Java 中的锁通常分为两种:
- 通过关键字 synchronized 获取的锁,我们称为同步锁,上一篇有介绍到:Java 多线程并发编程 Synchronized 关键字。
- java.util.concurrent(JUC)包里的锁,如通过继承接口 Lock 而实现的 ReentrantLock(互斥锁),继承 ReadWriteLock 实现的 ReentrantReadWriteLock(读写锁)。
本篇主要介绍 ReentrantLock(互斥锁)。
ReentrantLock(互斥锁)
ReentrantLock 互斥锁,在同一时间只能被一个线程所占有,在被持有后并未释放之前,其他线程若想获得该锁只能等待或放弃。
ReentrantLock 互斥锁是可重入锁,即某一线程可多次获得该锁。
公平锁 and 非公平锁
public ReentrantLock() { sync = new NonfairSync(); } public ReentrantLock(boolean fair) { sync = fair ? new FairSync() : new NonfairSync(); }
由 ReentrantLock 的构造函数可见,在实例化 ReentrantLock 的时候我们可以选择实例化一个公平锁或非公平锁,而默认会构造一个非公平锁。
公平锁与非公平锁区别在于竞争锁时的有序与否。公平锁可确保有序性(FIFO 队列),非公平锁不能确保有序性(即使也有 FIFO 队列)。
然而,公平是要付出代价的,公平锁比非公平锁要耗性能,所以在非必须确保公平的条件下,一般使用非公平锁可提高吞吐率。所以 ReentrantLock 默认的构造函数也是“不公平”的。
一般使用
DEMO1:
public class Test { private static class Counter { private ReentrantLock mReentrantLock = new ReentrantLock(); public void count() { mReentrantLock.lock(); try { for (int i = 0; i < 6; i++) { System.out.println(Thread.currentThread().getName() + ", i = " + i); } } finally { // 必须在 finally 释放锁 mReentrantLock.unlock(); } } } private static class MyThread extends Thread { private Counter mCounter; public MyThread(Counter counter) { mCounter = counter; } @Override public void run() { super.run(); mCounter.count(); } } public static void main(String[] var0) { Counter counter = new Counter(); // 注:myThread1 和 myThread2 是调用同一个对象 counter MyThread myThread1 = new MyThread(counter); MyThread myThread2 = new MyThread(counter); myThread1.start(); myThread2.start(); } }
DEMO1 输出:
Thread-0, i = 0 Thread-0, i = 1 Thread-0, i = 2 Thread-0, i = 3 Thread-0, i = 4 Thread-0, i = 5 Thread-1, i = 0 Thread-1, i = 1 Thread-1, i = 2 Thread-1, i = 3 Thread-1, i = 4 Thread-1, i = 5
DEMO1 仅使用了 ReentrantLock 的 lock 和 unlock 来提现一般锁的特性,确保线程的有序执行。此种场景 synchronized 也适用。
锁的作用域
DEMO2:
public class Test { private static class Counter { private ReentrantLock mReentrantLock = new ReentrantLock(); public void count() { for (int i = 0; i < 6; i++) { mReentrantLock.lock(); // 模拟耗时,突出线程是否阻塞 try{ Thread.sleep(100); System.out.println(Thread.currentThread().getName() + ", i = " + i); } catch (InterruptedException e) { e.printStackTrace(); } finally { // 必须在 finally 释放锁 mReentrantLock.unlock(); } } } public void doOtherThing(){ for (int i = 0; i < 6; i++) { // 模拟耗时,突出线程是否阻塞 try { Thread.sleep(100); } catch (InterruptedException e) { e.printStackTrace(); } System.out.println(Thread.currentThread().getName() + " doOtherThing, i = " + i); } } } public static void main(String[] var0) { final Counter counter = new Counter(); new Thread(new Runnable() { @Override public void run() { counter.count(); } }).start(); new Thread(new Runnable() { @Override public void run() { counter.doOtherThing(); } }).start(); } }
DEMO2 输出:
Thread-0, i = 0 Thread-1 doOtherThing, i = 0 Thread-0, i = 1 Thread-1 doOtherThing, i = 1 Thread-0, i = 2 Thread-1 doOtherThing, i = 2 Thread-0, i = 3 Thread-1 doOtherThing, i = 3 Thread-0, i = 4 Thread-1 doOtherThing, i = 4 Thread-0, i = 5 Thread-1 doOtherThing, i = 5
DEMO3:
public class Test { private static class Counter { private ReentrantLock mReentrantLock = new ReentrantLock(); public void count() { for (int i = 0; i < 6; i++) { mReentrantLock.lock(); // 模拟耗时,突出线程是否阻塞 try{ Thread.sleep(100); System.out.println(Thread.currentThread().getName() + ", i = " + i); } catch (InterruptedException e) { e.printStackTrace(); } finally { // 必须在 finally 释放锁 mReentrantLock.unlock(); } } } public void doOtherThing(){ mReentrantLock.lock(); try{ for (int i = 0; i < 6; i++) { // 模拟耗时,突出线程是否阻塞 try { Thread.sleep(100); } catch (InterruptedException e) { e.printStackTrace(); } System.out.println(Thread.currentThread().getName() + " doOtherThing, i = " + i); } }finally { mReentrantLock.unlock(); } } } public static void main(String[] var0) { final Counter counter = new Counter(); new Thread(new Runnable() { @Override public void run() { counter.count(); } }).start(); new Thread(new Runnable() { @Override public void run() { counter.doOtherThing(); } }).start(); } }
DEMO3 输出:
Thread-0, i = 0 Thread-0, i = 1 Thread-0, i = 2 Thread-0, i = 3 Thread-0, i = 4 Thread-0, i = 5 Thread-1 doOtherThing, i = 0 Thread-1 doOtherThing, i = 1 Thread-1 doOtherThing, i = 2 Thread-1 doOtherThing, i = 3 Thread-1 doOtherThing, i = 4 Thread-1 doOtherThing, i = 5
结合 DEMO2 和 DEMO3 输出可见,锁的作用域在于 mReentrantLock,因为所来自于 mReentrantLock。
可终止等待
DEMO4:
public class Test { static final int TIMEOUT = 300; private static class Counter { private ReentrantLock mReentrantLock = new ReentrantLock(); public void count() { try{ //lock() 不可中断 mReentrantLock.lock(); // 模拟耗时,突出线程是否阻塞 for (int i = 0; i < 6; i++) { long startTime = System.currentTimeMillis(); while (true) { if (System.currentTimeMillis() - startTime > 100) break; } System.out.println(Thread.currentThread().getName() + ", i = " + i); } } finally { // 必须在 finally 释放锁 mReentrantLock.unlock(); } } public void doOtherThing(){ try{ //lockInterruptibly() 可中断,若线程没有中断,则获取锁 mReentrantLock.lockInterruptibly(); for (int i = 0; i < 6; i++) { // 模拟耗时,突出线程是否阻塞 long startTime = System.currentTimeMillis(); while (true) { if (System.currentTimeMillis() - startTime > 100) break; } System.out.println(Thread.currentThread().getName() + " doOtherThing, i = " + i); } } catch (InterruptedException e) { System.out.println(Thread.currentThread().getName() + " 中断 "); }finally { // 若当前线程持有锁,则释放 if(mReentrantLock.isHeldByCurrentThread()){ mReentrantLock.unlock(); } } } } public static void main(String[] var0) { final Counter counter = new Counter(); new Thread(new Runnable() { @Override public void run() { counter.count(); } }).start(); Thread thread2 = new Thread(new Runnable() { @Override public void run() { counter.doOtherThing(); } }); thread2.start(); long start = System.currentTimeMillis(); while (true){ if (System.currentTimeMillis() - start > TIMEOUT) { // 若线程还在运行,尝试中断 if(thread2.isAlive()){ System.out.println(" 不等了,尝试中断 "); thread2.interrupt(); } break; } } } }
DEMO4 输出:
Thread-0, i = 0 Thread-0, i = 1 Thread-0, i = 2 不等了,尝试中断 Thread-1 中断 Thread-0, i = 3 Thread-0, i = 4 Thread-0, i = 5
线程 thread2 等待 300ms 后 timeout,中断等待成功。
若把 TIMEOUT 改成 3000ms,输出结果:(正常运行)
Thread-0, i = 0 Thread-0, i = 1 Thread-0, i = 2 Thread-0, i = 3 Thread-0, i = 4 Thread-0, i = 5 Thread-1 doOtherThing, i = 0 Thread-1 doOtherThing, i = 1 Thread-1 doOtherThing, i = 2 Thread-1 doOtherThing, i = 3 Thread-1 doOtherThing, i = 4 Thread-1 doOtherThing, i = 5
定时锁
DEMO5:
public class Test { static final int TIMEOUT = 3000; private static class Counter { private ReentrantLock mReentrantLock = new ReentrantLock(); public void count() { try{ //lock() 不可中断 mReentrantLock.lock(); // 模拟耗时,突出线程是否阻塞 for (int i = 0; i < 6; i++) { long startTime = System.currentTimeMillis(); while (true) { if (System.currentTimeMillis() - startTime > 100) break; } System.out.println(Thread.currentThread().getName() + ", i = " + i); } } finally { // 必须在 finally 释放锁 mReentrantLock.unlock(); } } public void doOtherThing(){ try{ //tryLock(long timeout, TimeUnit unit) 尝试获得锁 boolean isLock = mReentrantLock.tryLock(300, TimeUnit.MILLISECONDS); System.out.println(Thread.currentThread().getName() + " isLock:" + isLock); if(isLock){ for (int i = 0; i < 6; i++) { // 模拟耗时,突出线程是否阻塞 long startTime = System.currentTimeMillis(); while (true) { if (System.currentTimeMillis() - startTime > 100) break; } System.out.println(Thread.currentThread().getName() + " doOtherThing, i = " + i); } }else{ System.out.println(Thread.currentThread().getName() + " timeout"); } } catch (InterruptedException e) { System.out.println(Thread.currentThread().getName() + " 中断 "); }finally { // 若当前线程持有锁,则释放 if(mReentrantLock.isHeldByCurrentThread()){ mReentrantLock.unlock(); } } } } public static void main(String[] var0) { final Counter counter = new Counter(); new Thread(new Runnable() { @Override public void run() { counter.count(); } }).start(); Thread thread2 = new Thread(new Runnable() { @Override public void run() { counter.doOtherThing(); } }); thread2.start(); } }
DEMO5 输出:
Thread-0, i = 0 Thread-0, i = 1 Thread-0, i = 2 Thread-1 isLock:false Thread-1 timeout Thread-0, i = 3 Thread-0, i = 4 Thread-0, i = 5
tryLock() 尝试获得锁,tryLock(long timeout, TimeUnit unit) 在给定的 timeout 时间内尝试获得锁,若超时,则不带锁往下走,所以必须加以判断。
ReentrantLock or synchronized
ReentrantLock 、synchronized 之间如何选择?
ReentrantLock 在性能上 比 synchronized 更胜一筹。
ReentrantLock 需格外小心,因为需要显式释放锁,lock() 后记得 unlock(),而且必须在 finally 里面,否则容易造成死锁。
synchronized 隐式自动释放锁,使用方便。
ReentrantLock 扩展性好,可中断锁,定时锁,自由控制。
synchronized 一但进入阻塞等待,则无法中断等待。
原创文章,作者:Maggie-Hunter,如若转载,请注明出处:https://blog.ytso.com/7855.html