Version 3.0.5
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Preface
1. About the documentation
The Spring Cloud Task reference guide is available in html and pdf, epub . The latest copy is available at docs.spring.io/spring-cloud-task/docs/current-SNAPSHOT/reference/html/.
Copies of this document may be made for your own use and for distribution to others, provided that you do not charge any fee for such copies and further provided that each copy contains this Copyright Notice, whether distributed in print or electronically.
2. Getting help
Having trouble with Spring Cloud Task? We would like to help!
-
Ask a question. We monitor stackoverflow.com for questions tagged with
spring-cloud-task
. -
Report bugs with Spring Cloud Task at github.com/spring-cloud/spring-cloud-task/issues.
All of Spring Cloud Task is open source, including the documentation. If you find a problem with the docs or if you just want to improve them, please get involved. |
3. First Steps
If you are just getting started with Spring Cloud Task or with 'Spring' in general, we suggesting reading the Getting started chapter.
To get started from scratch, read the following sections:
To follow the tutorial, read
Developing Your First Spring Cloud Task Application
To run your example, read
Running the Example
Getting started
If you are just getting started with Spring Cloud Task, you should read this section. Here, we answer the basic “what?”, “how?”, and “why?” questions. We start with a gentle introduction to Spring Cloud Task. We then build a Spring Cloud Task application, discussing some core principles as we go.
4. Introducing Spring Cloud Task
Spring Cloud Task makes it easy to create short-lived microservices. It provides capabilities that let short-lived JVM processes be executed on demand in a production environment.
5. System Requirements
You need to have Java installed (Java 17 or better). To build, you need to have Maven installed as well.
5.1. Database Requirements
Spring Cloud Task uses a relational database to store the results of an executed task. While you can begin developing a task without a database (the status of the task is logged as part of the task repository’s updates), for production environments, you want to use a supported database. Spring Cloud Task currently supports the following databases:
-
DB2
-
H2
-
HSQLDB
-
MySql
-
Oracle
-
Postgres
-
SqlServer
6. Developing Your First Spring Cloud Task Application
A good place to start is with a simple “Hello, World!” application, so we create the Spring Cloud Task equivalent to highlight the features of the framework. Most IDEs have good support for Apache Maven, so we use it as the build tool for this project.
The spring.io web site contains many “Getting Started ”
guides that use Spring Boot. If you need to solve a specific problem, check there first.
You can shortcut the following steps by going to the
Spring Initializr and creating a new project. Doing so
automatically generates a new project structure so that you can start coding right away.
We recommend experimenting with the Spring Initializr to become familiar with it.
|
6.1. Creating the Spring Task Project using Spring Initializr
Now we can create and test an application that prints Hello, World!
to the console.
To do so:
-
Visit the Spring Initialzr site.
-
Create a new Maven project with a Group name of
io.spring.demo
and an Artifact name ofhelloworld
. -
In the Dependencies text box, type
task
and then select theCloud Task
dependency. -
In the Dependencies text box, type
jdbc
and then select theJDBC
dependency. -
In the Dependencies text box, type
h2
and then select theH2
. (or your favorite database) -
Click the Generate Project button
-
-
Unzip the helloworld.zip file and import the project into your favorite IDE.
6.2. Writing the Code
To finish our application, we need to update the generated HelloworldApplication
with the following contents so that it launches a Task.
package io.spring.Helloworld;
@SpringBootApplication
@EnableTask
public class HelloworldApplication {
@Bean
public ApplicationRunner applicationRunner() {
return new HelloWorldApplicationRunner();
}
public static void main(String[] args) {
SpringApplication.run(HelloworldApplication.class, args);
}
public static class HelloWorldApplicationRunner implements ApplicationRunner {
@Override
public void run(ApplicationArguments args) throws Exception {
System.out.println("Hello, World!");
}
}
}
While it may seem small, quite a bit is going on. For more about Spring Boot specifics, see the Spring Boot reference documentation.
Now we can open the application.properties
file in src/main/resources
.
We need to configure two properties in application.properties
:
-
application.name
: To set the application name (which is translated to the task name) -
logging.level
: To set the logging for Spring Cloud Task toDEBUG
in order to get a view of what is going on.
The following example shows how to do both:
logging.level.org.springframework.cloud.task=DEBUG
spring.application.name=helloWorld
6.2.1. Task Auto Configuration
When including Spring Cloud Task Starter dependency, Task auto configures all beans to bootstrap it’s functionality.
Part of this configuration registers the TaskRepository
and the infrastructure for its use.
In our demo, the TaskRepository
uses an embedded H2 database to record the results
of a task. This H2 embedded database is not a practical solution for a production environment, since
the H2 DB goes away once the task ends. However, for a quick getting-started
experience, we can use this in our example as well as echoing to the logs what is being updated
in that repository. In the Configuration section (later in this
documentation), we cover how to customize the configuration of the pieces provided by
Spring Cloud Task.
When our sample application runs, Spring Boot launches our HelloWorldCommandLineRunner
and outputs our “Hello, World!” message to standard out. The TaskLifecycleListener
records the start of the task and the end of the task in the repository.
6.2.2. The main method
The main method serves as the entry point to any java application. Our main method delegates to Spring Boot’s SpringApplication class.
6.2.3. The ApplicationRunner
Spring includes many ways to bootstrap an application’s logic. Spring Boot provides
a convenient method of doing so in an organized manner through its *Runner
interfaces
(CommandLineRunner
or ApplicationRunner
). A well behaved task can bootstrap any
logic by using one of these two runners.
The lifecycle of a task is considered from before the *Runner#run
methods are executed
to once they are all complete. Spring Boot lets an application use multiple
*Runner
implementations, as does Spring Cloud Task.
Any processing bootstrapped from mechanisms other than a CommandLineRunner or
ApplicationRunner (by using InitializingBean#afterPropertiesSet for example) is not
recorded by Spring Cloud Task.
|
6.3. Running the Example
At this point, our application should work. Since this application is Spring Boot-based,
we can run it from the command line by using $ mvn spring-boot:run
from the root
of our application, as shown (with its output) in the following example:
$ mvn clean spring-boot:run
....... . . .
....... . . . (Maven log output here)
....... . . .
. ____ _ __ _ _
/\\ / ___'_ __ _ _(_)_ __ __ _ \ \ \ \
( ( )\___ | '_ | '_| | '_ \/ _` | \ \ \ \
\\/ ___)| |_)| | | | | || (_| | ) ) ) )
' |____| .__|_| |_|_| |_\__, | / / / /
=========|_|==============|___/=/_/_/_/
:: Spring Boot :: (v2.0.3.RELEASE)
2018-07-23 17:44:34.426 INFO 1978 --- [ main] i.s.d.helloworld.HelloworldApplication : Starting HelloworldApplication on Glenns-MBP-2.attlocal.net with PID 1978 (/Users/glennrenfro/project/helloworld/target/classes started by glennrenfro in /Users/glennrenfro/project/helloworld)
2018-07-23 17:44:34.430 INFO 1978 --- [ main] i.s.d.helloworld.HelloworldApplication : No active profile set, falling back to default profiles: default
2018-07-23 17:44:34.472 INFO 1978 --- [ main] s.c.a.AnnotationConfigApplicationContext : Refreshing org.springframework.context.annotation.AnnotationConfigApplicationContext@1d24f32d: startup date [Mon Jul 23 17:44:34 EDT 2018]; root of context hierarchy
2018-07-23 17:44:35.280 INFO 1978 --- [ main] com.zaxxer.hikari.HikariDataSource : HikariPool-1 - Starting...
2018-07-23 17:44:35.410 INFO 1978 --- [ main] com.zaxxer.hikari.HikariDataSource : HikariPool-1 - Start completed.
2018-07-23 17:44:35.419 DEBUG 1978 --- [ main] o.s.c.t.c.SimpleTaskConfiguration : Using org.springframework.cloud.task.configuration.DefaultTaskConfigurer TaskConfigurer
2018-07-23 17:44:35.420 DEBUG 1978 --- [ main] o.s.c.t.c.DefaultTaskConfigurer : No EntityManager was found, using DataSourceTransactionManager
2018-07-23 17:44:35.522 DEBUG 1978 --- [ main] o.s.c.t.r.s.TaskRepositoryInitializer : Initializing task schema for h2 database
2018-07-23 17:44:35.525 INFO 1978 --- [ main] o.s.jdbc.datasource.init.ScriptUtils : Executing SQL script from class path resource [org/springframework/cloud/task/schema-h2.sql]
2018-07-23 17:44:35.558 INFO 1978 --- [ main] o.s.jdbc.datasource.init.ScriptUtils : Executed SQL script from class path resource [org/springframework/cloud/task/schema-h2.sql] in 33 ms.
2018-07-23 17:44:35.728 INFO 1978 --- [ main] o.s.j.e.a.AnnotationMBeanExporter : Registering beans for JMX exposure on startup
2018-07-23 17:44:35.730 INFO 1978 --- [ main] o.s.j.e.a.AnnotationMBeanExporter : Bean with name 'dataSource' has been autodetected for JMX exposure
2018-07-23 17:44:35.733 INFO 1978 --- [ main] o.s.j.e.a.AnnotationMBeanExporter : Located MBean 'dataSource': registering with JMX server as MBean [com.zaxxer.hikari:name=dataSource,type=HikariDataSource]
2018-07-23 17:44:35.738 INFO 1978 --- [ main] o.s.c.support.DefaultLifecycleProcessor : Starting beans in phase 0
2018-07-23 17:44:35.762 DEBUG 1978 --- [ main] o.s.c.t.r.support.SimpleTaskRepository : Creating: TaskExecution{executionId=0, parentExecutionId=null, exitCode=null, taskName='application', startTime=Mon Jul 23 17:44:35 EDT 2018, endTime=null, exitMessage='null', externalExecutionId='null', errorMessage='null', arguments=[]}
2018-07-23 17:44:35.772 INFO 1978 --- [ main] i.s.d.helloworld.HelloworldApplication : Started HelloworldApplication in 1.625 seconds (JVM running for 4.764)
Hello, World!
2018-07-23 17:44:35.782 DEBUG 1978 --- [ main] o.s.c.t.r.support.SimpleTaskRepository : Updating: TaskExecution with executionId=1 with the following {exitCode=0, endTime=Mon Jul 23 17:44:35 EDT 2018, exitMessage='null', errorMessage='null'}
The preceding output has three lines that of interest to us here:
-
SimpleTaskRepository
logged the creation of the entry in theTaskRepository
. -
The execution of our
CommandLineRunner
, demonstrated by the “Hello, World!” output. -
SimpleTaskRepository
logs the completion of the task in theTaskRepository
.
A simple task application can be found in the samples module of the Spring Cloud Task Project here. |
Features
This section goes into more detail about Spring Cloud Task, including how to use it, how to configure it, and the appropriate extension points.
7. The lifecycle of a Spring Cloud Task
In most cases, the modern cloud environment is designed around the execution of processes that are not expected to end. If they do end, they are typically restarted. While most platforms do have some way to run a process that is not restarted when it ends, the results of that run are typically not maintained in a consumable way. Spring Cloud Task offers the ability to execute short-lived processes in an environment and record the results. Doing so allows for a microservices architecture around short-lived processes as well as longer running services through the integration of tasks by messages.
While this functionality is useful in a cloud environment, the same issues can arise in a traditional deployment model as well. When running Spring Boot applications with a scheduler such as cron, it can be useful to be able to monitor the results of the application after its completion.
Spring Cloud Task takes the approach that a Spring Boot application can have a start and an end and still be successful. Batch applications are one example of how processes that are expected to end (and that are often short-lived) can be helpful.
Spring Cloud Task records the lifecycle events of a given task. Most long-running processes, typified by most web applications, do not save their lifecycle events. The tasks at the heart of Spring Cloud Task do.
The lifecycle consists of a single task execution. This is a physical execution of a Spring Boot application configured to be a task (that is, it has the Sprint Cloud Task dependencies).
At the beginning of a task, before any CommandLineRunner
or ApplicationRunner
implementations have been run, an entry in the TaskRepository
that records the start
event is created. This event is triggered through SmartLifecycle#start
being triggered
by the Spring Framework. This indicates to the system that all beans are ready for use and
comes before running any of the CommandLineRunner
or ApplicationRunner
implementations
provided by Spring Boot.
The recording of a task only occurs upon the successful bootstrapping of an
ApplicationContext . If the context fails to bootstrap at all, the task’s run is not
recorded.
|
Upon completion of all of the *Runner#run
calls from Spring Boot or the failure of an
ApplicationContext
(indicated by an ApplicationFailedEvent
), the task execution is
updated in the repository with the results.
If the application requires the ApplicationContext to be closed at the
completion of a task (all *Runner#run methods have been called and the task
repository has been updated), set the property spring.cloud.task.closecontextEnabled
to true.
|
7.1. The TaskExecution
The information stored in the TaskRepository
is modeled in the TaskExecution
class and
consists of the following information:
Field | Description |
---|---|
|
The unique ID for the task’s run. |
|
The exit code generated from an |
|
The name for the task, as determined by the configured |
|
The time the task was started, as indicated by the |
|
The time the task was completed, as indicated by the |
|
Any information available at the time of exit. This can programmatically be set by a
|
|
If an exception is the cause of the end of the task (as indicated by an
|
|
A |
7.2. Mapping Exit Codes
When a task completes, it tries to return an exit code to the OS. If we take a look at our original example, we can see that we are not controlling that aspect of our application. So, if an exception is thrown, the JVM returns a code that may or may not be of any use to you in debugging.
Consequently, Spring Boot provides an interface, ExitCodeExceptionMapper
, that lets you
map uncaught exceptions to exit codes. Doing so lets you indicate, at the level of exit
codes, what went wrong. Also, by mapping exit codes in this manner, Spring Cloud Task
records the returned exit code.
If the task terminates with a SIG-INT or a SIG-TERM, the exit code is zero unless otherwise specified within the code.
While the task is running, the exit code is stored as a null in the repository. Once the task completes, the appropriate exit code is stored based on the guidelines described earlier in this section. |
8. Configuration
Spring Cloud Task provides a ready-to-use configuration, as defined in the
DefaultTaskConfigurer
and SimpleTaskConfiguration
classes. This section walks through
the defaults and how to customize Spring Cloud Task for your needs.
8.1. DataSource
Spring Cloud Task uses a datasource for storing the results of task executions. By
default, we provide an in-memory instance of H2 to provide a simple method of
bootstrapping development. However, in a production environment, you probably want to
configure your own DataSource
.
If your application uses only a single DataSource
and that serves as both your business
schema and the task repository, all you need to do is provide any DataSource
(the
easiest way to do so is through Spring Boot’s configuration conventions). This
DataSource
is automatically used by Spring Cloud Task for the repository.
If your application uses more than one DataSource
, you need to configure the task
repository with the appropriate DataSource
. This customization can be done through an
implementation of TaskConfigurer
.
8.2. Table Prefix
One modifiable property of TaskRepository
is the table prefix for the task tables. By
default, they are all prefaced with TASK_
. TASK_EXECUTION
and TASK_EXECUTION_PARAMS
are two examples. However, there are potential reasons to modify this prefix. If the
schema name needs to be prepended to the table names or if more than one set of task
tables is needed within the same schema, you must change the table prefix. You can do so
by setting the spring.cloud.task.tablePrefix
to the prefix you need, as follows:
spring.cloud.task.tablePrefix=yourPrefix
By using the spring.cloud.task.tablePrefix
, a user assumes the responsibility to
create the task tables that meet both the criteria for the task table schema but
with modifications that are required for a user’s business needs.
You can utilize the Spring Cloud Task Schema DDL as a guide when creating your own Task DDL as seen
here.
8.3. Enable/Disable table initialization
In cases where you are creating the task tables and do not wish for Spring Cloud Task to
create them at task startup, set the spring.cloud.task.initialize-enabled
property to
false
, as follows:
spring.cloud.task.initialize-enabled=false
It defaults to true
.
The property spring.cloud.task.initialize.enable has been deprecated.
|
8.4. Externally Generated Task ID
In some cases, you may want to allow for the time difference between when a task is
requested and when the infrastructure actually launches it. Spring Cloud Task lets you
create a TaskExecution
when the task is requested. Then pass the execution ID of the
generated TaskExecution
to the task so that it can update the TaskExecution
through
the task’s lifecycle.
A TaskExecution
can be created by calling the createTaskExecution
method on an
implementation of the TaskRepository
that references the datastore that holds
the TaskExecution
objects.
In order to configure your Task to use a generated TaskExecutionId
, add the
following property:
spring.cloud.task.executionid=yourtaskId
8.5. External Task Id
Spring Cloud Task lets you store an external task ID for each
TaskExecution
. In order to configure your Task to use a generated TaskExecutionId
, add the
following property:
spring.cloud.task.external-execution-id=<externalTaskId>
8.6. Parent Task Id
Spring Cloud Task lets you store a parent task ID for each TaskExecution
. An example of
this would be a task that executes another task or tasks and you want to record which task
launched each of the child tasks. In order to configure your Task to set a parent
TaskExecutionId
add the following property on the child task:
spring.cloud.task.parent-execution-id=<parentExecutionTaskId>
8.7. TaskConfigurer
The TaskConfigurer
is a strategy interface that lets you customize the way components of
Spring Cloud Task are configured. By default, we provide the DefaultTaskConfigurer
that
provides logical defaults: Map
-based in-memory components (useful for development if no
DataSource
is provided) and JDBC based components (useful if there is a DataSource
available).
The TaskConfigurer
lets you configure three main components:
Component | Description | Default (provided by DefaultTaskConfigurer ) |
---|---|---|
|
The implementation of the |
|
|
The implementation of the |
|
|
A transaction manager to be used when running updates for tasks. |
|
You can customize any of the components described in the preceding table by creating a
custom implementation of the TaskConfigurer
interface. Typically, extending the
DefaultTaskConfigurer
(which is provided if a TaskConfigurer
is not found) and
overriding the required getter is sufficient. However, implementing your own from scratch
may be required.
Users should not directly use getter methods from a TaskConfigurer directly
unless they are using it to supply implementations to be exposed as Spring Beans.
|
8.8. Task Execution Listener
TaskExecutionListener
lets you register listeners for specific events that occur during
the task lifecycle. To do so, create a class that implements the
TaskExecutionListener
interface. The class that implements the TaskExecutionListener
interface is notified of the following events:
-
onTaskStartup
: Prior to storing theTaskExecution
into theTaskRepository
. -
onTaskEnd
: Prior to updating theTaskExecution
entry in theTaskRepository
and marking the final state of the task. -
onTaskFailed
: Prior to theonTaskEnd
method being invoked when an unhandled exception is thrown by the task.
Spring Cloud Task also lets you add TaskExecution
Listeners to methods within a bean
by using the following method annotations:
-
@BeforeTask
: Prior to the storing theTaskExecution
into theTaskRepository
-
@AfterTask
: Prior to the updating of theTaskExecution
entry in theTaskRepository
marking the final state of the task. -
@FailedTask
: Prior to the@AfterTask
method being invoked when an unhandled exception is thrown by the task.
The following example shows the three annotations in use:
public class MyBean {
@BeforeTask
public void methodA(TaskExecution taskExecution) {
}
@AfterTask
public void methodB(TaskExecution taskExecution) {
}
@FailedTask
public void methodC(TaskExecution taskExecution, Throwable throwable) {
}
}
Inserting an ApplicationListener earlier in the chain than TaskLifecycleListener exists may cause unexpected effects.
|
8.8.1. Exceptions Thrown by Task Execution Listener
If an exception is thrown by a TaskExecutionListener
event handler, all listener
processing for that event handler stops. For example, if three onTaskStartup
listeners
have started and the first onTaskStartup
event handler throws an exception, the other
two onTaskStartup
methods are not called. However, the other event handlers (onTaskEnd
and onTaskFailed
) for the TaskExecutionListeners
are called.
The exit code returned when a exception is thrown by a TaskExecutionListener
event handler is the exit code that was reported by the
ExitCodeEvent.
If no ExitCodeEvent
is emitted, the Exception thrown is evaluated to see
if it is of type
ExitCodeGenerator.
If so, it returns the exit code from the ExitCodeGenerator
. Otherwise, 1
is returned.
In the case that an exception is thrown in an onTaskStartup
method, the exit code for the application will be 1
.
If an exception is thrown in either a onTaskEnd
or onTaskFailed
method, the exit code for the application will be the one established using the rules enumerated above.
In the case of an exception being thrown in a onTaskStartup , onTaskEnd , or onTaskFailed
you can not override the exit code for the application using ExitCodeExceptionMapper .
|
8.8.2. Exit Messages
You can set the exit message for a task programmatically by using a
TaskExecutionListener
. This is done by setting the TaskExecution’s
exitMessage
,
which then gets passed into the TaskExecutionListener
. The following example shows
a method that is annotated with the @AfterTask
ExecutionListener
:
@AfterTask
public void afterMe(TaskExecution taskExecution) {
taskExecution.setExitMessage("AFTER EXIT MESSAGE");
}
An ExitMessage
can be set at any of the listener events (onTaskStartup
,
onTaskFailed
, and onTaskEnd
). The order of precedence for the three listeners follows:
-
onTaskEnd
-
onTaskFailed
-
onTaskStartup
For example, if you set an exitMessage
for the onTaskStartup
and onTaskFailed
listeners and the task ends without failing, the exitMessage
from the onTaskStartup
is stored in the repository. Otherwise, if a failure occurs, the exitMessage
from
the onTaskFailed
is stored. Also if you set the exitMessage
with an
onTaskEnd
listener, the exitMessage
from the onTaskEnd
supersedes
the exit messages from both the onTaskStartup
and onTaskFailed
.
8.9. Restricting Spring Cloud Task Instances
Spring Cloud Task lets you establish that only one task with a given task name can be run
at a time. To do so, you need to establish the task name and set
spring.cloud.task.single-instance-enabled=true
for each task execution. While the first
task execution is running, any other time you try to run a task with the same
task name and`spring.cloud.task.single-instance-enabled=true`, the
task fails with the following error message: Task with name "application" is already
running.
The default value for spring.cloud.task.single-instance-enabled
is false
. The
following example shows how to set spring.cloud.task.single-instance-enabled
to true
:
spring.cloud.task.single-instance-enabled=true or false
To use this feature, you must add the following Spring Integration dependencies to your application:
<dependency>
<groupId>org.springframework.integration</groupId>
<artifactId>spring-integration-core</artifactId>
</dependency>
<dependency>
<groupId>org.springframework.integration</groupId>
<artifactId>spring-integration-jdbc</artifactId>
</dependency>
The exit code for the application will be 1 if the task fails because this feature is enabled and another task is running with the same task name. |
8.9.1. Single Instance Usage for Spring AOT And Native Compilation
To use Spring Cloud Task’s single-instance feature when creating a natively compiled app, you need to enable the feature at build time.
To do so, add the process-aot execution and set spring.cloud.task.single-step-instance-enabled=true
as a JVM argument, as follows:
<plugin>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-maven-plugin</artifactId>
<executions>
<execution>
<id>process-aot</id>
<goals>
<goal>process-aot</goal>
</goals>
<configuration>
<jvmArguments>
-Dspring.cloud.task.single-instance-enabled=true
</jvmArguments>
</configuration>
</execution>
</executions>
</plugin>
8.10. Enabling Observations for ApplicationRunner and CommandLineRunner
To Enable Task Observations for ApplicationRunner
or CommandLineRunner
set spring.cloud.task.observation.enabled
to true.
An example task application with observations enables using the SimpleMeterRegistry
can be found here.
8.11. Disabling Spring Cloud Task Auto Configuration
In cases where Spring Cloud Task should not be autoconfigured for an implementation, you can disable Task’s auto configuration. This can be done either by adding the following annotation to your Task application:
@EnableAutoConfiguration(exclude={SimpleTaskAutoConfiguration.class})
You may also disable Task auto configuration by setting the spring.cloud.task.autoconfiguration.enabled
property to false
.
8.12. Closing the Context
If the application requires the ApplicationContext
to be closed at the
completion of a task (all *Runner#run
methods have been called and the task
repository has been updated), set the property spring.cloud.task.closecontextEnabled
to true
.
Another case to close the context is when the Task Execution completes however the application does not terminate.
In these cases the context is held open because a thread has been allocated
(for example: if you are using a TaskExecutor). In these cases
set the spring.cloud.task.closecontextEnabled
property to true
when launching your task.
This will close the application’s context once the task is complete.
Thus allowing the application to terminate.
8.13. Enable Task Metrics
Spring Cloud Task integrates with Micrometer and creates observations for the Tasks it executes.
To enable Task Observability integration, you must add spring-boot-starter-actuator
, your preferred registry implementation (if you want to publish metrics), and micrometer-tracing (if you want to publish tracing data) to your task application.
An example maven set of dependencies to enable task observability and metrics using Influx would be:
<dependency>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-starter-actuator</artifactId>
</dependency>
<dependency>
<groupId>io.micrometer</groupId>
<artifactId>micrometer-registry-influx</artifactId>
<scope>runtime</scope>
</dependency>
8.14. Spring Task and Spring Cloud Task Properties
The term task
is frequently used word in the industry. In one such example Spring Boot offers the spring.task
while Spring Cloud Task offers the spring.cloud.task
properties.
This has caused some confusion in the past that these two groups of properties are directly related. However, they represent 2 different set of features offered in the Spring ecosystem.
-
spring.task
refers to the properties that configure theThreadPoolTaskScheduler
. -
spring.cloud.task
refers to the properties that configure features of Spring Cloud Task.
Batch
This section goes into more detail about Spring Cloud Task’s integration with Spring Batch. Tracking the association between a job execution and the task in which it was executed as well as remote partitioning through Spring Cloud Deployer are covered in this section.
9. Associating a Job Execution to the Task in which It Was Executed
Spring Boot provides facilities for the execution of batch jobs within an über-jar. Spring Boot’s support of this functionality lets a developer execute multiple batch jobs within that execution. Spring Cloud Task provides the ability to associate the execution of a job (a job execution) with a task’s execution so that one can be traced back to the other.
Spring Cloud Task achieves this functionality by using the TaskBatchExecutionListener
.
By default,
this listener is auto configured in any context that has both a Spring Batch Job
configured (by having a bean of type Job
defined in the context) and the
spring-cloud-task-batch
jar on the classpath. The listener is injected into all jobs
that meet those conditions.
9.1. Overriding the TaskBatchExecutionListener
To prevent the listener from being injected into any batch jobs within the current context, you can disable the autoconfiguration by using standard Spring Boot mechanisms.
To only have the listener injected into particular jobs within the context, override the
batchTaskExecutionListenerBeanPostProcessor
and provide a list of job bean IDs, as shown
in the following example:
public static TaskBatchExecutionListenerBeanPostProcessor batchTaskExecutionListenerBeanPostProcessor() {
TaskBatchExecutionListenerBeanPostProcessor postProcessor =
new TaskBatchExecutionListenerBeanPostProcessor();
postProcessor.setJobNames(Arrays.asList(new String[] {"job1", "job2"}));
return postProcessor;
}
You can find a sample batch application in the samples module of the Spring Cloud Task Project, here. |
10. Remote Partitioning
Spring Cloud Deployer provides facilities for launching Spring Boot-based applications on
most cloud infrastructures. The DeployerPartitionHandler
and
DeployerStepExecutionHandler
delegate the launching of worker step executions to Spring
Cloud Deployer.
To configure the DeployerStepExecutionHandler
, you must provide a Resource
representing the Spring Boot über-jar to be executed, a TaskLauncherHandler
, and a
JobExplorer
. You can configure any environment properties as well as the max number of
workers to be executing at once, the interval to poll for the results (defaults to 10
seconds), and a timeout (defaults to -1 or no timeout). The following example shows how
configuring this PartitionHandler
might look:
@Bean
public PartitionHandler partitionHandler(TaskLauncher taskLauncher,
JobExplorer jobExplorer) throws Exception {
MavenProperties mavenProperties = new MavenProperties();
mavenProperties.setRemoteRepositories(new HashMap<>(Collections.singletonMap("springRepo",
new MavenProperties.RemoteRepository(repository))));
Resource resource =
MavenResource.parse(String.format("%s:%s:%s",
"io.spring.cloud",
"partitioned-batch-job",
"1.1.0.RELEASE"), mavenProperties);
DeployerPartitionHandler partitionHandler =
new DeployerPartitionHandler(taskLauncher, jobExplorer, resource, "workerStep");
List<String> commandLineArgs = new ArrayList<>(3);
commandLineArgs.add("--spring.profiles.active=worker");
commandLineArgs.add("--spring.cloud.task.initialize.enable=false");
commandLineArgs.add("--spring.batch.initializer.enabled=false");
partitionHandler.setCommandLineArgsProvider(
new PassThroughCommandLineArgsProvider(commandLineArgs));
partitionHandler.setEnvironmentVariablesProvider(new NoOpEnvironmentVariablesProvider());
partitionHandler.setMaxWorkers(2);
partitionHandler.setApplicationName("PartitionedBatchJobTask");
return partitionHandler;
}
When passing environment variables to partitions, each partition may be on a different machine with different environment settings. Consequently, you should pass only those environment variables that are required. |
Notice in the example above that we have set the maximum number of workers to 2. Setting the maximum of workers establishes the maximum number of partitions that should be running at one time.
The Resource
to be executed is expected to be a Spring Boot über-jar with a
DeployerStepExecutionHandler
configured as a CommandLineRunner
in the current context.
The repository enumerated in the preceding example should be the remote repository in
which the über-jar is located. Both the manager and worker are expected to have visibility
into the same data store being used as the job repository and task repository. Once the
underlying infrastructure has bootstrapped the Spring Boot jar and Spring Boot has
launched the DeployerStepExecutionHandler
, the step handler executes the requested
Step
. The following example shows how to configure the DeployerStepExecutionHandler
:
@Bean
public DeployerStepExecutionHandler stepExecutionHandler(JobExplorer jobExplorer) {
DeployerStepExecutionHandler handler =
new DeployerStepExecutionHandler(this.context, jobExplorer, this.jobRepository);
return handler;
}
You can find a sample remote partition application in the samples module of the Spring Cloud Task project, here. |
10.1. Asynchronously launch remote batch partitions
By default batch partitions are launched sequentially. However, in some cases this may affect performance as each launch will block until the resource (For example: provisioning a pod in Kubernetes) is provisioned.
In these cases you can provide a ThreadPoolTaskExecutor
to the DeployerPartitionHandler
. This will launch the remote batch partitions based on the configuration of the ThreadPoolTaskExecutor
.
For example:
@Bean
public ThreadPoolTaskExecutor threadPoolTaskExecutor() {
ThreadPoolTaskExecutor executor = new ThreadPoolTaskExecutor();
executor.setCorePoolSize(4);
executor.setThreadNamePrefix("default_task_executor_thread");
executor.setWaitForTasksToCompleteOnShutdown(true);
executor.initialize();
return executor;
}
@Bean
public PartitionHandler partitionHandler(TaskLauncher taskLauncher, JobExplorer jobExplorer,
TaskRepository taskRepository, ThreadPoolTaskExecutor executor) throws Exception {
Resource resource = this.resourceLoader
.getResource("maven://io.spring.cloud:partitioned-batch-job:2.2.0.BUILD-SNAPSHOT");
DeployerPartitionHandler partitionHandler =
new DeployerPartitionHandler(taskLauncher, jobExplorer, resource,
"workerStep", taskRepository, executor);
...
}
We need to close the context since the use of ThreadPoolTaskExecutor leaves a thread active thus the app will not terminate. To close the application appropriately, we will need to set spring.cloud.task.closecontextEnabled property to true .
|
10.2. Notes on Developing a Batch-partitioned application for the Kubernetes Platform
-
When deploying partitioned apps on the Kubernetes platform, you must use the following dependency for the Spring Cloud Kubernetes Deployer:
<dependency> <groupId>org.springframework.cloud</groupId> <artifactId>spring-cloud-starter-deployer-kubernetes</artifactId> </dependency>
-
The application name for the task application and its partitions need to follow the following regex pattern:
[a-z0-9]([-a-z0-9]*[a-z0-9])
. Otherwise, an exception is thrown.
11. Batch Informational Messages
Spring Cloud Task provides the ability for batch jobs to emit informational messages. The “Spring Batch Events” section covers this feature in detail.
12. Batch Job Exit Codes
As discussed earlier, Spring Cloud Task
applications support the ability to record the exit code of a task execution. However, in
cases where you run a Spring Batch Job within a task, regardless of how the Batch Job
Execution completes, the result of the task is always zero when using the default
Batch/Boot behavior. Keep in mind that a task is a boot application and that the exit code
returned from the task is the same as a boot application.
To override this behavior and allow the task to return an exit code other than zero when a
batch job returns an
BatchStatus
of FAILED
, set spring.cloud.task.batch.fail-on-job-failure
to true
. Then the exit code
can be 1 (the default) or be based on the
specified
ExitCodeGenerator
)
This functionality uses a new ApplicationRunner
that replaces the one provided by Spring
Boot. By default, it is configured with the same order. However, if you want to customize
the order in which the ApplicationRunner
is run, you can set its order by setting the
spring.cloud.task.batch.applicationRunnerOrder
property. To have your task return the
exit code based on the result of the batch job execution, you need to write your own
CommandLineRunner
.
Single Step Batch Job Starter
This section goes into how to develop a Spring Batch Job
with a single Step
by using the
starter included in Spring Cloud Task. This starter lets you use configuration
to define an ItemReader
, an ItemWriter
, or a full single-step Spring Batch Job
.
For more about Spring Batch and its capabilities, see the
Spring Batch documentation.
To obtain the starter for Maven, add the following to your build:
<dependency>
<groupId>org.springframework.cloud</groupId>
<artifactId>spring-cloud-starter-single-step-batch-job</artifactId>
<version>2.3.0</version>
</dependency>
To obtain the starter for Gradle, add the following to your build:
compile "org.springframework.cloud:spring-cloud-starter-single-step-batch-job:2.3.0"
13. Defining a Job
You can use the starter to define as little as an ItemReader
or an ItemWriter
or as much as a full Job
.
In this section, we define which properties are required to be defined to configure a
Job
.
13.1. Properties
To begin, the starter provides a set of properties that let you configure the basics of a Job with one Step:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
The name of the job. |
|
|
|
The name of the step. |
|
|
|
The number of items to be processed per transaction. |
With the above properties configured, you have a job with a single, chunk-based step.
This chunk-based step reads, processes, and writes Map<String, Object>
instances as the
items. However, the step does not yet do anything. You need to configure an ItemReader
, an
optional ItemProcessor
, and an ItemWriter
to give it something to do. To configure one
of these, you can either use properties and configure one of the options that has provided
autoconfiguration or you can configure your own with the standard Spring configuration
mechanisms.
If you configure your own, the input and output types must match the others in the step.
The ItemReader implementations and ItemWriter implementations in this starter all use
a Map<String, Object> as the input and the output item.
|
14. Autoconfiguration for ItemReader Implementations
This starter provides autoconfiguration for four different ItemReader
implementations:
AmqpItemReader
, FlatFileItemReader
, JdbcCursorItemReader
, and KafkaItemReader
.
In this section, we outline how to configure each of these by using the provided
autoconfiguration.
14.1. AmqpItemReader
You can read from a queue or topic with AMQP by using the AmqpItemReader
. The
autoconfiguration for this ItemReader
implementation is dependent upon two sets of
configuration. The first is the configuration of an AmqpTemplate
. You can either
configure this yourself or use the autoconfiguration provided by Spring Boot. See the
Spring Boot AMQP documentation.
Once you have configured the AmqpTemplate
, you can enable the batch capabilities to support it
by setting the following properties:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
If |
|
|
|
Indicates if the |
For more information, see the AmqpItemReader
documentation.
14.2. FlatFileItemReader
FlatFileItemReader
lets you read from flat files (such as CSVs
and other file formats). To read from a file, you can provide some components
yourself through normal Spring configuration (LineTokenizer
, RecordSeparatorPolicy
,
FieldSetMapper
, LineMapper
, or SkippedLinesCallback
). You can also use the
following properties to configure the reader:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
Determines if the state should be saved for restarts. |
|
|
|
Name used to provide unique keys in the |
|
|
|
Maximum number of items to be read from the file. |
|
|
0 |
Number of items that have already been read. Used on restarts. |
|
|
empty List |
A list of Strings that indicate commented lines (lines to be ignored) in the file. |
|
|
|
The resource to be read. |
|
|
|
If set to |
|
|
|
Encoding to be used when reading the file. |
|
|
0 |
Indicates the number of lines to skip at the start of a file. |
|
|
|
Indicates whether the file is a delimited file (CSV and other formats). Only one of this property or |
|
|
|
If reading a delimited file, indicates the delimiter to parse on. |
|
|
|
Used to determine the character used to quote values. |
|
|
empty list |
A list of indices to determine which fields in a record to include in the item. |
|
|
|
Indicates if a file’s records are parsed by column numbers. Only one of this property or |
|
|
empty list |
List of column ranges by which to parse a fixed width record. See the Range documentation. |
|
|
|
List of names for each field parsed from a record. These names are the keys in the |
|
|
|
If set to |
See the FlatFileItemReader
documentation.
14.3. JdbcCursorItemReader
The JdbcCursorItemReader
runs a query against a relational database and iterates over
the resulting cursor (ResultSet
) to provide the resulting items. This autoconfiguration
lets you provide a PreparedStatementSetter
, a RowMapper
, or both. You
can also use the following properties to configure a JdbcCursorItemReader
:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
Determines whether the state should be saved for restarts. |
|
|
|
Name used to provide unique keys in the |
|
|
|
Maximum number of items to be read from the file. |
|
|
0 |
Number of items that have already been read. Used on restarts. |
|
|
A hint to the driver to indicate how many records to retrieve per call to the database system. For best performance, you usually want to set it to match the chunk size. |
|
|
|
Maximum number of items to read from the database. |
|
|
|
Number of milliseconds for the query to timeout. |
|
|
|
|
Determines whether the reader should ignore SQL warnings when processing. |
|
|
|
Indicates whether the cursor’s position should be verified after each read to verify that the |
|
|
|
Indicates whether the driver supports absolute positioning of a cursor. |
|
|
|
Indicates whether the connection is shared with other processing (and is therefore part of a transaction). |
|
|
|
SQL query from which to read. |
You can also specify JDBC DataSource specifically for the reader by using the following properties:
.JdbcCursorItemReader
Properties
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
Determines whether |
|
|
|
JDBC URL of the database. |
|
|
|
Login username of the database. |
|
|
|
Login password of the database. |
|
|
|
Fully qualified name of the JDBC driver. |
The default DataSource will be used by the JDBCCursorItemReader if the jdbccursoritemreader_datasource is not specified.
|
See the JdbcCursorItemReader
documentation.
14.4. KafkaItemReader
Ingesting a partition of data from a Kafka topic is useful and exactly what the
KafkaItemReader
can do. To configure a KafkaItemReader
, two pieces
of configuration are required. First, configuring Kafka with Spring Boot’s Kafka
autoconfiguration is required (see the
Spring Boot Kafka documentation).
Once you have configured the Kafka properties from Spring Boot, you can configure the KafkaItemReader
itself by setting the following properties:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
Name used to provide unique keys in the |
|
|
|
Name of the topic from which to read. |
|
|
empty list |
List of partition indices from which to read. |
|
|
30 |
Timeout for the |
|
|
|
Determines whether the state should be saved for restarts. |
See the KafkaItemReader
documentation.
14.5. Native Compilation
The advantage of Single Step Batch Processing is that it lets you dynamically select which reader and writer beans to use at runtime when you use the JVM. However, when you use native compilation, you must determine the reader and writer at build time instead of runtime. The following example does so:
<plugin>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-maven-plugin</artifactId>
<executions>
<execution>
<id>process-aot</id>
<goals>
<goal>process-aot</goal>
</goals>
<configuration>
<jvmArguments>
-Dspring.batch.job.flatfileitemreader.name=fooReader
-Dspring.batch.job.flatfileitemwriter.name=fooWriter
</jvmArguments>
</configuration>
</execution>
</executions>
</plugin>
15. ItemProcessor Configuration
The single-step batch job autoconfiguration accepts an ItemProcessor
if one
is available within the ApplicationContext
. If one is found of the correct type
(ItemProcessor<Map<String, Object>, Map<String, Object>>
), it is autowired
into the step.
16. Autoconfiguration for ItemWriter implementations
This starter provides autoconfiguration for ItemWriter
implementations that
match the supported ItemReader
implementations: AmqpItemWriter
,
FlatFileItemWriter
, JdbcItemWriter
, and KafkaItemWriter
. This section
covers how to use autoconfiguration to configure a supported ItemWriter
.
16.1. AmqpItemWriter
To write to a RabbitMQ queue, you need two sets of configuration. First, you need an
AmqpTemplate
. The easiest way to get this is by using Spring Boot’s
RabbitMQ autoconfiguration. See the Spring Boot AMQP documentation.
Once you have configured the AmqpTemplate
, you can configure the AmqpItemWriter
by setting the
following properties:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
If |
|
|
|
Indicates whether |
16.2. FlatFileItemWriter
To write a file as the output of the step, you can configure FlatFileItemWriter
.
Autoconfiguration accepts components that have been explicitly configured (such as LineAggregator
,
FieldExtractor
, FlatFileHeaderCallback
, or a FlatFileFooterCallback
) and
components that have been configured by setting the following properties specified:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
The resource to be read. |
|
|
|
Indicates whether the output file is a delimited file. If |
|
|
|
Indicates whether the output file a formatted file. If |
|
|
|
The format used to generate the output for a formatted file. The formatting is performed by using |
|
|
|
The |
|
|
0 |
Max length of the record. If 0, the size is unbounded. |
|
|
0 |
The minimum record length. |
|
|
|
The |
|
|
|
Encoding to use when writing the file. |
|
|
|
Indicates whether a file should be force-synced to the disk on flush. |
|
|
|
List of names for each field parsed from a record. These names are the keys in the |
|
|
|
Indicates whether a file should be appended to if the output file is found. |
|
|
|
What |
|
|
|
Name used to provide unique keys in the |
|
|
|
Determines whether the state should be saved for restarts. |
|
|
|
If set to |
|
|
|
If set to |
|
|
|
Indicates whether the reader is a transactional queue (indicating that the items read are returned to the queue upon a failure). |
See the FlatFileItemWriter
documentation.
16.3. JdbcBatchItemWriter
To write the output of a step to a relational database, this starter provides the ability
to autoconfigure a JdbcBatchItemWriter
. The autoconfiguration lets you provide your
own ItemPreparedStatementSetter
or ItemSqlParameterSourceProvider
and
configuration options by setting the following properties:
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
Name used to provide unique keys in the |
|
|
|
The SQL used to insert each item. |
|
|
|
Whether to verify that every insert results in the update of at least one record. |
You can also specify JDBC DataSource specifically for the writer by using the following properties:
.JdbcBatchItemWriter
Properties
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
Determines whether |
|
|
|
JDBC URL of the database. |
|
|
|
Login username of the database. |
|
|
|
Login password of the database. |
|
|
|
Fully qualified name of the JDBC driver. |
The default DataSource will be used by the JdbcBatchItemWriter if the jdbcbatchitemwriter_datasource is not specified.
|
See the JdbcBatchItemWriter
documentation.
16.4. KafkaItemWriter
To write step output to a Kafka topic, you need KafkaItemWriter
. This starter
provides autoconfiguration for a KafkaItemWriter
by using facilities from two places.
The first is Spring Boot’s Kafka autoconfiguration. (See the Spring Boot Kafka documentation.)
Second, this starter lets you configure two properties on the writer.
Property | Type | Default Value | Description |
---|---|---|---|
|
|
|
The Kafka topic to which to write. |
|
|
|
Whether the items being passed to the writer are all to be sent as delete events to the topic. |
For more about the configuration options for the KafkaItemWriter
, see the KafkaItemWiter
documentation.
16.5. Spring AOT
When using Spring AOT with Single Step Batch Starter you must set the reader and
writer name properties at compile time (unless you create a bean(s) for the reader and or writer).
To do this you must include the name of the reader and writer that you wish to use as
and argument or environment variable in the boot maven plugin or gradle plugin. For example if
you wish to enable the FlatFileItemReader
and FlatFileItemWriter
in Maven it would look like:
<plugin>
<groupId>org.springframework.boot</groupId>
<artifactId>spring-boot-maven-plugin</artifactId>
<executions>
<execution>
<id>process-aot</id>
<goals>
<goal>process-aot</goal>
</goals>
</execution>
</executions>
<configuration>
<arguments>
<argument>--spring.batch.job.flatfileitemreader.name=foobar</argument>
<argument>--spring.batch.job.flatfileitemwriter.name=fooWriter</argument>
</arguments>
</configuration>
</plugin>
Spring Cloud Stream Integration
A task by itself can be useful, but integration of a task into a larger ecosystem lets it be useful for more complex processing and orchestration. This section covers the integration options for Spring Cloud Task with Spring Cloud Stream.
17. Launching a Task from a Spring Cloud Stream
You can launch tasks from a stream. To do so, create a sink that listens for a message
that contains a TaskLaunchRequest
as its payload. The TaskLaunchRequest
contains:
-
uri
: To the task artifact that is to be executed. -
applicationName
: The name that is associated with the task. If no applicationName is set, theTaskLaunchRequest
generates a task name comprised of the following:Task-<UUID>
. -
commandLineArguments
: A list containing the command line arguments for the task. -
environmentProperties
: A map containing the environment variables to be used by the task. -
deploymentProperties
: A map containing the properties that are used by the deployer to deploy the task.
If the payload is of a different type, the sink throws an exception. |
For example, a stream can be created that has a processor that takes in data from an
HTTP source and creates a GenericMessage
that contains the TaskLaunchRequest
and sends
the message to its output channel. The task sink would then receive the message from its
input channel and then launch the task.
To create a taskSink, you need only create a Spring Boot application that includes the
EnableTaskLauncher
annotation, as shown in the following example:
@SpringBootApplication
@EnableTaskLauncher
public class TaskSinkApplication {
public static void main(String[] args) {
SpringApplication.run(TaskSinkApplication.class, args);
}
}
The samples
module of the Spring Cloud Task project contains a sample Sink and Processor. To install
these samples into your local maven repository, run a maven build from the
spring-cloud-task-samples
directory with the skipInstall
property set to false
, as
shown in the following example:
mvn clean install
The maven.remoteRepositories.springRepo.url property must be set to the location
of the remote repository in which the über-jar is located. If not set, there is no remote
repository, so it relies upon the local repository only.
|
17.1. Spring Cloud Data Flow
To create a stream in Spring Cloud Data Flow, you must first register the Task Sink Application we created. In the following example, we are registering the Processor and Sink sample applications by using the Spring Cloud Data Flow shell:
app register --name taskSink --type sink --uri maven://io.spring.cloud:tasksink:<version>
app register --name taskProcessor --type processor --uri maven:io.spring.cloud:taskprocessor:<version>
The following example shows how to create a stream from the Spring Cloud Data Flow shell:
stream create foo --definition "http --server.port=9000|taskProcessor|taskSink" --deploy
18. Spring Cloud Task Events
Spring Cloud Task provides the ability to emit events through a Spring Cloud Stream
channel when the task is run through a Spring Cloud Stream channel. A task listener is
used to publish the TaskExecution
on a message channel named task-events
. This feature
is autowired into any task that has spring-cloud-stream
, spring-cloud-stream-<binder>
,
and a defined task on its classpath.
To disable the event emitting listener, set the spring.cloud.task.events.enabled
property to false .
|
With the appropriate classpath defined, the following task emits the TaskExecution
as an
event on the task-events
channel (at both the start and the end of the task):
@SpringBootApplication
public class TaskEventsApplication {
public static void main(String[] args) {
SpringApplication.run(TaskEventsApplication.class, args);
}
@Configuration
public static class TaskConfiguration {
@Bean
public ApplicationRunner applicationRunner() {
return new ApplicationRunner() {
@Override
public void run(ApplicationArguments args) {
System.out.println("The ApplicationRunner was executed");
}
};
}
}
}
A binder implementation is also required to be on the classpath. |
A sample task event application can be found in the samples module of the Spring Cloud Task Project, here. |
18.1. Disabling Specific Task Events
To disable task events, you can set the spring.cloud.task.events.enabled
property to
false
.
19. Spring Batch Events
When executing a Spring Batch job through a task, Spring Cloud Task can be configured to emit informational messages based on the Spring Batch listeners available in Spring Batch. Specifically, the following Spring Batch listeners are autoconfigured into each batch job and emit messages on the associated Spring Cloud Stream channels when run through Spring Cloud Task:
-
JobExecutionListener
listens forjob-execution-events
-
StepExecutionListener
listens forstep-execution-events
-
ChunkListener
listens forchunk-events
-
ItemReadListener
listens foritem-read-events
-
ItemProcessListener
listens foritem-process-events
-
ItemWriteListener
listens foritem-write-events
-
SkipListener
listens forskip-events
These listeners are autoconfigured into any AbstractJob
when the appropriate
beans (a Job
and a TaskLifecycleListener
) exist in the context. Configuration to
listen to these events is handled the same way binding to any other Spring
Cloud Stream channel is done. Our task (the one running the batch job) serves as a
Source
, with the listening applications serving as either a Processor
or a Sink
.
An example could be to have an application listening to the job-execution-events
channel
for the start and stop of a job. To configure the listening application, you would
configure the input to be job-execution-events
as follows:
spring.cloud.stream.bindings.input.destination=job-execution-events
A binder implementation is also required to be on the classpath. |
A sample batch event application can be found in the samples module of the Spring Cloud Task Project, here. |
19.1. Sending Batch Events to Different Channels
One of the options that Spring Cloud Task offers for batch events is the ability to alter
the channel to which a specific listener can emit its messages. To do so, use the
following configuration:
spring.cloud.stream.bindings.<the channel>.destination=<new destination>
. For example,
if StepExecutionListener
needs to emit its messages to another channel called
my-step-execution-events
instead of the default step-execution-events
, you can add the
following configuration:
spring.cloud.task.batch.events.step-execution-events-binding-name=my-step-execution-events
19.2. Disabling Batch Events
To disable the listener functionality for all batch events, use the following configuration:
spring.cloud.task.batch.events.enabled=false
To disable a specific batch event, use the following configuration:
spring.cloud.task.batch.events.<batch event listener>.enabled=false
:
The following listing shows individual listeners that you can disable:
spring.cloud.task.batch.events.job-execution.enabled=false
spring.cloud.task.batch.events.step-execution.enabled=false
spring.cloud.task.batch.events.chunk.enabled=false
spring.cloud.task.batch.events.item-read.enabled=false
spring.cloud.task.batch.events.item-process.enabled=false
spring.cloud.task.batch.events.item-write.enabled=false
spring.cloud.task.batch.events.skip.enabled=false
19.3. Emit Order for Batch Events
By default, batch events have Ordered.LOWEST_PRECEDENCE
. To change this value (for
example, to 5 ), use the following configuration:
spring.cloud.task.batch.events.job-execution-order=5
spring.cloud.task.batch.events.step-execution-order=5
spring.cloud.task.batch.events.chunk-order=5
spring.cloud.task.batch.events.item-read-order=5
spring.cloud.task.batch.events.item-process-order=5
spring.cloud.task.batch.events.item-write-order=5
spring.cloud.task.batch.events.skip-order=5
Appendices
20. Task Repository Schema
This appendix provides an ERD for the database schema used in the task repository.
20.1. Table Information
Stores the task execution information.
Column Name | Required | Type | Field Length | Notes |
---|---|---|---|---|
TASK_EXECUTION_ID |
TRUE |
BIGINT |
X |
Spring Cloud Task Framework at app startup establishes the next available id as obtained from the |
START_TIME |
FALSE |
DATETIME(6) |
X |
Spring Cloud Task Framework at app startup establishes the value. |
END_TIME |
FALSE |
DATETIME(6) |
X |
Spring Cloud Task Framework at app exit establishes the value. |
TASK_NAME |
FALSE |
VARCHAR |
100 |
Spring Cloud Task Framework at app startup will set this to "Application" unless user establish the name using the |
EXIT_CODE |
FALSE |
INTEGER |
X |
Follows Spring Boot defaults unless overridden by the user as discussed here. |
EXIT_MESSAGE |
FALSE |
VARCHAR |
2500 |
User Defined as discussed here. |
ERROR_MESSAGE |
FALSE |
VARCHAR |
2500 |
Spring Cloud Task Framework at app exit establishes the value. |
LAST_UPDATED |
TRUE |
TIMESTAMP |
X |
Spring Cloud Task Framework at app startup establishes the value. Or if the record is created outside of task then the value must be populated at record creation time. |
EXTERNAL_EXECUTION_ID |
FALSE |
VARCHAR |
250 |
If the |
PARENT_TASK_EXECUTION_ID |
FALSE |
BIGINT |
X |
If the |
Stores the parameters used for a task execution
Column Name | Required | Type | Field Length |
---|---|---|---|
TASK_EXECUTION_ID |
TRUE |
BIGINT |
X |
TASK_PARAM |
FALSE |
VARCHAR |
2500 |
Used to link the task execution to the batch execution.
Column Name | Required | Type | Field Length |
---|---|---|---|
TASK_EXECUTION_ID |
TRUE |
BIGINT |
X |
JOB_EXECUTION_ID |
TRUE |
BIGINT |
X |
Used for the single-instance-enabled
feature discussed here.
Column Name | Required | Type | Field Length | Notes |
---|---|---|---|---|
LOCK_KEY |
TRUE |
CHAR |
36 |
UUID for the this lock |
REGION |
TRUE |
VARCHAR |
100 |
User can establish a group of locks using this field. |
CLIENT_ID |
TRUE |
CHAR |
36 |
The task execution id that contains the name of the app to lock. |
CREATED_DATE |
TRUE |
DATETIME |
X |
The date that the entry was created |
The DDL for setting up tables for each database type can be found here. |
20.2. SQL Server
By default Spring Cloud Task uses a sequence table for determining the TASK_EXECUTION_ID
for the TASK_EXECUTION
table.
However, when launching multiple tasks simultaneously while using SQL Server, this can cause a deadlock to occur on the TASK_SEQ
table.
The resolution is to drop the TASK_EXECUTION_SEQ
table and create a sequence using the same name. For example:
DROP TABLE TASK_SEQ;
CREATE SEQUENCE [DBO].[TASK_SEQ] AS BIGINT
START WITH 1
INCREMENT BY 1;
Set the START WITH to a higher value than your current execution id.
|
21. Building This Documentation
This project uses Maven to generate this documentation. To generate it for yourself,
run the following command: $ mvn clean install -DskipTests -P docs
.
22. Observability metadata
22.1. Observability - Metrics
Below you can find a list of all metrics declared by this project.
22.1.1. Task Active
Metrics created around a task execution.
Metric name spring.cloud.task
(defined by convention class org.springframework.cloud.task.listener.DefaultTaskExecutionObservationConvention
). Type timer
.
Metric name spring.cloud.task.active
(defined by convention class org.springframework.cloud.task.listener.DefaultTaskExecutionObservationConvention
). Type long task timer
.
KeyValues that are added after starting the Observation might be missing from the *.active metrics. |
Micrometer internally uses nanoseconds for the baseunit. However, each backend determines the actual baseunit. (i.e. Prometheus uses seconds)
|
Fully qualified name of the enclosing class org.springframework.cloud.task.listener.TaskExecutionObservation
.
All tags must be prefixed with spring.cloud.task prefix!
|
Name |
Description |
|
App id for CF cloud. |
|
App name for CF cloud. |
|
App version for CF cloud. |
|
Instance index for CF cloud. |
|
Organization Name for CF cloud. |
|
Space id for CF cloud. |
|
Space name for CF cloud. |
|
Task execution id. |
|
Task exit code. |
|
External execution id for task. |
|
Task name measurement. |
|
Task parent execution id. |
|
task status. Can be either success or failure. |
22.1.2. Task Runner Observation
Observation created when a task runner is executed.
Metric name spring.cloud.task.runner
(defined by convention class org.springframework.cloud.task.configuration.observation.DefaultTaskObservationConvention
). Type timer
.
Metric name spring.cloud.task.runner.active
(defined by convention class org.springframework.cloud.task.configuration.observation.DefaultTaskObservationConvention
). Type long task timer
.
KeyValues that are added after starting the Observation might be missing from the *.active metrics. |
Micrometer internally uses nanoseconds for the baseunit. However, each backend determines the actual baseunit. (i.e. Prometheus uses seconds)
|
Fully qualified name of the enclosing class org.springframework.cloud.task.configuration.observation.TaskDocumentedObservation
.
All tags must be prefixed with spring.cloud.task prefix!
|
Name |
Description |
|
Name of the bean that was executed by Spring Cloud Task. |
22.2. Observability - Spans
Below you can find a list of all spans declared by this project.
22.2.1. Task Active Span
Metrics created around a task execution.
Span name spring.cloud.task
(defined by convention class org.springframework.cloud.task.listener.DefaultTaskExecutionObservationConvention
).
Fully qualified name of the enclosing class org.springframework.cloud.task.listener.TaskExecutionObservation
.
All tags must be prefixed with spring.cloud.task prefix!
|
Name |
Description |
|
App id for CF cloud. |
|
App name for CF cloud. |
|
App version for CF cloud. |
|
Instance index for CF cloud. |
|
Organization Name for CF cloud. |
|
Space id for CF cloud. |
|
Space name for CF cloud. |
|
Task execution id. |
|
Task exit code. |
|
External execution id for task. |
|
Task name measurement. |
|
Task parent execution id. |
|
task status. Can be either success or failure. |
22.2.2. Task Runner Observation Span
Observation created when a task runner is executed.
Span name spring.cloud.task.runner
(defined by convention class org.springframework.cloud.task.configuration.observation.DefaultTaskObservationConvention
).
Fully qualified name of the enclosing class org.springframework.cloud.task.configuration.observation.TaskDocumentedObservation
.
All tags must be prefixed with spring.cloud.task prefix!
|
Name |
Description |
|
Name of the bean that was executed by Spring Cloud Task. |