@Target(value=TYPE) @Retention(value=RUNTIME) @Import(value=SchedulingConfiguration.class) @Documented public @interface EnableScheduling
<task:*> XML namespace. To be used
on @Configuration classes as follows:
@Configuration
@EnableScheduling
public class AppConfig {
// various @Bean definitions
}
This enables detection of @Scheduled annotations on any Spring-managed
bean in the container. For example, given a class MyTask
package com.myco.tasks;
public class MyTask {
@Scheduled(fixedRate=1000)
public void work() {
// task execution logic
}
}
the following configuration would ensure that MyTask.work() is called
once every 1000 ms:
@Configuration
@EnableScheduling
public class AppConfig {
@Bean
public MyTask task() {
return new MyTask();
}
}
Alternatively, if MyTask were annotated with @Component, the
following configuration would ensure that its @Scheduled method is
invoked at the desired interval:
@Configuration
@EnableScheduling
@ComponentScan(basePackages="com.myco.tasks")
public class AppConfig {
}
Methods annotated with @Scheduled may even be declared directly within
@Configuration classes:
@Configuration
@EnableScheduling
public class AppConfig {
@Scheduled(fixedRate=1000)
public void work() {
// task execution logic
}
}
In all of the above scenarios, a default single-threaded task executor is used.
When more control is desired, a @Configuration class may implement
SchedulingConfigurer. This allows access to the underlying
ScheduledTaskRegistrar instance. For example, the following example
demonstrates how to customize the Executor used to execute scheduled
tasks:
@Configuration
@EnableScheduling
public class AppConfig implements SchedulingConfigurer {
@Override
public void configureTasks(ScheduledTaskRegistrar taskRegistrar) {
taskRegistrar.setScheduler(taskExecutor());
}
@Bean(destroyMethod="shutdown")
public Executor taskExecutor() {
return Executors.newScheduledThreadPool(100);
}
}
Note in the example above the use of @Bean(destroyMethod="shutdown").
This ensures that the task executor is properly shut down when the Spring
application context itself is closed.
Implementing SchedulingConfigurer also allows for fine-grained
control over task registration via the ScheduledTaskRegistrar.
For example, the following configures the execution of a particular bean
method per a custom Trigger implementation:
@Configuration
@EnableScheduling
public class AppConfig implements SchedulingConfigurer {
@Override
public void configureTasks(ScheduledTaskRegistrar taskRegistrar) {
taskRegistrar.setScheduler(taskScheduler());
taskRegistrar.addTriggerTask(
new Runnable() {
public void run() {
myTask().work();
}
},
new CustomTrigger()
);
}
@Bean(destroyMethod="shutdown")
public Executor taskScheduler() {
return Executors.newScheduledThreadPool(42);
}
@Bean
public MyTask myTask() {
return new MyTask();
}
}
For reference, the example above can be compared to the following Spring XML configuration:
<beans>
<task:annotation-driven scheduler="taskScheduler"/>
<task:scheduler id="taskScheduler" pool-size="42"/>
<task:scheduled-tasks scheduler="taskScheduler">
<task:scheduled ref="myTask" method="work" fixed-rate="1000"/>
</task:scheduled-tasks>
<bean id="myTask" class="com.foo.MyTask"/>
</beans>
The examples are equivalent save that in XML a fixed-rate period is used
instead of a custom Trigger implementation; this is because the
task: namespace scheduled cannot easily expose such support. This is
but one demonstration how the code-based approach allows for maximum configurability
through direct access to actual componentry.Scheduled,
SchedulingConfiguration,
SchedulingConfigurer,
ScheduledTaskRegistrar,
Trigger,
ScheduledAnnotationBeanPostProcessor