java.util.concurrent包的拆解
java.util.concurrent包:
1.locks部分:显式锁(互斥锁和速写锁)相关
2.atomic部分:原子变量类相关,是构建非阻塞算法的基础
3.executor部分:线程池相关
4.collection部分:并发容器相关
5.tools部分:同步工具相关,如信号量、闭锁、栅栏等功能
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1.collection部分:
1.1 BlockingQueue
BlockingQueue为接口,如果要用它,需要实现它的子类:
ArrayBlockingQueue
DelayQueue
LinkedBlockingQueue
SynchronousQueue
PriorityBlockingQueue
TransferQueue
/**- 在两个独立的线程中启动一个Producer和一个Consumer
- Producer向一个共享的BlockingQueue注入字符串,而Comsumer从中拿出来
- @Author mufeng
@Date 2019-7-8 11:25
*/
public class BlockingQueueExample {
public static void main(String[] args) {
BlockingQueue blockingQueue=new ArrayBlockingQueue(1024);
Producer producer=new Producer(blockingQueue);
Consumer consumer=new Consumer(blockingQueue);
new Thread(producer).start();
new Thread(consumer).start();
try {
Thread.sleep(4000);
} catch (InterruptedException e) {
e.printStackTrace();
}
}
}
class Producer implements Runnable{
private BlockingQueue blockingQueue;
public Producer(BlockingQueue blockingQueue){this.blockingQueue=blockingQueue;
}
@Override
br/>this.blockingQueue=blockingQueue;
}
@Override
try {
blockingQueue.put("1");
Thread.sleep(1000);
blockingQueue.put("2");
Thread.sleep(1000);
blockingQueue.put("3");
Thread.sleep(1000);
} catch (InterruptedException e) {
e.printStackTrace();
}
}
}
class Consumer implements Runnable{
private BlockingQueue blockingQueue;
public Consumer(BlockingQueue blockingQueue){
this.blockingQueue=blockingQueue;
}@Override
public void run() {
try {
System.out.println(blockingQueue.take());
System.out.println(blockingQueue.take());
System.out.println(blockingQueue.take());
} catch (InterruptedException e) {
e.printStackTrace();
}
}
}
2.Tools部分
2.1 CountDownLatch用法
/**
- @Author mufeng
- @Date 2019-7-8 11:54
*/
public class TestCountDownLatch {
public static void main(String[] args) {
final CountDownLatch countDownLatch=new CountDownLatch(2);
new Thread(){
public void run(){
System.out.println(Thread.currentThread().getName()+"processing");
try {
Thread.sleep(3000);
System.out.println(Thread.currentThread().getName()+"ended");
countDownLatch.countDown();
} catch (InterruptedException e) {
e.printStackTrace();
}
}
}.start();
new Thread(){
public void run(){
System.out.println(Thread.currentThread().getName()+"processing");
try {
Thread.sleep(3000);
System.out.println(Thread.currentThread().getName()+"ended");
countDownLatch.countDown();
} catch (InterruptedException e) {
e.printStackTrace();
}
}
}.start();
try {
System.out.println("wait success...");
countDownLatch.await();//调用await()方法的线程会被挂起,会等待直到count值为0才继续执行
System.out.println("2 end");
} catch (Exception e) {
e.printStackTrace();
}
}
}
/**
- 所有线程都停留在栅栏的位置,都结束,才继续执行
- @Author mufeng
- @Date 2019-7-8 14:10
*/
public class TestCyclicBarrier {
public static void main(String[] args) {
int n=4;
CyclicBarrier cyclicBarrier=new CyclicBarrier(n);
for(int i=0;i
}
}
class Writer extends Thread{
private CyclicBarrier cyclicBarrier;
public Writer(CyclicBarrier cyclicBarrier){
this.cyclicBarrier=cyclicBarrier;
}
public void run(){
try {
System.out.println("writer start");
Thread.sleep(5000);
System.out.println("writer end");
cyclicBarrier.await();
} catch (InterruptedException e) {
e.printStackTrace();
} catch (BrokenBarrierException e) {
e.printStackTrace();
}
System.out.println("continue...");
}
}
/**
- Semaphore可以控制同时访问的线程个数,通过acquire()获取一个许可,如果没有就等待,而release()释放一个许可。
- @Author mufeng
- @Date 2019-7-8 14:32
*/
public class TestSemaphore {
public static void main(String[] args) {
int N=8;//工人数
Semaphore semaphore=new Semaphore(5);//机器数
for(int i=0;i
}
}
}
class Worker extends Thread{
private int num;
private Semaphore semaphore;
public Worker(int num,Semaphore semaphore){
this.num=num;
this.semaphore=semaphore;
}
public void run(){
try {
semaphore.acquire();
System.out.println("工人"+this.num+"occupy a machine。。。");
Thread.sleep(2000);
semaphore.release();
System.out.println("工人"+this.num+"release a machine");
} catch (InterruptedException e) {
e.printStackTrace();
}
}
}
/**
- Exchanger是在两个任务之间交换对象的栅栏,当这些任务进入栅栏时,它们各自拥有一个对象,当它们离开时,它们都拥有之前由对象持有的对象
- @Author mufeng
- @Date 2019-7-8 14:54
*/
public class TestExchanger {
public static void main(String[] args) {
ExecutorService executor =Executors.newCachedThreadPool();
final Exchanger exchanger=new Exchanger();
executor.execute(new Runnable() {@Override
br/>@Override
String data1="li";
doExchangeWork(data1,exchanger);
}
});
executor.execute(new Runnable() {@Override
br/>@Override
String data1="zhang";
doExchangeWork(data1,exchanger);
}
});
executor.shutdown();
}
private static void doExchangeWork(String data1,Exchanger exchanger){
System.out.println(Thread.currentThread().getName()+"exchange:"+data1);
try {
String data2 = (String) exchanger.exchange(data1);
System.out.println(Thread.currentThread().getName()+"exchange to"+data2);
} catch (InterruptedException e) {
e.printStackTrace();
}
}
}
3.Executor
四种线程池:newFixedThreadPool,newCachedThreadPool,newSingleThreadExecutor,newScheduledThreadPool
1.newFixedThreadPool创建一个可重用固定线程数的线程池,以共享的×××队列方式来运行线程。
2.newCachedThreadPool创建一个可缓存线程池,如果线程池长度超过处理需要,可灵活回收空闲线程
3.newScheduledThreadPool创建一个定长线程池,支持定时及周期性任务执行
4.newSingleThreadExecutor创建一个单线程化的线程池,它只会用唯一的工作线程来执行任务,保证所有任务按照指定顺序(FIFO,LIFO,优先级)执行
任务分两类:一类是实现了Runnable接口的类,一类是实现了Callable接口的类, Callable的call()方法只能通过ExecutorService的submit(Callable task)方法来执行,
并且返回一个Future.
4.lock
Synchronized缺点
1.无法中断
2.无法设置超时
3.使用在方法上的synchronized其实是个语法糖
lock(),trylock(),tryLock(long time,TimeUnit unit)和lockInterruptibly()是用来获取锁的,unlock()方法是用来释放锁的。
ReentrantLock 可重入锁
5.atomic
标量类:AtomicBoolean,AtomicInteger,AtomicLong,AtomicReference
数组类:AtomicIntegerArray,AtomicLongArray,AtomicReferenceArray
更新器类:AtomicLongFieldUpdater,AtomicIntegerFieldUpdater,AtomicReferenceFieldUpdater
复合变量类:AtomicMarkableReference,AtomicStampedReference
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