一、前言
上周工作遇到了一个需求,同步多个省份销号数据,解绑微信粉丝。分省定时将销号数据放到SFTP服务器上,我需要开发定时任务去解析文件。因为是多省份,服务器、文件名规则、数据规则都不一定,所以要做成可配置是有一定难度的。数据规则这块必须强烈要求统一,服务器、文件名规则都可以从配置中心去读。每新增一个省份的配置,后台感知到后,动态生成定时任务。
二、Springboot引入定时任务核心配置
@Target(ElementType.TYPE) @Retention(RetentionPolicy.RUNTIME) @Import(SchedulingConfiguration.class) @Documented public @interface EnableScheduling { } @Configuration @Role(BeanDefinition.ROLE_INFRASTRUCTURE) public class SchedulingConfiguration { @Bean(name = TaskManagementConfigUtils.SCHEDULED_ANNOTATION_PROCESSOR_BEAN_NAME) @Role(BeanDefinition.ROLE_INFRASTRUCTURE) public ScheduledAnnotationBeanPostProcessor scheduledAnnotationProcessor() { return new ScheduledAnnotationBeanPostProcessor(); } }
接下来主要看一下这个核心后置处理器:ScheduledAnnotationBeanPostProcessor 。
@Override
public Object postProcessAfterInitialization(Object bean, String beanName) {
if (bean instanceof AopInfrastructureBean || bean instanceof TaskScheduler ||
bean instanceof ScheduledExecutorService) {
// Ignore AOP infrastructure such as scoped proxies.
return bean;
}
Class<?> targetClass = AopProxyUtils.ultimateTargetClass(bean);
if (!this.nonAnnotatedClasses.contains(targetClass)) {
Map<Method, Set<Scheduled>> annotatedMethods = MethodIntrospector.selectMethods(targetClass,
(MethodIntrospector.MetadataLookup<Set<Scheduled>>) method -> {
Set<Scheduled> scheduledMethods = AnnotatedElementUtils.getMergedRepeatableAnnotations(
method, Scheduled.class, Schedules.class);
return (!scheduledMethods.isEmpty() ? scheduledMethods : null);
});
if (annotatedMethods.isEmpty()) {
this.nonAnnotatedClasses.add(targetClass);
if (logger.isTraceEnabled()) {
logger.trace("No @Scheduled annotations found on bean class: " + targetClass);
}
}
else {
// Non-empty set of methods
annotatedMethods.forEach((method, scheduledMethods) ->
scheduledMethods.forEach(scheduled -> processScheduled(scheduled, method, bean)));
if (logger.isTraceEnabled()) {
logger.trace(annotatedMethods.size() + " @Scheduled methods processed on bean '" + beanName +
"': " + annotatedMethods);
}
}
}
return bean;
}
1、处理Scheduled注解,通过ScheduledTaskRegistrar注册定时任务。
private void finishRegistration() { if (this.scheduler != null) { this.registrar.setScheduler(this.scheduler); } if (this.beanFactory instanceof ListableBeanFactory) { Map<String, SchedulingConfigurer> beans = ((ListableBeanFactory) this.beanFactory).getBeansOfType(SchedulingConfigurer.class); List<SchedulingConfigurer> configurers = new ArrayList<>(beans.values()); AnnotationAwareOrderComparator.sort(configurers); for (SchedulingConfigurer configurer : configurers) { configurer.configureTasks(this.registrar); } } if (this.registrar.hasTasks() && this.registrar.getScheduler() == null) { Assert.state(this.beanFactory != null, "BeanFactory must be set to find scheduler by type"); try { // Search for TaskScheduler bean... this.registrar.setTaskScheduler(resolveSchedulerBean(this.beanFactory, TaskScheduler.class, false)); } catch (NoUniqueBeanDefinitionException ex) { logger.trace("Could not find unique TaskScheduler bean", ex); try { this.registrar.setTaskScheduler(resolveSchedulerBean(this.beanFactory, TaskScheduler.class, true)); } catch (NoSuchBeanDefinitionException ex2) { if (logger.isInfoEnabled()) { logger.info("More than one TaskScheduler bean exists within the context, and " + "none is named 'taskScheduler'. Mark one of them as primary or name it 'taskScheduler' " + "(possibly as an alias); or implement the SchedulingConfigurer interface and call " + "ScheduledTaskRegistrar#setScheduler explicitly within the configureTasks() callback: " + ex.getBeanNamesFound()); } } } catch (NoSuchBeanDefinitionException ex) { logger.trace("Could not find default TaskScheduler bean", ex); // Search for ScheduledExecutorService bean next... try { this.registrar.setScheduler(resolveSchedulerBean(this.beanFactory, ScheduledExecutorService.class, false)); } catch (NoUniqueBeanDefinitionException ex2) { logger.trace("Could not find unique ScheduledExecutorService bean", ex2); try { this.registrar.setScheduler(resolveSchedulerBean(this.beanFactory, ScheduledExecutorService.class, true)); } catch (NoSuchBeanDefinitionException ex3) { if (logger.isInfoEnabled()) { logger.info("More than one ScheduledExecutorService bean exists within the context, and " + "none is named 'taskScheduler'. Mark one of them as primary or name it 'taskScheduler' " + "(possibly as an alias); or implement the SchedulingConfigurer interface and call " + "ScheduledTaskRegistrar#setScheduler explicitly within the configureTasks() callback: " + ex2.getBeanNamesFound()); } } } catch (NoSuchBeanDefinitionException ex2) { logger.trace("Could not find default ScheduledExecutorService bean", ex2); // Giving up -> falling back to default scheduler within the registrar... logger.info("No TaskScheduler/ScheduledExecutorService bean found for scheduled processing"); } } } this.registrar.afterPropertiesSet(); }
1、通过一系列的SchedulingConfigurer动态配置ScheduledTaskRegistrar。
2、向ScheduledTaskRegistrar注册一个TaskScheduler(用于对Runnable的任务进行调度,它包含有多种触发规则)。
3、registrar.afterPropertiesSet(),在这开始安排所有的定时任务开始执行了。
protected void scheduleTasks() { if (this.taskScheduler == null) { this.localExecutor = Executors.newSingleThreadScheduledExecutor(); this.taskScheduler = new ConcurrentTaskScheduler(this.localExecutor); } if (this.triggerTasks != null) { for (TriggerTask task : this.triggerTasks) { addScheduledTask(scheduleTriggerTask(task)); } } if (this.cronTasks != null) { for (CronTask task : this.cronTasks) { addScheduledTask(scheduleCronTask(task)); } } if (this.fixedRateTasks != null) { for (IntervalTask task : this.fixedRateTasks) { addScheduledTask(scheduleFixedRateTask(task)); } } if (this.fixedDelayTasks != null) { for (IntervalTask task : this.fixedDelayTasks) { addScheduledTask(scheduleFixedDelayTask(task)); } } }
1、TriggerTask:动态定时任务。通过Trigger#nextExecutionTime 给定的触发上下文确定下一个执行时间。
2、CronTask:动态定时任务,TriggerTask子类。通过cron表达式确定的时间触发下一个任务执行。
3、IntervalTask:一定时间延迟之后,周期性执行的任务。
4、taskScheduler 如果为空,默认是ConcurrentTaskScheduler,并使用默认单线程的ScheduledExecutor。
三、主要看一下CronTask工作原理
ScheduledTaskRegistrar.java @Nullable public ScheduledTask scheduleCronTask(CronTask task) { ScheduledTask scheduledTask = this.unresolvedTasks.remove(task); boolean newTask = false; if (scheduledTask == null) { scheduledTask = new ScheduledTask(task); newTask = true; } if (this.taskScheduler != null) { scheduledTask.future = this.taskScheduler.schedule(task.getRunnable(), task.getTrigger()); } else { addCronTask(task); this.unresolvedTasks.put(task, scheduledTask); } return (newTask ? scheduledTask : null); } ConcurrentTaskScheduler.java @Override @Nullable public ScheduledFuture<?> schedule(Runnable task, Trigger trigger) { try { if (this.enterpriseConcurrentScheduler) { return new EnterpriseConcurrentTriggerScheduler().schedule(decorateTask(task, true), trigger); } else { ErrorHandler errorHandler = (this.errorHandler != null ? this.errorHandler : TaskUtils.getDefaultErrorHandler(true)); return new ReschedulingRunnable(task, trigger, this.scheduledExecutor, errorHandler).schedule(); } } catch (RejectedExecutionException ex) { throw new TaskRejectedException("Executor [" + this.scheduledExecutor + "] did not accept task: " + task, ex); } } ReschedulingRunnable.java @Nullable public ScheduledFuture<?> schedule() { synchronized (this.triggerContextMonitor) { this.scheduledExecutionTime = this.trigger.nextExecutionTime(this.triggerContext); if (this.scheduledExecutionTime == null) { return null; } long initialDelay = this.scheduledExecutionTime.getTime() - System.currentTimeMillis(); this.currentFuture = this.executor.schedule(this, initialDelay, TimeUnit.MILLISECONDS); return this; } } private ScheduledFuture<?> obtainCurrentFuture() { Assert.state(this.currentFuture != null, "No scheduled future"); return this.currentFuture; } @Override public void run() { Date actualExecutionTime = new Date(); super.run(); Date completionTime = new Date(); synchronized (this.triggerContextMonitor) { Assert.state(this.scheduledExecutionTime != null, "No scheduled execution"); this.triggerContext.update(this.scheduledExecutionTime, actualExecutionTime, completionTime); if (!obtainCurrentFuture().isCancelled()) { schedule(); } } }
1、最终将task和trigger都封装到了ReschedulingRunnable中。
2、ReschedulingRunnable实现了任务重复调度(schedule方法中调用调度器executor并传入自身对象,executor会调用run方法,run方法又调用了schedule方法)。
3、ReschedulingRunnable schedule方法加了同步锁,只能有一个线程拿到下次执行时间并加入执行器的调度。
4、不同的ReschedulingRunnable对象之间在线程池够用的情况下是不会相互影响的,也就是说满足线程池的条件下,TaskScheduler的schedule方法的多次调用是可以交叉执行的。
ScheduledThreadPoolExecutor.java public ScheduledFuture<?> schedule(Runnable command, long delay, TimeUnit unit) { if (command == null || unit == null) throw new NullPointerException(); RunnableScheduledFuture<?> t = decorateTask(command, new ScheduledFutureTask<Void>(command, null, triggerTime(delay, unit))); delayedExecute(t); return t; } private void delayedExecute(RunnableScheduledFuture<?> task) { if (isShutdown()) reject(task); else { super.getQueue().add(task); if (isShutdown() && !canRunInCurrentRunState(task.isPeriodic()) && remove(task)) task.cancel(false); else ensurePrestart(); } }
ScheduledFutureTask 工作原理如下图所示【太懒了,不想画图了,盗图一张】。
1、ScheduledFutureTask会放入优先阻塞队列:ScheduledThreadPoolExecutor.DelayedWorkQueue(二叉最小堆实现)
2、上图中的Thread对象即ThreadPoolExecutor.Worker,实现了Runnable接口
/** * Creates with given first task and thread from ThreadFactory. * @param firstTask the first task (null if none) */ Worker(Runnable firstTask) { setState(-1); // inhibit interrupts until runWorker this.firstTask = firstTask; this.thread = getThreadFactory().newThread(this); } /** Delegates main run loop to outer runWorker */ public void run() { runWorker(this); }
1、Worker中维护了Thread对象,Thread对象的Runnable实例即Worker自身
2、ThreadPoolExecutor#addWorker方法中会创建Worker对象,然后拿到Worker中的thread实例并start,这样就创建了线程池中的一个线程实例
3、Worker的run方法会调用ThreadPoolExecutor#runWorker方法,这才是任务最终被执行的地方,该方法示意如下
(1)首先取传入的task执行,如果task是null,只要该线程池处于运行状态,就会通过getTask方法从workQueue中取任务。ThreadPoolExecutor的execute方法会在无法产生core线程的时候向 workQueue队列中offer任务。
getTask方法从队列中取task的时候会根据相关配置决定是否阻塞和阻塞多久。如果getTask方法结束,返回的是null,runWorker循环结束,执行processWorkerExit方法。
至此,该线程结束自己的使命,从线程池中“消失”。
(2)在开始执行任务之前,会调用Worker的lock方法,目的是阻止task正在被执行的时候被interrupt,通过调用clearInterruptsForTaskRun方法来保证的(后面可以看一下这个方法),该线程没有自己的interrupt set了。
(3)beforeExecute和afterExecute方法用于在执行任务前后执行一些自定义的操作,这两个方法是空的,留给继承类去填充功能。
我们可以在beforeExecute方法中抛出异常,这样task不会被执行,而且在跳出该循环的时候completedAbruptly的值是true,表示the worker died due to user exception,会用decrementWorkerCount调整wc。
(4)因为Runnable的run方法不能抛出Throwables异常,所以这里重新包装异常然后抛出,抛出的异常会使当当前线程死掉,可以在afterExecute中对异常做一些处理。
(5)afterExecute方法也可能抛出异常,也可能使当前线程死掉。
四、动态创建定时任务
TaskConfiguration 配置类
@Configuration @EnableScheduling @Role(BeanDefinition.ROLE_INFRASTRUCTURE) public class TaskConfiguration { @Bean(name = ScheduledAnnotationBeanPostProcessor.DEFAULT_TASK_SCHEDULER_BEAN_NAME) @Role(BeanDefinition.ROLE_INFRASTRUCTURE) public ScheduledExecutorService scheduledAnnotationProcessor() { return Executors.newScheduledThreadPool(5, new DefaultThreadFactory()); } private static class DefaultThreadFactory implements ThreadFactory { private static final AtomicInteger poolNumber = new AtomicInteger(1); private final ThreadGroup group; private final AtomicInteger threadNumber = new AtomicInteger(1); private final String namePrefix; DefaultThreadFactory() { SecurityManager s = System.getSecurityManager(); group = (s != null) ? s.getThreadGroup() : Thread.currentThread().getThreadGroup(); namePrefix = "pool-" + poolNumber.getAndIncrement() + "-schedule-"; } @Override public Thread newThread(Runnable r) { Thread t = new Thread(group, r, namePrefix + threadNumber.getAndIncrement(), 0); if (t.isDaemon()) { t.setDaemon(false); } if (t.getPriority() != Thread.NORM_PRIORITY) { t.setPriority(Thread.NORM_PRIORITY); } return t; } } }
1、保证ConcurrentTaskScheduler不使用默认单线程的ScheduledExecutor,而是corePoolSize=5的线程池
2、自定义线程池工厂类
DynamicTask 动态定时任务
@Configuration public class DynamicTask implements SchedulingConfigurer { private static Logger LOGGER = LoggerFactory.getLogger(DynamicTask.class); private static final ExecutorService es = new ThreadPoolExecutor(10, 20, 0L, TimeUnit.MILLISECONDS, new LinkedBlockingQueue<>(10), new DynamicTaskConsumeThreadFactory()); private volatile ScheduledTaskRegistrar registrar; private final ConcurrentHashMap<String, ScheduledFuture<?>> scheduledFutures = new ConcurrentHashMap<>(); private final ConcurrentHashMap<String, CronTask> cronTasks = new ConcurrentHashMap<>(); private volatile List<TaskConstant> taskConstants = Lists.newArrayList(); @Override public void configureTasks(ScheduledTaskRegistrar registrar) { this.registrar = registrar; this.registrar.addTriggerTask(() -> { if (!CollectionUtils.isEmpty(taskConstants)) { LOGGER.info("检测动态定时任务列表..."); List<TimingTask> tts = new ArrayList<>(); taskConstants .forEach(taskConstant -> { TimingTask tt = new TimingTask(); tt.setExpression(taskConstant.getCron()); tt.setTaskId("dynamic-task-" + taskConstant.getTaskId()); tts.add(tt); }); this.refreshTasks(tts); } } , triggerContext -> new PeriodicTrigger(5L, TimeUnit.SECONDS).nextExecutionTime(triggerContext)); } public List<TaskConstant> getTaskConstants() { return taskConstants; } private void refreshTasks(List<TimingTask> tasks) { //取消已经删除的策略任务 Set<String> taskIds = scheduledFutures.keySet(); for (String taskId : taskIds) { if (!exists(tasks, taskId)) { scheduledFutures.get(taskId).cancel(false); } } for (TimingTask tt : tasks) { String expression = tt.getExpression(); if (StringUtils.isBlank(expression) || !CronSequenceGenerator.isValidExpression(expression)) { LOGGER.error("定时任务DynamicTask cron表达式不合法: " + expression); continue; } //如果配置一致,则不需要重新创建定时任务 if (scheduledFutures.containsKey(tt.getTaskId()) && cronTasks.get(tt.getTaskId()).getExpression().equals(expression)) { continue; } //如果策略执行时间发生了变化,则取消当前策略的任务 if (scheduledFutures.containsKey(tt.getTaskId())) { scheduledFutures.remove(tt.getTaskId()).cancel(false); cronTasks.remove(tt.getTaskId()); } CronTask task = new CronTask(tt, expression); ScheduledFuture<?> future = registrar.getScheduler().schedule(task.getRunnable(), task.getTrigger()); cronTasks.put(tt.getTaskId(), task); scheduledFutures.put(tt.getTaskId(), future); } } private boolean exists(List<TimingTask> tasks, String taskId) { for (TimingTask task : tasks) { if (task.getTaskId().equals(taskId)) { return true; } } return false; } @PreDestroy public void destroy() { this.registrar.destroy(); } public static class TaskConstant { private String cron; private String taskId; public String getCron() { return cron; } public void setCron(String cron) { this.cron = cron; } public String getTaskId() { return taskId; } public void setTaskId(String taskId) { this.taskId = taskId; } } private class TimingTask implements Runnable { private String expression; private String taskId; public String getTaskId() { return taskId; } public void setTaskId(String taskId) { this.taskId = taskId; } @Override public void run() { //设置队列大小10 LOGGER.error("当前CronTask: " + this); DynamicBlockingQueue queue = new DynamicBlockingQueue(3); es.submit(() -> { while (!queue.isDone() || !queue.isEmpty()) { try { String content = queue.poll(500, TimeUnit.MILLISECONDS); if (StringUtils.isBlank(content)) { return; } LOGGER.info("DynamicBlockingQueue 消费:" + content); TimeUnit.MILLISECONDS.sleep(500); } catch (InterruptedException e) { e.printStackTrace(); } } }); //队列放入数据 for (int i = 0; i < 5; ++i) { try { queue.put(String.valueOf(i)); LOGGER.info("DynamicBlockingQueue 生产:" + i); } catch (InterruptedException e) { e.printStackTrace(); } } queue.setDone(true); } public String getExpression() { return expression; } public void setExpression(String expression) { this.expression = expression; } @Override public String toString() { return ReflectionToStringBuilder.toString(this , ToStringStyle.JSON_STYLE , false , false , TimingTask.class); } } /** * 队列消费线程工厂类 */ private static class DynamicTaskConsumeThreadFactory implements ThreadFactory { private static final AtomicInteger poolNumber = new AtomicInteger(1); private final ThreadGroup group; private final AtomicInteger threadNumber = new AtomicInteger(1); private final String namePrefix; DynamicTaskConsumeThreadFactory() { SecurityManager s = System.getSecurityManager(); group = (s != null) ? s.getThreadGroup() : Thread.currentThread().getThreadGroup(); namePrefix = "pool-" + poolNumber.getAndIncrement() + "-dynamic-task-"; } @Override public Thread newThread(Runnable r) { Thread t = new Thread(group, r, namePrefix + threadNumber.getAndIncrement(), 0); if (t.isDaemon()) { t.setDaemon(false); } if (t.getPriority() != Thread.NORM_PRIORITY) { t.setPriority(Thread.NORM_PRIORITY); } return t; } } private static class DynamicBlockingQueue extends LinkedBlockingQueue<String> { DynamicBlockingQueue(int capacity) { super(capacity); } private volatile boolean done = false; public boolean isDone() { return done; } public void setDone(boolean done) { this.done = done; } } }
1、taskConstants 动态任务列表
2、ScheduledTaskRegistrar#addTriggerTask 添加动态周期定时任务,检测动态任务列表的变化
CronTask task = new CronTask(tt, expression);
ScheduledFuture<?> future = registrar.getScheduler().schedule(task.getRunnable(), task.getTrigger());
cronTasks.put(tt.getTaskId(), task);
scheduledFutures.put(tt.getTaskId(), future);
3、动态创建cron定时任务,拿到ScheduledFuture实例并缓存起来
4、在刷新任务列表时,通过缓存的ScheduledFuture实例和CronTask实例,来决定是否取消、移除失效的动态定时任务。
DynamicTaskTest 动态定时任务测试类
@RunWith(SpringRunner.class) @SpringBootTest public class DynamicTaskTest { @Autowired private DynamicTask dynamicTask; @Test public void test() throws InterruptedException { List<DynamicTask.TaskConstant> taskConstans = dynamicTask.getTaskConstants(); DynamicTask.TaskConstant taskConstant = new DynamicTask.TaskConstant(); taskConstant.setCron("0/5 * * * * ?"); taskConstant.setTaskId("test1"); taskConstans.add(taskConstant); DynamicTask.TaskConstant taskConstant1 = new DynamicTask.TaskConstant(); taskConstant1.setCron("0/5 * * * * ?"); taskConstant1.setTaskId("test2"); taskConstans.add(taskConstant1); DynamicTask.TaskConstant taskConstant2 = new DynamicTask.TaskConstant(); taskConstant2.setCron("0/5 * * * * ?"); taskConstant2.setTaskId("test3"); taskConstans.add(taskConstant2); TimeUnit.SECONDS.sleep(40); //移除并添加新的配置 taskConstans.remove(taskConstans.size() - 1); DynamicTask.TaskConstant taskConstant3 = new DynamicTask.TaskConstant(); taskConstant3.setCron("0/5 * * * * ?"); taskConstant3.setTaskId("test4"); taskConstans.add(taskConstant3); // TimeUnit.MINUTES.sleep(50); } }