java 线程池keepAliveTime的含义说明_Java教程

之前对线程池中属性：keepAliveTime比较模糊，而且看过之后过一段时间就会忘掉，于是就在此记录一下。

keepAliveTime的jdk中的解释为：

当线程数大于核心时，此为终止前多余的空闲线程等待新任务的最长时间。

说的让人感觉比较模糊，总结一下大概意思为：比如说线程池中最大的线程数为50，而其中只有40个线程任务在跑，相当于有10个空闲线程，这10个空闲线程不能让他一直在开着，因为线程的存在也会特别好资源的，所有就需要设置一个这个空闲线程的存活时间，这么解释应该就很清楚了。

这样以后忘记了就过来看看就OK了。

补充：线程池的状态及KeepAliveTime参数

五个状态

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									// runState is stored in the high-order bits

									private static final int RUNNING = -1 << COUNT_BITS;

									private static final int SHUTDOWN = 0 << COUNT_BITS;

									private static final int STOP  = 1 << COUNT_BITS;

									private static final int TIDYING = 2 << COUNT_BITS;

									private static final int TERMINATED = 3 << COUNT_BITS;

循环getTask方法

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									/**

									  * Performs blocking or timed wait for a task, depending on

									  * current configuration settings, or returns null if this worker

									  * must exit because of any of:

									  * 1. There are more than maximumPoolSize workers (due to

									  * a call to setMaximumPoolSize).

									  * 2. The pool is stopped.

									  * 3. The pool is shutdown and the queue is empty.

									  * 4. This worker timed out waiting for a task, and timed-out

									  * workers are subject to termination (that is,

									  * {@code allowCoreThreadTimeOut || workerCount > corePoolSize})

									  * both before and after the timed wait.

									  *

									  * @return task, or null if the worker must exit, in which case

									  *   workerCount is decremented

									  */

									 private Runnable getTask() {

									  boolean timedOut = false; // Did the last poll() time out?

									  retry:

									  for (;;) {

									   int c = ctl.get();

									   int rs = runStateOf(c);

									   // Check if queue empty only if necessary.

									   if (rs >= SHUTDOWN && (rs >= STOP || workQueue.isEmpty())) {

									    decrementWorkerCount();

									    return null;

									   }

									   boolean timed;  // Are workers subject to culling?

									   for (;;) {

									    int wc = workerCountOf(c);

									    timed = allowCoreThreadTimeOut || wc > corePoolSize;

									    //默认allowCoreThreadTimeOut为false，除非程序指定

									    //（1）当没有超过核心线程时，默认allowCoreThreadTimeOut为false时

									    //timed值为false，始终break掉，不会销毁线程

									    //（2）当超过核心线程数，默认allowCoreThreadTimeOut为false时

									    //timed值为true，如果超过最大值，则销毁；如果timeout过，则销毁

									    // 如果allowCoreThreadTimeOut为true，则timed始终为true

									    if (wc <= maximumPoolSize && ! (timedOut && timed))

									     break;

									    if (compareAndDecrementWorkerCount(c))

									     return null;

									    c = ctl.get(); // Re-read ctl

									    if (runStateOf(c) != rs)

									     continue retry;

									    // else CAS failed due to workerCount change; retry inner loop

									   }

									   try {

									    Runnable r = timed ?

									     workQueue.poll(keepAliveTime, TimeUnit.NANOSECONDS) :

									     workQueue.take();

									    if (r != null)

									     return r;

									    timedOut = true;

									   } catch (InterruptedException retry) {

									    timedOut = false;

									   }

									  }

									 }

线程池状态大于SHUTDOWN值的两种情况

1、调用shutdown方法

当线程池调用了shutdown方法，线程池的状态会首先被设置为SHUTDOWN，然后遍历线程池中所有线程，调用一次interrupt方法，如果在休眠中的线程将会激活，激活后的线程以及调用shutdown方法本身的线程都会尝试去调用tryTerminate方法，该方法将判定如果线程池中所有记录的线程数为0，则将线程状态改为TERMINATED，这个值为3，将大于SHUTDOWN状态值。

2、调用shutdownNow方法

当线程调用了shutdownNow方法后，首先将线程的状态修改为STOP，这个状态是大于SHUTDOWN值的，接下来它也会通过中断激活线程，只是它来的更暴力一些，连加锁和一些基本判断都没有，直接中断；在调用tryTerminate之前会先清空阻塞队列中所有的元素，这些元素被组装为一个List列表作为shutdownNow方法的返回值。换句话说，没有执行的任务在shutdownNow执行后的返回值中可以得到。在程序某些必要的情况下，可以通过线程池的isTerminating，isTerminated，isStopped，isShutdown来对线程做一些状态判定。

KeepAliveTime参数

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									workQueue.poll(keepAliveTime, TimeUnit.NANOSECONDS)

当阻塞队列中没有任务时，等待时间达到keepAliveTime毫秒值时就会被自动唤醒，而不会永远地沉睡下去。

keepAliveTime，如果是通过newCachedThreadPool的话，默认是1分钟超时，如果遇到前面所提到的瞬间冲击，那么线程池数量将瞬间快速膨胀，而且这些瞬间膨胀的线程的生命周期最少在1分钟以上。

如果设置了该参数，那么当timeout的时候，就return null，就会跳出循环，回收线程。

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									if (wc <= maximumPoolSize && ! (timedOut && timed))

									     break;

									    if (compareAndDecrementWorkerCount(c))

									     return null;

allowCoreThreadTimeout : 默认情况下核心线程不会退出，可通过将该参数设置为true，让核心线程也退出。

默认的Executors工厂，只有newCachedThreadPool，timeout为60秒，出现timeout情况下，而且线程数超过了核心线程数，会销毁销毁线程。保持在corePoolSize数（如果是cached的，corePoolSize为0）。

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									/**

									 * Timeout in nanoseconds for idle threads waiting for work.

									 * Threads use this timeout when there are more than corePoolSize

									 * present or if allowCoreThreadTimeOut. Otherwise they wait

									 * forever for new work.

									 */

									private volatile long keepAliveTime;

									/**

									 * If false (default), core threads stay alive even when idle.

									 * If true, core threads use keepAliveTime to time out waiting

									 * for work.

									 */

									private volatile boolean allowCoreThreadTimeOut;

线程池最小是corePoolSize，最大是maximumPoolSize，除非设置了allowCoreThreadTimeOut和超时时间，这种情况线程数可能减少到0，最大可能是Integer.MAX_VALUE。

Core pool size is the minimum number of workers to keep alive(and not allow to time out etc) unless allowCoreThreadTimeOut is set, in which case the minimum is zero.

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									/**

									  * Creates a thread pool that creates new threads as needed, but

									  * will reuse previously constructed threads when they are

									  * available. These pools will typically improve the performance

									  * of programs that execute many short-lived asynchronous tasks.

									  * Calls to <tt>execute</tt> will reuse previously constructed

									  * threads if available. If no existing thread is available, a new

									  * thread will be created and added to the pool. Threads that have

									  * not been used for sixty seconds are terminated and removed from

									  * the cache. Thus, a pool that remains idle for long enough will

									  * not consume any resources. Note that pools with similar

									  * properties but different details (for example, timeout parameters)

									  * may be created using {@link ThreadPoolExecutor} constructors.

									  *

									  * @return the newly created thread pool

									  */

									 public static ExecutorService newCachedThreadPool() {

									  return new ThreadPoolExecutor(0, Integer.MAX_VALUE,

									          60L, TimeUnit.SECONDS,

									          new SynchronousQueue<Runnable>());

									 }

									 /**

									  * Creates a thread pool that creates new threads as needed, but

									  * will reuse previously constructed threads when they are

									  * available, and uses the provided

									  * ThreadFactory to create new threads when needed.

									  * @param threadFactory the factory to use when creating new threads

									  * @return the newly created thread pool

									  * @throws NullPointerException if threadFactory is null

									  */

									 public static ExecutorService newCachedThreadPool(ThreadFactory threadFactory) {

									  return new ThreadPoolExecutor(0, Integer.MAX_VALUE,

									          60L, TimeUnit.SECONDS,

									          new SynchronousQueue<Runnable>(),

									          threadFactory);

									 }

超时timeout设置为0的话，表示不等待

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									public E poll(long timeout, TimeUnit unit) throws InterruptedException {

									  return pollFirst(timeout, unit);

									 }

具体如下

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									public E pollFirst(long timeout, TimeUnit unit)

									  throws InterruptedException {

									  long nanos = unit.toNanos(timeout);

									  final ReentrantLock lock = this.lock;

									  lock.lockInterruptibly();

									  try {

									   E x;

									   while ( (x = unlinkFirst()) == null) {

									    if (nanos <= 0)

									     return null;

									    nanos = notEmpty.awaitNanos(nanos);

									   }

									   return x;

									  } finally {

									   lock.unlock();

									  }

									 }