1. 类 Executors
Executors类可以看做一个“工具类”。援引JDK1.6 API中的介绍:
此包中所定义的 Executor、ExecutorService、ScheduledExecutorService、ThreadFactory 和 Callable 类的工厂和实用方法。此类支持以下各种方法:
(1)创建并返回设置有常用配置字符串的 ExecutorService 的方法。
(2)创建并返回设置有常用配置字符串的 ScheduledExecutorService 的方法。
(3)创建并返回“包装的”ExecutorService 方法,它通过使特定于实现的方法不可访问来禁用重新配置。
(4)创建并返回 ThreadFactory 的方法,它可将新创建的线程设置为已知的状态。
(5)创建并返回非闭包形式的 Callable 的方法,这样可将其用于需要 Callable 的执行方法中。
通过这个类能够获得多种线程池的实例,例如可以调用newSingleThreadExecutor()获得单线程的ExecutorService,调 用newFixedThreadPool()获得固定大小线程池的ExecutorService,等等。拿到ExecutorService可以做的事情就比 较多了,最简单的是用它来执行Runnable对象,也可以执行一些实现了Callable<T>的对象。用Thread的start()方 法没有返回值,如果该线程执行的方法有返回值那用ExecutorService就再好不过了,可以选择submit()、invokeAll()或者 invokeAny(),根据具体情况选择合适的方法即可。
此类中提供的一些方法有:
1.1 public static ExecutorService newCachedThreadPool()
创建一个可根据需要创建新线程的线程池,但是在以前构造的线程可用时将重用它们。对于执行很多短期异步任务的程序而言,这些线程池通常可提高程序性能。
1.2 public static ExecutorService newFixedThreadPool(int nThreads)
创建一个可重用固定线程数的线程池,以共享的*队列方式来运行这些线程。
1.3 public static ExecutorService newSingleThreadExecutor()
创建一个使用单个 worker 线程的 Executor,以*队列方式来运行该线程。
这三个方法都可以配合接口ThreadFactory的实例一起使用。并且返回一个ExecutorService接口的实例。
2. 接口 ThreadFactory
根据需要创建新线程的对象。使用线程工厂就无需再手工编写对 new Thread 的调用了,从而允许应用程序使用特殊的线程子类、属性等等。
此接口最简单的实现就是:
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class SimpleThreadFactory implements ThreadFactory {
public Thread newThread(Runnable r) {
return new Thread(r);
}
}
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3. 接口ExecutorService
该接口提供了管理终止的方法。
4.创建标准线程池启动线程
4.1 提供一个简单的实现Runnable接口的线程
MyThread.java
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package com.zj.concurrency.executors;
public class MyThread implements Runnable {
private int count = 1 , number;
public MyThread( int num) {
number = num;
System.out.println( "Create Thread-" + number);
}
public void run() {
while ( true ) {
System.out.println( "Thread-" + number + " run " + count+ " time(s)" );
if (++count == 3 )
return ;
}
}
}
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这个线程会打印出相应的创建和执行信息。
4.2使用CachedThreadPool启动线程
CachedThreadPool.java
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package com.zj.concurrency.executors;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
public class CachedThreadPool {
public static void main(String[] args) {
ExecutorService exec = Executors.newCachedThreadPool();
for ( int i = 0 ; i < 5 ; i++)
exec.execute( new MyThread(i));
exec.shutdown();
}
}
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结果:
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Create Thread-0
Create Thread-1
Create Thread-2
Create Thread-3
Thread-0 run 1 time(s)
Thread-0 run 2 time(s)
Thread-1 run 1 time(s)
Thread-1 run 2 time(s)
Thread-2 run 1 time(s)
Thread-2 run 2 time(s)
Create Thread-4
Thread-4 run 1 time(s)
Thread-4 run 2 time(s)
Thread-3 run 1 time(s)
Thread-3 run 2 time(s)
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4.3 使用FixedThreadPool启动线程
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FixedThreadPool.java
package com.zj.concurrency.executors;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
public class FixedThreadPool {
public static void main(String[] args) {
ExecutorService exec = Executors.newFixedThreadPool( 2 );
for ( int i = 0 ; i < 5 ; i++)
exec.execute( new MyThread(i));
exec.shutdown();
}
}
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结果:
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Create Thread-0
Create Thread-1
Create Thread-2
Create Thread-3
Create Thread-4
Thread-0 run 1 time(s)
Thread-0 run 2 time(s)
Thread-2 run 1 time(s)
Thread-2 run 2 time(s)
Thread-3 run 1 time(s)
Thread-3 run 2 time(s)
Thread-4 run 1 time(s)
Thread-4 run 2 time(s)
Thread-1 run 1 time(s)
Thread-1 run 2 time(s)
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4.4 使用SingleThreadExecutor启动线程
SingleThreadExecutor.java
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package com.zj.concurrency.executors;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
public class SingleThreadExecutor {
public static void main(String[] args) {
ExecutorService exec = Executors.newSingleThreadExecutor();
for ( int i = 0 ; i < 5 ; i++)
exec.execute( new MyThread(i));
exec.shutdown();
}
}
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结果:
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Create Thread-0
Create Thread-1
Create Thread-2
Create Thread-3
Create Thread-4
Thread-0 run 1 time(s)
Thread-0 run 2 time(s)
Thread-1 run 1 time(s)
Thread-1 run 2 time(s)
Thread-2 run 1 time(s)
Thread-2 run 2 time(s)
Thread-3 run 1 time(s)
Thread-3 run 2 time(s)
Thread-4 run 1 time(s)
Thread-4 run 2 time(s)
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5.配合ThreadFactory接口的使用
我们试图给线程加入daemon和priority的属性设置。
5.1设置后台线程属性
DaemonThreadFactory.java
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package com.zj.concurrency.executors.factory;
import java.util.concurrent.ThreadFactory;
public class DaemonThreadFactory implements ThreadFactory {
public Thread newThread(Runnable r) {
Thread t = new Thread(r);
t.setDaemon( true );
return t;
}
}
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5.2 设置优先级属性
最高优先级MaxPriorityThreadFactory.java
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package com.zj.concurrency.executors.factory;
import java.util.concurrent.ThreadFactory;
public class MaxPriorityThreadFactory implements ThreadFactory {
public Thread newThread(Runnable r) {
Thread t = new Thread(r);
t.setPriority(Thread.MAX_PRIORITY);
return t;
}
}
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最低优先级MinPriorityThreadFactory.java
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package com.zj.concurrency.executors.factory;
import java.util.concurrent.ThreadFactory;
public class MinPriorityThreadFactory implements ThreadFactory {
public Thread newThread(Runnable r) {
Thread t = new Thread(r);
t.setPriority(Thread.MIN_PRIORITY);
return t;
}
}
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5.3启动带有属性设置的线程
ExecFromFactory.java
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package com.zj.concurrency.executors;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import com.zj.concurrency.executors.factory.DaemonThreadFactory;
import com.zj.concurrency.executors.factory.MaxPriorityThreadFactory;
import com.zj.concurrency.executors.factory.MinPriorityThreadFactory;
public class ExecFromFactory {
public static void main(String[] args) throws Exception {
ExecutorService defaultExec = Executors.newCachedThreadPool();
ExecutorService daemonExec = Executors
.newCachedThreadPool( new DaemonThreadFactory());
ExecutorService maxPriorityExec = Executors
.newCachedThreadPool( new MaxPriorityThreadFactory());
ExecutorService minPriorityExec = Executors
.newCachedThreadPool( new MinPriorityThreadFactory());
for ( int i = 0 ; i < 10 ; i++)
daemonExec.execute( new MyThread(i));
for ( int i = 10 ; i < 20 ; i++)
if (i == 10 )
maxPriorityExec.execute( new MyThread(i));
else if (i == 11 )
minPriorityExec.execute( new MyThread(i));
else
defaultExec.execute( new MyThread(i));
}
}
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结果:
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Create Thread-0
Create Thread-1
Create Thread-2
Create Thread-3
Thread-0 run 1 time(s)
Thread-0 run 2 time(s)
Thread-1 run 1 time(s)
Thread-1 run 2 time(s)
Thread-2 run 1 time(s)
Thread-2 run 2 time(s)
Create Thread-4
Thread-4 run 1 time(s)
Thread-4 run 2 time(s)
Create Thread-5
Thread-5 run 1 time(s)
Thread-5 run 2 time(s)
Create Thread-6
Create Thread-7
Thread-7 run 1 time(s)
Thread-7 run 2 time(s)
Create Thread-8
Thread-8 run 1 time(s)
Thread-8 run 2 time(s)
Create Thread-9
Create Thread-10
Thread-10 run 1 time(s)
Thread-10 run 2 time(s)
Create Thread-11
Thread-9 run 1 time(s)
Thread-9 run 2 time(s)
Thread-6 run 1 time(s)
Thread-6 run 2 time(s)
Thread-3 run 1 time(s)
Thread-3 run 2 time(s)
Create Thread-12
Create Thread-13
Create Thread-14
Thread-12 run 1 time(s)
Thread-12 run 2 time(s)
Thread-13 run 1 time(s)
Thread-13 run 2 time(s)
Create Thread-15
Thread-15 run 1 time(s)
Thread-15 run 2 time(s)
Create Thread-16
Thread-16 run 1 time(s)
Thread-16 run 2 time(s)
Create Thread-17
Create Thread-18
Create Thread-19
Thread-14 run 1 time(s)
Thread-14 run 2 time(s)
Thread-17 run 1 time(s)
Thread-17 run 2 time(s)
Thread-18 run 1 time(s)
Thread-18 run 2 time(s)
Thread-19 run 1 time(s)
Thread-19 run 2 time(s)
Thread-11 run 1 time(s)
Thread-11 run 2 time(s)
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