Java中常见的并发控制手段浅析

2024-04-02 19:04:59 842人浏览八月长安

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摘要

目录前言1.1 同步代码块1.2 CAS自旋方式1.3 锁1.4 阻塞队列1.5 信号量Semaphore1.6 计数器CountDownLatch1.7 栅栏 CyclicBarr

前言

单实例的并发控制，主要是针对JVM内，我们常规的手段即可满足需求，常见的手段大概有下面这些

同步代码块
CAS自旋
锁
阻塞队列，令牌桶等

1.1 同步代码块

通过同步代码块，来确保同一时刻只会有一个线程执行对应的业务逻辑，常见的使用姿势如下


public synchronized doProcess() {
    // 同步代码块，只会有一个线程执行
}

一般推荐使用最小区间使用原则，尽量不要直接在方法上加synchronized，比如经典的双重判定单例模式


public class Single {
  private static volatile Single instance;
  private Single() {}
  public static Single getInstance() {
      if (instance == null) {
          synchronized(Single.class) {
              if (instance == null) instance = new Single();
          }
      }
      return instance;
  }
}

1.2 CAS自旋方式

比如AtomicXXX原子类中的很多实现，就是借助unsafe的CAS来实现的，如下


public final int getAndIncrement() {
    return unsafe.getAndAddInt(this, valueOffset, 1);
}


// unsafe 实现
// cas + 自选，不断的尝试更新设置，直到成功为止
public final int getAndAddInt(Object var1, long var2, int var4) {
    int var5;
    do {
        var5 = this.getIntVolatile(var1, var2);
    } while(!this.compareAndSwapint(var1, var2, var5, var5 + var4));

    return var5;
}

1.3 锁

jdk本身提供了不少的锁，为了实现单实例的并发控制，我们需要选择写锁；如果支持多读，单实例写，则可以考虑读写锁；一般使用姿势也比较简单


private void doSome(ReentrantReadWriteLock.WriteLock writeLock) {
    try {
        writeLock.lock();
        System.out.println("持有锁成功 " + Thread.currentThread().getName());
        Thread.sleep(1000);
        System.out.println("执行完毕! " + Thread.currentThread().getName());
        writeLock.unlock();
    } catch (Exception e) {
        e.printStackTrace();
    }
}

@Test
public void lock() throws InterruptedException {
    ReentrantReadWriteLock reentrantReadWriteLock = new ReentrantReadWriteLock();

    new Thread(()->doSome(reentrantReadWriteLock.writeLock())).start();
    new Thread(()->doSome(reentrantReadWriteLock.writeLock())).start();
    new Thread(()->doSome(reentrantReadWriteLock.writeLock())).start();

    Thread.sleep(20000);
}

1.4 阻塞队列

借助同步阻塞队列，也可以实现并发控制的效果，比如队列中初始化n个元素，每次消费从队列中获取一个元素，如果拿不到则阻塞；执行完毕之后，重新塞入一个元素，这样就可以实现一个简单版的并发控制

demo版演示，下面指定队列长度为2，表示最大并发数控制为2；设置为1时，可以实现单线程的访问控制


AtomicInteger cnt = new AtomicInteger();

private void consumer(LinkedBlockingQueue<Integer> queue) {
    try {
        // 同步阻塞拿去数据
        int val = queue.take();
        Thread.sleep(2000);
        System.out.println("成功拿到: " + val + " Thread: " + Thread.currentThread());
    } catch (InterruptedException e) {
        e.printStackTrace();
    } finally {
        // 添加数据
        System.out.println("结束 " + Thread.currentThread());
        queue.offer(cnt.getAndAdd(1));
    }
}

@Test
public void blockQueue() throws InterruptedException {
    LinkedBlockingQueue<Integer> queue = new LinkedBlockingQueue<>(2);
    queue.add(cnt.getAndAdd(1));
    queue.add(cnt.getAndAdd(1));


    new Thread(() -> consumer(queue)).start();
    new Thread(() -> consumer(queue)).start();
    new Thread(() -> consumer(queue)).start();
    new Thread(() -> consumer(queue)).start();

    Thread.sleep(10000);
}

1.5 信号量Semaphore

上面队列的实现方式，可以使用信号量Semaphore来完成，通过设置信号量，来控制并发数


private void semConsumer(Semaphore semaphore) {
    try {
        //同步阻塞，尝试获取信号
        semaphore.acquire(1);
        System.out.println("成功拿到信号，执行: " + Thread.currentThread());
        Thread.sleep(2000);
        System.out.println("执行完毕，释放信号: " + Thread.currentThread());
        semaphore.release(1);
    } catch (Exception e) {
        e.printStackTrace();
    }
}

@Test
public void semaphore() throws InterruptedException {
    Semaphore semaphore = new Semaphore(2);

    new Thread(() -> semConsumer(semaphore)).start();
    new Thread(() -> semConsumer(semaphore)).start();
    new Thread(() -> semConsumer(semaphore)).start();
    new Thread(() -> semConsumer(semaphore)).start();
    new Thread(() -> semConsumer(semaphore)).start();

    Thread.sleep(20_000);
}

1.6 计数器CountDownLatch

计数，应用场景更偏向于多线程的协同，比如多个线程执行完毕之后，再处理某些事情；不同于上面的并发数的控制，它和栅栏一样，更多的是行为结果的统一

这种场景下的使用姿势一般如下

重点：countDownLatch 计数为0时放行


@Test
public void countDown() throws InterruptedException {
    CountDownLatch countDownLatch = new CountDownLatch(2);

    new Thread(() -> {
        try {
            System.out.println("do something in " + Thread.currentThread());
            Thread.sleep(2000);
        } catch (InterruptedException e) {
            e.printStackTrace();
        } finally {
            countDownLatch.countDown();
        }
    }).start();

    new Thread(() -> {
        try {
            System.out.println("do something in t2: " + Thread.currentThread());
            Thread.sleep(1000);
        } catch (InterruptedException e) {
            e.printStackTrace();
        } finally {
            countDownLatch.countDown();
        }
    }).start();

    countDownLatch.await();
    System.out.printf("结束");
}

1.7 栅栏 CyclicBarrier

CyclicBarrier的作用与上面的CountDownLatch相似，区别在于正向计数+1, 只有达到条件才放行; 且支持通过调用reset()重置计数，而CountDownLatch则不行

一个简单的demo


private void cyclicBarrierLogic(CyclicBarrier barrier, long sleep) {
    // 等待达到条件才放行
    try {
        System.out.println("准备执行: " + Thread.currentThread() + " at: " + LocalDateTime.now());
        Thread.sleep(sleep);
        int index = barrier.await();
        System.out.println("开始执行: " + index + " thread: " + Thread.currentThread() + " at: " + LocalDateTime.now());
    } catch (Exception e) {
        e.printStackTrace();
    }
}

@Test
public void testCyclicBarrier() throws InterruptedException {
    // 到达两个工作线程才能继续往后面执行
    CyclicBarrier barrier = new CyclicBarrier(2);
    // 三秒之后，下面两个线程的才会输出 开始执行
    new Thread(() -> cyclicBarrierLogic(barrier, 1000)).start();
    new Thread(() -> cyclicBarrierLogic(barrier, 3000)).start();

    Thread.sleep(4000);
    // 重置，可以再次使用
    barrier.reset();
    new Thread(() -> cyclicBarrierLogic(barrier, 1)).start();
    new Thread(() -> cyclicBarrierLogic(barrier, 1)).start();
    Thread.sleep(10000);
}

1.8 guava令牌桶

guava封装了非常简单的并发控制工具类RateLimiter，作为单机的并发控制首选

一个控制qps为2的简单demo如下:


private void guavaProcess(RateLimiter rateLimiter) {
    try {
        // 同步阻塞方式获取
        System.out.println("准备执行: " + Thread.currentThread() + " > " + LocalDateTime.now());
        rateLimiter.acquire();
        System.out.println("执行中: " + Thread.currentThread() + " > " + LocalDateTime.now());
    } catch (Exception e) {
        e.printStackTrace();
    }
}

@Test
public void testGuavaRate() throws InterruptedException {
    // 1s 中放行两个请求
    RateLimiter rateLimiter = RateLimiter.create(2.0d);
    new Thread(() -> guavaProcess(rateLimiter)).start();
    new Thread(() -> guavaProcess(rateLimiter)).start();
    new Thread(() -> guavaProcess(rateLimiter)).start();
    new Thread(() -> guavaProcess(rateLimiter)).start();
    new Thread(() -> guavaProcess(rateLimiter)).start();
    new Thread(() -> guavaProcess(rateLimiter)).start();
    new Thread(() -> guavaProcess(rateLimiter)).start();

    Thread.sleep(20_000);
}

输出:

准备执行: Thread[Thread-2,5,main] > 2021-04-13T10:18:05.263
准备执行: Thread[Thread-1,5,main] > 2021-04-13T10:18:05.263
准备执行: Thread[Thread-5,5,main] > 2021-04-13T10:18:05.264
准备执行: Thread[Thread-7,5,main] > 2021-04-13T10:18:05.264
准备执行: Thread[Thread-3,5,main] > 2021-04-13T10:18:05.263
准备执行: Thread[Thread-4,5,main] > 2021-04-13T10:18:05.264
准备执行: Thread[Thread-6,5,main] > 2021-04-13T10:18:05.263
执行中: Thread[Thread-2,5,main] > 2021-04-13T10:18:05.267
执行中: Thread[Thread-6,5,main] > 2021-04-13T10:18:05.722
执行中: Thread[Thread-4,5,main] > 2021-04-13T10:18:06.225
执行中: Thread[Thread-3,5,main] > 2021-04-13T10:18:06.721
执行中: Thread[Thread-7,5,main] > 2021-04-13T10:18:07.221
执行中: Thread[Thread-5,5,main] > 2021-04-13T10:18:07.720
执行中: Thread[Thread-1,5,main] > 2021-04-13T10:18:08.219