在谈到DelayQueue的使用和原理的时候,我们首先介绍一下DelayQueue,DelayQueue是一个无界阻塞队列,只有在延迟期满时才能从中提取元素。该队列的头部是延迟期满后保存时间最长的Delayed 元素。
DelayQueue阻塞队列在我们系统开发中也常常会用到,例如:缓存系统的设计,缓存中的对象,超过了空闲时间,需要从缓存中移出;任务调度系统,能够准确的把握任务的执行时间。我们可能需要通过线程处理很多时间上要求很严格的数据,如果使用普通的线程,我们就需要遍历所有的对象,一个一个的检 查看数据是否过期等,首先这样在执行上的效率不会太高,其次就是这种设计的风格也大大的影响了数据的精度。一个需要12:00点执行的任务可能12:01 才执行,这样对数据要求很高的系统有更大的弊端。由此我们可以使用DelayQueue。
为了具有调用行为,存放到DelayDeque的元素必须继承Delayed接口。Delayed接口使对象成为延迟对象,它使存放在DelayQueue类中的对象具有了激活日期。该接口强制执行下列两个方法。
- CompareTo(Delayed o):Delayed接口继承了Comparable接口,因此有了这个方法。
- getDelay(TimeUnit unit):这个方法返回到激活日期的剩余时间,时间单位由单位参数指定。
public class DelayEvent implements Delayed { private Date startDate; public DelayEvent(Date startDate) { super(); this.startDate = startDate; } @Override public int compareTo(Delayed o) { long result = this.getDelay(TimeUnit.NANOSECONDS) - o.getDelay(TimeUnit.NANOSECONDS); if (result < 0) { return -1; } else if (result > 0) { return 1; } else { return 0; } } @Override public long getDelay(TimeUnit unit) { Date now = new Date(); long diff = startDate.getTime() - now.getTime(); return unit.convert(diff, TimeUnit.MILLISECONDS); } }
public class DelayTask implements Runnable { private int id; private DelayQueue<DelayEvent> queue; public DelayTask(int id, DelayQueue<DelayEvent> queue) { super(); this.id = id; this.queue = queue; } @Override public void run() { Date now = new Date(); Date delay = new Date(); delay.setTime(now.getTime() + id * 1000); System.out.println("Thread " + id + " " + delay); for (int i = 0; i < 100; i++) { DelayEvent delayEvent = new DelayEvent(delay); queue.add(delayEvent); } } }
public class DelayDequeMain { public static void main(String[] args) throws Exception { DelayQueue<DelayEvent> queue = new DelayQueue<DelayEvent>(); Thread threads[] = new Thread[5]; for (int i = 0; i < threads.length; i++) { DelayTask task = new DelayTask(i + 1, queue); threads[i] = new Thread(task); } for (int i = 0; i < threads.length; i++) { threads[i].start(); } for (int i = 0; i < threads.length; i++) { try { threads[i].join(); } catch (InterruptedException e) { e.printStackTrace(); } } do { int counter = 0; DelayEvent delayEvent; do { delayEvent = queue.poll(); if (delayEvent != null) { counter++; } } while (delayEvent != null); System.out.println("At " + new Date() + " you have read " + counter+ " event"); TimeUnit.MILLISECONDS.sleep(500); } while (queue.size() > 0); } }
Thread 3 Fri May 06 11:00:20 CST 2016 Thread 1 Fri May 06 11:00:18 CST 2016 Thread 5 Fri May 06 11:00:22 CST 2016 Thread 4 Fri May 06 11:00:21 CST 2016 Thread 2 Fri May 06 11:00:19 CST 2016 At Fri May 06 11:00:17 CST 2016 you have read 0 event At Fri May 06 11:00:18 CST 2016 you have read 0 event At Fri May 06 11:00:18 CST 2016 you have read 100 event At Fri May 06 11:00:19 CST 2016 you have read 0 event At Fri May 06 11:00:19 CST 2016 you have read 100 event At Fri May 06 11:00:20 CST 2016 you have read 0 event At Fri May 06 11:00:20 CST 2016 you have read 100 event At Fri May 06 11:00:21 CST 2016 you have read 0 event At Fri May 06 11:00:21 CST 2016 you have read 100 event At Fri May 06 11:00:22 CST 2016 you have read 0 event At Fri May 06 11:00:22 CST 2016 you have read 100 event