定时任务ScheduledThreadPoolExecutor的使用详解
前短时间需要用到一个定时器处理蓝牙设备接收的数据,并且需要处理的频率是很快的,这就需要一个稳定的定时器来保证数据的长久进行。ScheduledThreadPoolExecutor这个类就是个很好的选择。
正常情况下,定时器我们都是用Timer和TimerTask这两个类就能完成定时任务,并且设置延长时间和循环时间间隔。
ScheduledThreadPoolExecutor也能完成Timer一样的定时任务,并且时间间隔更加准确。
误差说明:
我在后台程序看看一下Timer执行程序是有可能延迟1、2毫秒,如果是1秒执行一次的任务,1分钟有可能延迟60毫秒,一小时延迟3600毫秒,相当于3秒,实际用户看不出什么区别。
但是,如果我的程序需要每40毫秒就执行一次任务,如果还是有1、2毫秒的误差,1秒钟就有25毫秒的误差,大概40秒就有1秒的误差,十几分钟就有十几秒的误差,这对UI显示来说是延迟非常严重的了。
而我用ScheduledThreadPoolExecutor来做40毫秒的间隔任务,一般十几分钟才有1秒多的误差,这个还是能接受的。
这也是我用ScheduledThreadPoolExecutor这个类的原因。
ScheduledThreadPoolExecutor的介绍
ScheduledThreadPoolExecutor,它可另行安排在给定的延迟后运行命令,或者定期执行命令。需要多个辅助线程时,或者要求 ThreadPoolExecutor 具有额外的灵活性或功能时,此类要优于Timer。
使用Timer和TimerTask存在一些缺陷:
1.Timer只创建了一个线程。当你的任务执行的时间超过设置的延时时间将会产生一些问题。
2.Timer创建的线程没有处理异常,因此一旦抛出非受检异常,该线程会立即终止。
JDK 5.0以后推荐使用ScheduledThreadPoolExecutor。该类属于Executor Framework,它除了能处理异常外,还可以创建多个线程解决上面的问题
Timer和TimerTask的使用
这个大家应该都是会使用的了,但是还是給给大家看看代码:
Timer timer = new Timer();
timer.schedule(new TimerTask() {
@Override
public void run() {
log.e("time:");
}
}, 2000, 40);//2000表示第一次执行任务延迟时间,40表示以后每隔多长时间执行一次run里面的任务ScheduledThreadPoolExecutor的使用
这里先学会简单使用再深入探讨。
ScheduledThreadPoolExecutor scheduled = new ScheduledThreadPoolExecutor(2);
scheduled.scheduleAtFixedRate(new Runnable() {
@Override
public void run() {
loge("time:");
}
}, 0, 40, TimeUnit.MILLISECONDS);//0表示首次执行任务的延迟时间,40表示每次执行任务的间隔时间,TimeUnit.MILLISECONDS执行的时间间隔数值单位
间隔单位毫秒:TimeUnit.MILLISECONDS
间隔单位秒:TimeUnit.SECONDS
间隔单位分钟:TimeUnit.MINUTES
间隔单位小时:TimeUnit.HOURS
间隔单位天:TimeUnit.DAYS
定时器的一个实例
使用Timer和TimerTask、ScheduledThreadPoolExecutor显示秒的定时器
效果:
这里看起来是每秒刷新一次UI,但是我为了看40毫秒的延迟效果,是每40 毫秒index加一,添加25次后,刷新一次UI,表面上看起来是和每秒刷新的效果。
代码:
package com.example.wenzhi.scheduledthreadpoolexecutordemo;
import android.os.Handler;
import android.os.Message;
import android.support.v7.app.AppCompatActivity;
import android.os.Bundle;
import android.util.Log;
import android.view.View;
import android.widget.TextView;
import java.util.Timer;
import java.util.TimerTask;
import java.util.concurrent.ScheduledThreadPoolExecutor;
import java.util.concurrent.TimeUnit;
public class MainActivity extends AppCompatActivity {
TextView tv_time;
int time;
@Override
protected void onCreate(Bundle savedInstanceState) {
super.onCreate(savedInstanceState);
setContentView(R.layout.activity_main);
tv_time = (TextView) findViewById(R.id.tv_time);
}
Handler handler = new Handler() {
@Override
public void handleMessage(Message msg) {
super.handleMessage(msg);
if (time % 25 == 0) {
tv_time.setText("" + time / 25);
}
}
};
/**
* 普通定时器
*/
Timer timer;
public void timer(View view) {
stopTimer1();
timer = new Timer();
timer.schedule(new TimerTask() {
@Override
public void run() {
loge("time:" + time++);//add
handler.sendEmptyMessage(11);
}
}, 2000, 40);
}
public void stop(View view) {
stopTimer1();
}
/**
* 停止定时器
*/
private void stopTimer1() {
if (timer != null) {
timer.cancel();
timer = null;
}
}
/**
* 稳定的定时器
*/
ScheduledThreadPoolExecutor scheduled;
public void timer2(View view) {
stopTimer2();
scheduled = new ScheduledThreadPoolExecutor(2);
scheduled.scheduleAtFixedRate(new Runnable() {
@Override
public void run() {
loge("time:" + time++);
handler.sendEmptyMessage(11);
}
}, 0, 40, TimeUnit.MILLISECONDS);
}
public void stop2(View view) {
stopTimer2();
}
/**
* 停止定时器
*/
private void stopTimer2() {
if (scheduled != null) {
scheduled.shutdownNow();
scheduled = null;
}
}
private void loge(String msg) {
Log.e("TAG", msg);
}
@Override
protected void onDestroy() {
super.onDestroy();
System.exit(0);
}
/**
* 数据清零
*/
public void clear(View view) {
time = 0;
tv_time.setText("" + time);
}
}
Log数据对比
Timer定时器
11-29 01:08:09.940 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:0
11-29 01:08:09.980 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:1
11-29 01:08:10.020 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:2
11-29 01:08:10.060 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:3
11-29 01:08:10.100 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:4
11-29 01:08:10.140 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:5
11-29 01:08:10.180 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:6
11-29 01:08:10.224 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:7
11-29 01:08:10.264 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:8
11-29 01:08:10.304 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:9
11-29 01:08:10.344 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:10
11-29 01:08:10.384 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:11
11-29 01:08:10.424 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:12
11-29 01:08:10.468 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:13
11-29 01:08:10.508 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:14
11-29 01:08:10.548 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:15
11-29 01:08:10.592 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:16
11-29 01:08:10.632 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:17
11-29 01:08:10.672 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:18
11-29 01:08:10.712 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:19
11-29 01:08:10.752 6070-20203/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:20可以看到上面时间间隔不是很稳定,有几个是间隔40多毫秒的
ScheduledThreadPoolExecutor定时器
11-29 01:11:13.492 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:0
11-29 01:11:13.528 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:1
11-29 01:11:13.564 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:2
11-29 01:11:13.604 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:3
11-29 01:11:13.644 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:4
11-29 01:11:13.684 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:5
11-29 01:11:13.724 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:6
11-29 01:11:13.764 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:7
11-29 01:11:13.804 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:8
11-29 01:11:13.844 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:9
11-29 01:11:13.888 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:10
11-29 01:11:13.924 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:11
11-29 01:11:13.984 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:12
11-29 01:11:14.004 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:13
11-29 01:11:14.044 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:14
11-29 01:11:14.084 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:15
11-29 01:11:14.124 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:16
11-29 01:11:14.164 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:17
11-29 01:11:14.204 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:18
11-29 01:11:14.244 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:19
11-29 01:11:14.284 6070-22987/com.example.wenzhi.scheduledthreadpoolexecutordemo E/TAG: time:20
可以看到上面的数据除了第一个和第二个,其他的数据都是非常稳定的,间隔时间都是40毫秒。
而且时间越长越能看出,这两种定时器的差距。