch (InterruptedException e) {

            e.printStackTrace();

        }

        System.out.println(String.format("%s is ok", this));

        return threadId;

    }

    @Override

    public int compareTo(Delayed arg0) {

        int rtn;

        if (arg0 == null || !(arg0 instanceof MyRequest)) {

            rtn = 1;

        } else {

            MyRequest impl = (MyRequest) arg0;

            rtn = startTime > impl.getStartTime() ? 1 : (startTime == impl.getStartTime() ? 0 : -1);

        }

        return rtn;

    }

    @Override

    public long getDelay(TimeUnit unit) {

        return expiredTime - System.nanoTime();

    }

    public long getStartTime() {

        return startTime;

    }

    @Override

    public String toString() {

        return String.format("MyRequest [threadId=%s, startTime=%s, expiredTime=%s]", threadId, startTime, expiredTime);

    }

}

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