类ReentrantLock具有完全互斥排他的效果,即同一时间只有一个线程在执行ReentrantLock.lock()后面的代码。这样虽然保证了线程的安全性,但是效率低下。JDK提供了ReentrantReadWriteLock读写锁,使用它可以加快效率,在某些不需要操作实例变量的方法中,完全可以使用读写锁ReemtrantReadWriteLock来提升该方法的运行速度。
读写锁表示有两个锁,一个是读操作相关的锁,也称为共享锁;另一个是写操作相关的锁,也叫排他锁。也就是多个读锁之间不互斥,读锁与写锁互斥、写锁与写锁互斥。在没有线程Thread进行写入操作时,进行读取操作的多个Thread都可以获取读锁,而进行写入操作的Thread只有在获取写锁后才能进行写入操作。即多个Thread可以同时进行读取操作,但是同一时刻只允许一个Thread进行写入操作。
1.读读共享
读锁与读锁可以共享,这种锁一般用于只读操作,不对变量进行修改操作。
package cn.qlq.thread.twelve; import java.util.concurrent.locks.ReentrantReadWriteLock; import org.slf4j.Logger; import org.slf4j.LoggerFactory; import cn.qlq.thread.one.RunnableThread; public class Demo1 { private ReentrantReadWriteLock lock = new ReentrantReadWriteLock();// 读写锁 private static final Logger log = LoggerFactory.getLogger(Demo1.class); private int i; public String readI() { try { lock.readLock().lock();// 占用读锁 log.info("threadName -> {} 占用读锁,i->{}", Thread.currentThread().getName(), i); Thread.sleep(2 * 1000); } catch (InterruptedException e) { } finally { log.info("threadName -> {} 释放读锁,i->{}", Thread.currentThread().getName(), i); lock.readLock().unlock();// 释放读锁 } return i + ""; } public static void main(String[] args) { final Demo1 demo1 = new Demo1(); Runnable runnable = new Runnable() { @Override public void run() { demo1.readI(); } }; new Thread(runnable, "t1").start(); new Thread(runnable, "t2").start(); new Thread(runnable, "t3").start(); } }
结果:
18:27:20 [cn.qlq.thread.twelve.Demo1]-[INFO] threadName -> t2 占用读锁,i->0
18:27:20 [cn.qlq.thread.twelve.Demo1]-[INFO] threadName -> t1 占用读锁,i->0
18:27:20 [cn.qlq.thread.twelve.Demo1]-[INFO] threadName -> t3 占用读锁,i->0
18:27:22 [cn.qlq.thread.twelve.Demo1]-[INFO] threadName -> t3 释放读锁,i->0
18:27:22 [cn.qlq.thread.twelve.Demo1]-[INFO] threadName -> t1 释放读锁,i->0
18:27:22 [cn.qlq.thread.twelve.Demo1]-[INFO] threadName -> t2 释放读锁,i->0
2.写写互斥
写锁与写锁互斥,这就类似于ReentrantLock的作用效果。
package cn.qlq.thread.twelve; import java.util.concurrent.locks.ReentrantReadWriteLock; import org.slf4j.Logger; import org.slf4j.LoggerFactory; public class Demo2 { private ReentrantReadWriteLock lock = new ReentrantReadWriteLock();// 读写锁 private static final Logger log = LoggerFactory.getLogger(Demo2.class); private int i; public void addI() { try { lock.writeLock().lock();// 占用写锁 log.info("threadName -> {} 占用写锁,i->{}", Thread.currentThread().getName(), i); Thread.sleep(2 * 1000); i++; } catch (InterruptedException e) { } finally { log.info("threadName -> {} 释放写锁,i->{}", Thread.currentThread().getName(), i); lock.writeLock().unlock();// 释放写锁 } } public static void main(String[] args) { final Demo2 demo1 = new Demo2(); Runnable runnable = new Runnable() { @Override public void run() { demo1.addI(); } }; new Thread(runnable, "t1").start(); new Thread(runnable, "t2").start(); new Thread(runnable, "t3").start(); } }
结果:(从时间可以看出实现了互斥效果)
18:31:31 [cn.qlq.thread.twelve.Demo2]-[INFO] threadName -> t1 占用写锁,i->0
18:31:33 [cn.qlq.thread.twelve.Demo2]-[INFO] threadName -> t1 释放写锁,i->1
18:31:33 [cn.qlq.thread.twelve.Demo2]-[INFO] threadName -> t2 占用写锁,i->1
18:31:35 [cn.qlq.thread.twelve.Demo2]-[INFO] threadName -> t2 释放写锁,i->2
18:31:35 [cn.qlq.thread.twelve.Demo2]-[INFO] threadName -> t3 占用写锁,i->2
18:31:37 [cn.qlq.thread.twelve.Demo2]-[INFO] threadName -> t3 释放写锁,i->3
3.读写互斥
package cn.qlq.thread.twelve; import java.util.concurrent.locks.ReentrantReadWriteLock; import org.slf4j.Logger; import org.slf4j.LoggerFactory; /** * 读写互斥 * * @author Administrator * */ public class Demo3 { private ReentrantReadWriteLock lock = new ReentrantReadWriteLock();// 读写锁 private static final Logger log = LoggerFactory.getLogger(Demo3.class); private int i; public String readI() { try { lock.readLock().lock();// 占用读锁 log.info("threadName -> {} 占用读锁,i->{}", Thread.currentThread().getName(), i); Thread.sleep(2 * 1000); } catch (InterruptedException e) { } finally { log.info("threadName -> {} 释放读锁,i->{}", Thread.currentThread().getName(), i); lock.readLock().unlock();// 释放读锁 } return i + ""; } public void addI() { try { lock.writeLock().lock();// 占用写锁 log.info("threadName -> {} 占用写锁,i->{}", Thread.currentThread().getName(), i); Thread.sleep(2 * 1000); i++; } catch (InterruptedException e) { } finally { log.info("threadName -> {} 释放写锁,i->{}", Thread.currentThread().getName(), i); lock.writeLock().unlock();// 释放写锁 } } public static void main(String[] args) throws InterruptedException { final Demo3 demo1 = new Demo3(); new Thread(new Runnable() { @Override public void run() { demo1.readI(); } }, "t1").start(); Thread.sleep(1 * 1000); new Thread(new Runnable() { @Override public void run() { demo1.addI(); } }, "t2").start(); } }
结果:
18:34:59 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t1 占用读锁,i->0
18:35:01 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t1 释放读锁,i->0
18:35:01 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t2 占用写锁,i->0
18:35:03 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t2 释放写锁,i->1
4.写读互斥
写锁与读锁也是互斥的。先占用写锁后读锁进行抢占也会等待写锁释放。
package cn.qlq.thread.twelve; import java.util.concurrent.locks.ReentrantReadWriteLock; import org.slf4j.Logger; import org.slf4j.LoggerFactory; /** * 读写互斥 * * @author Administrator * */ public class Demo3 { private ReentrantReadWriteLock lock = new ReentrantReadWriteLock();// 读写锁 private static final Logger log = LoggerFactory.getLogger(Demo3.class); private int i; public String readI() { try { lock.readLock().lock();// 占用读锁 log.info("threadName -> {} 占用读锁,i->{}", Thread.currentThread().getName(), i); Thread.sleep(2 * 1000); } catch (InterruptedException e) { } finally { log.info("threadName -> {} 释放读锁,i->{}", Thread.currentThread().getName(), i); lock.readLock().unlock();// 释放读锁 } return i + ""; } public void addI() { try { lock.writeLock().lock();// 占用写锁 log.info("threadName -> {} 占用写锁,i->{}", Thread.currentThread().getName(), i); Thread.sleep(2 * 1000); i++; } catch (InterruptedException e) { } finally { log.info("threadName -> {} 释放写锁,i->{}", Thread.currentThread().getName(), i); lock.writeLock().unlock();// 释放写锁 } } public static void main(String[] args) throws InterruptedException { final Demo3 demo1 = new Demo3(); new Thread(new Runnable() { @Override public void run() { demo1.addI(); } }, "t2").start(); Thread.sleep(1 * 1000); new Thread(new Runnable() { @Override public void run() { demo1.readI(); } }, "t1").start(); } }
结果:
18:36:14 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t2 占用写锁,i->0
18:36:16 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t2 释放写锁,i->1
18:36:16 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t1 占用读锁,i->1
18:36:18 [cn.qlq.thread.twelve.Demo3]-[INFO] threadName -> t1 释放读锁,i->1