最近做项目,使用到了FutureTask和主线程并发,应用到实际中还是挺实用的,特在此总结一下。
有不对之处,忘各位多多指出。
package com.demo; import java.util.concurrent.Callable;
import java.util.concurrent.FutureTask; public class FutureTaskTest { public static void main(String[] args) throws Exception {
for (int i = 0; i < 10; i++) {
long currentTimeMillis = System.currentTimeMillis();
FutureTask<String> future1 = new FutureTask<>(new MyTaskA());
new Thread(future1).start();// 一定要先开启线程,如果主线程在开启线程前调用,就没了并发的效果,可以自行测试
Thread.sleep(100);// 主线程耗时100ms
String r1 = future1.get();
System.out.println(r1);
System.err.println(i + "-----" + String.valueOf(System.currentTimeMillis() - currentTimeMillis) + "ms");
}
} static class MyTaskA implements Callable<String> {
@Override
public String call() throws Exception {
Thread.sleep(50);// 并发线程耗时50ms
return "testA";
}
} }
20-26行创建一个任务MyTaskA,实现的是Callable,主要是为了获取返回值(关于如何创建线程,这里就不在赘述);
11行创建FutureTask;
12行启动线程:此时任务MyTaskA就已经开始执行;
13行主线程执行耗时100ms的任务;
14行FutureTask获取返回值,该方法是会等待任务完成然后获取到返回值。
输出结果如下:
testA
0-----101ms
testA
1-----100ms
testA
2-----100ms
testA
3-----100ms
testA
4-----100ms
testA
5-----100ms
testA
6-----100ms
testA
7-----100ms
testA
8-----100ms
testA
9-----100ms
上面就是一个线程和主线程并发执行,下面再看一个两个线程和主线程并发,其实差别不大
package com.demo; import java.util.concurrent.Callable;
import java.util.concurrent.FutureTask; public class FutureTaskTest { public static void main(String[] args) throws Exception{
for (int i = 0; i < 10; i++) {
long currentTimeMillis = System.currentTimeMillis(); FutureTask<String> futureA = new FutureTask<>(new MyTaskA());
FutureTask<String> futureB = new FutureTask<>(new MyTaskB());
new Thread(futureA).start();
new Thread(futureB).start(); Thread.sleep(100);
System.out.println(futureA.get()+"---"+futureB.get());
System.err.println(i+"-----"+String.valueOf(System.currentTimeMillis()-currentTimeMillis)+"ms");
}
}
static class MyTaskA implements Callable<String>{
@Override
public String call() throws Exception {
Thread.sleep(50);//并发线程耗时50ms
return "testA";
}
}
static class MyTaskB implements Callable<String>{
@Override
public String call() throws Exception {
Thread.sleep(50);
return "testB";
}
} }
执行结果如下
testA---testB
0-----103ms
testA---testB
1-----100ms
testA---testB
2-----100ms
testA---testB
3-----100ms
testA---testB
4-----100ms
testA---testB
5-----101ms
testA---testB
6-----100ms
testA---testB
7-----101ms
testA---testB
8-----100ms
testA---testB
9-----101ms
上面使用Thread启动的FutureTask,咱们也可以用线程池,代码如下
package com.demo; import java.util.concurrent.Callable;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Future; public class FutureTaskTest { public static void main(String[] args) throws Exception {
for (int i = 0; i < 10; i++) {
long currentTimeMillis = System.currentTimeMillis();
ExecutorService executorService = Executors.newFixedThreadPool(2);
Future<String> futureA = executorService.submit(new MyTaskA());
Future<String> futureB = executorService.submit(new MyTaskB()); Thread.sleep(100);
System.out.println(futureA.get() + "---" + futureB.get());
System.err.println(i + "-----" + String.valueOf(System.currentTimeMillis() - currentTimeMillis) + "ms");
executorService.shutdown();//注意:用完之后一定要关闭线程池
}
} static class MyTaskA implements Callable<String> {
@Override
public String call() throws Exception {
Thread.sleep(50);// 并发线程耗时50ms
return "testA";
}
} static class MyTaskB implements Callable<String> {
@Override
public String call() throws Exception {
Thread.sleep(50);
return "testB";
}
} }
输出结果如下
testA---testB
0-----104ms
testA---testB
1-----101ms
testA---testB
2-----101ms
testA---testB
3-----101ms
testA---testB
4-----100ms
testA---testB
5-----102ms
testA---testB
6-----101ms
testA---testB
7-----101ms
testA---testB
8-----101ms
testA---testB
9-----101ms