线程池的学习和使用

发表于 | 分类于 | 阅读次数:
本文字数: 5.3k | 阅读时长 ≈ 5 分钟

什么是线程池

线程池的作用是初始化一些线程,当有任务的时候,就从中启动一个来执行相关任务,执行完后,线程资源重新回收到线程池中,达到复用的效果,从而减少资源的开销;

本文将介绍线程池的创建方式、优化和实际使用这几个方面进行讲解;

创建线程池

在JDK中,Executors类已经帮我们封装了创建线程池的方法。

1
2
3
Executors.newFixedThreadPool();
Executors.newCachedThreadPool();
Executors.newScheduledThreadPool();

但是点进去看的话,

1
2
3
4
5
public static ExecutorService newFixedThreadPool(int nThreads) {
    return new ThreadPoolExecutor(nThreads, nThreads,
                                  0L, TimeUnit.MILLISECONDS,
                                  new LinkedBlockingQueue<Runnable>());
}

它的内部实现还是基于ThreadPoolExecutor来实现的。通过阿里代码规范插件扫描会提示我们用ThreadPoolExecutor去实现线程池。通过查看ThreadPoolExecutor的构造方法

1
2
3
4
5
6
7
8
9
10
11
public ThreadPoolExecutor(int corePoolSize,
                              int maximumPoolSize,
                              long keepAliveTime,
                              TimeUnit unit,
                              BlockingQueue<Runnable> workQueue,
                              ThreadFactory threadFactory,
                              RejectedExecutionHandler handler) {
                                    ...
                                  do something
                                  ...
                              }

我觉得有以下几方面的原因。

  1. 可以灵活设置keepAliveTime(当线程池中线程数大于corePoolSize的数m, 为这m个线程设置的最长等待时间 ),节约系统资源。
  2. workQueue:线程等待队列,在Executors中默认的是LinkedBlockingQueue。可以理解是一种无界的数组,当有不断有线程来的时候,可能会撑爆机器内存。
  3. 可以设线程工厂,里面添加自己想要的一些元素,只需要实现JDK的ThreadFactory类。
  4. 按照自己的业务设置合适的拒绝策略。策略有以下几种
    1. AbortPolicy:直接抛出拒绝异常(继承自RuntimeException),会中断调用者的处理过程,所以除非有明确需求,一般不推荐
    2. DiscardPolicy:默默丢弃无法加载的任务。
    3. DiscardOldestPolicy:丢弃队列中最老的,然后再次尝试提交新任务。
    4. CallerRunsPolicy:在调用者线程中(也就是说谁把 r 这个任务甩来的),运行当前被丢弃的任务。只会用调用者所在线程来运行任务,也就是说任务不会进入线程池。如果线程池已经被关闭,则直接丢弃该任务。

使用线程池

声明ThreadFactory

1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
public class NacosSyncThreadFactory implements ThreadFactory {
    private final AtomicInteger threadNum = new AtomicInteger(1);
    private String threadPrefix = null;
    private ThreadGroup threadGroup;

    public NacosSyncThreadFactory(String prefix) {
        this.threadPrefix = "thread" + "-" + prefix + "-" ;
        threadGroup = Thread.currentThread().getThreadGroup();

    }

    public NacosSyncThreadFactory() {
        this("pool");
    }

    @Override
    public Thread newThread(Runnable r) {
        String name = threadPrefix + threadNum.incrementAndGet();
        Thread thread = new Thread(threadGroup, r, name);
        return thread;
    }
}

创建线程池类

1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
public class MyThreadPool {
    private ThreadFactory threadFactory;
    private int threadNum;
    private BlockingQueue blockingQueue;
    private RejectedExecutionHandler handler;

    public MyThreadPool(ThreadFactory threadFactory, int threadNum,
                        BlockingQueue blockingQueue,
                        RejectedExecutionHandler handler ) {
        this.threadFactory = threadFactory;
        this.threadNum = threadNum;
        this.blockingQueue = blockingQueue;
        this.handler = handler;
    }

    public MyThreadPool() {
        this(Executors.defaultThreadFactory(), 10,
                new ArrayBlockingQueue(10), new ThreadPoolExecutor.AbortPolicy());
    }

    public ThreadPoolExecutor initThreadPool(ThreadFactory threadFactory, int threadNum, BlockingQueue blockingQueue, RejectedExecutionHandler handler) {
        if (handler == null) {
            handler = new ThreadPoolExecutor.AbortPolicy();
        }


        return new ThreadPoolExecutor(1, threadNum, 5, TimeUnit.SECONDS, blockingQueue, threadFactory, handler);
    }

}

调用线程池

  1. 初始化线程池类

    1
    2
    3
    4
    5
    6
    7
    8
    9
    10
    11
      MyThreadPool myThreadPool = new MyThreadPool();

        threadPoolExecutor = myThreadPool.initThreadPool(
                new NacosSyncThreadFactory("nacos-sync"),
                threadNum,
                new ArrayBlockingQueue(10),
                new ThreadPoolExecutor.DiscardPolicy()

        );

    }

  2. 创建Callable(FutureTask)

    1
    2
    3
    4
    5
    6
    7
    8
    9
    10
    11
    12
    13
    14
    15
    16
    17
    18
    19
    20
    21
    22
    23
    24
    25
    26
     /**
      * 分页获取task信息
      * @return
      */
    private List<Task> getTask(int pageNum) {
        IPage<Task> page = new Page(pageNum, 25);
        IPage<Task> taskIPage = this.taskService.page(page);
        if (null == taskIPage || CollectionUtils.isEmpty(taskIPage.getRecords())) {
            return null;
        }

        return taskIPage.getRecords();

    }

    // 执行任务
     private FutureTask<String> assembleTaskFuture(Task task) {
         FutureTask<String> futureTask = new FutureTask(() -> {

             // 执行任务
             this.doSyncWork(task);
             return "success";
         });
     
         return futureTask;
     }

  3. 执行任务(FutureTask)

    1
    2
    3
    4
    5
    6
    7
    8
    9
    10
    11
    12
    13
    14
    15
    16
    17
    18
    19
    20
    21
    22
    23
    24
    public void zkSync() {
        // 获取数据总数,得到线程数
        int count = this.taskService.count();
        int pageSize = 25;
        int num = count / pageSize;
        int pageTotal = count % pageSize == 0 ? num : num + 1;
        log.info("========总记录数:{}=====总页数:{}", count, pageTotal);

        for (int i = 1; i <=  pageTotal; i++) {
            List<Task> taskList = this.getTask(i);
            if (CollectionUtils.isEmpty(taskList)) {
                break;
            }
            List<Integer> collect = taskList.stream().map(task -> task.getId()).collect(Collectors.toList());
            taskList.forEach(task -> {
                FutureTask<String> futureTask = this.assembleTaskFuture(task);
                threadPoolExecutor.execute(futureTask);
            });

        }

        threadPoolExecutor.shutdown();

    }
线程