497 lines
19 KiB
Plaintext
497 lines
19 KiB
Plaintext
:batch-asciidoc: ./
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:toc: left
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:toclevels: 4
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[[scalability]]
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== Scaling and Parallel Processing
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ifndef::onlyonetoggle[]
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include::toggle.adoc[]
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endif::onlyonetoggle[]
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Many batch processing problems can be solved with single threaded, single process jobs,
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so it is always a good idea to properly check if that meets your needs before thinking
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about more complex implementations. Measure the performance of a realistic job and see if
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the simplest implementation meets your needs first. You can read and write a file of
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several hundred megabytes in well under a minute, even with standard hardware.
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When you are ready to start implementing a job with some parallel processing, Spring
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Batch offers a range of options, which are described in this chapter, although some
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features are covered elsewhere. At a high level, there are two modes of parallel
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processing:
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* Single process, multi-threaded
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* Multi-process
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These break down into categories as well, as follows:
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* Multi-threaded Step (single process)
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* Parallel Steps (single process)
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* Remote Chunking of Step (multi process)
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* Partitioning a Step (single or multi process)
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First, we review the single-process options. Then we review the multi-process options.
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[[multithreadedStep]]
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=== Multi-threaded Step
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The simplest way to start parallel processing is to add a `TaskExecutor` to your Step
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configuration.
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[role="xmlContent"]
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For example, you might add an attribute of the `tasklet`, as shown in the
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following example:
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[source, xml, role="xmlContent"]
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----
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<step id="loading">
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<tasklet task-executor="taskExecutor">...</tasklet>
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</step>
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----
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[role="javaContent"]
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When using java configuration, a `TaskExecutor` can be added to the step
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as shown in the following example:
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.Java Configuration
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[source, java, role="javaContent"]
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----
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@Bean
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public TaskExecutor taskExecutor(){
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return new SimpleAsyncTaskExecutor("spring_batch");
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}
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@Bean
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public Step sampleStep(TaskExecutor taskExecutor) {
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return this.stepBuilderFactory.get("sampleStep")
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.<String, String>chunk(10)
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.reader(itemReader())
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.writer(itemWriter())
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.taskExecutor(taskExecutor)
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.build();
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}
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----
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In this example, the `taskExecutor` is a reference to another bean definition that
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implements the `TaskExecutor` interface.
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https://docs.spring.io/spring/docs/current/javadoc-api/org/springframework/core/task/TaskExecutor.html[`TaskExecutor`]
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is a standard Spring interface, so consult the Spring User Guide for details of available
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implementations. The simplest multi-threaded `TaskExecutor` is a
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`SimpleAsyncTaskExecutor`.
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The result of the above configuration is that the `Step` executes by reading, processing,
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and writing each chunk of items (each commit interval) in a separate thread of execution.
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Note that this means there is no fixed order for the items to be processed, and a chunk
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might contain items that are non-consecutive compared to the single-threaded case. In
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addition to any limits placed by the task executor (such as whether it is backed by a
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thread pool), there is a throttle limit in the tasklet configuration which defaults to 4.
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You may need to increase this to ensure that a thread pool is fully utilized.
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[role="xmlContent"]
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For example you might increase the throttle-limit, as shown in the following example:
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[source, xml, role="xmlContent"]
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----
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<step id="loading"> <tasklet
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task-executor="taskExecutor"
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throttle-limit="20">...</tasklet>
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</step>
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----
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[role="javaContent"]
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When using java configuration, the builders provide access to the throttle limit:
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.Java Configuration
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[source, java, role="javaContent"]
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----
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@Bean
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public Step sampleStep(TaskExecutor taskExecutor) {
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return this.stepBuilderFactory.get("sampleStep")
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.<String, String>chunk(10)
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.reader(itemReader())
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.writer(itemWriter())
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.taskExecutor(taskExecutor)
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.throttleLimit(20)
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.build();
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}
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----
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Note also that there may be limits placed on concurrency by any pooled resources used in
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your step, such as a `DataSource`. Be sure to make the pool in those resources at least
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as large as the desired number of concurrent threads in the step.
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There are some practical limitations of using multi-threaded `Step` implementations for
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some common batch use cases. Many participants in a `Step` (such as readers and writers)
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are stateful. If the state is not segregated by thread, then those components are not
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usable in a multi-threaded `Step`. In particular, most of the off-the-shelf readers and
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writers from Spring Batch are not designed for multi-threaded use. It is, however,
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possible to work with stateless or thread safe readers and writers, and there is a sample
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(called `parallelJob`) in the
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https://github.com/spring-projects/spring-batch/tree/master/spring-batch-samples[Spring
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Batch Samples] that shows the use of a process indicator (see
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<<readersAndWriters.adoc#process-indicator,Preventing State Persistence>>) to keep track
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of items that have been processed in a database input table.
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Spring Batch provides some implementations of `ItemWriter` and `ItemReader`. Usually,
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they say in the Javadoc if they are thread safe or not or what you have to do to avoid
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problems in a concurrent environment. If there is no information in the Javadoc, you can
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check the implementation to see if there is any state. If a reader is not thread safe,
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you can decorate it with the provided `SynchronizedItemStreamReader` or use it in your own
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synchronizing delegator. You can synchronize the call to `read()` and as long as the
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processing and writing is the most expensive part of the chunk, your step may still
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complete much faster than it would in a single threaded configuration.
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[[scalabilityParallelSteps]]
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=== Parallel Steps
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As long as the application logic that needs to be parallelized can be split into distinct
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responsibilities and assigned to individual steps, then it can be parallelized in a
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single process. Parallel Step execution is easy to configure and use.
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[role="xmlContent"]
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For example, executing steps `(step1,step2)` in parallel with `step3` is straightforward,
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as shown in the following example:
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[source, xml, role="xmlContent"]
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----
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<job id="job1">
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<split id="split1" task-executor="taskExecutor" next="step4">
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<flow>
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<step id="step1" parent="s1" next="step2"/>
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<step id="step2" parent="s2"/>
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</flow>
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<flow>
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<step id="step3" parent="s3"/>
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</flow>
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</split>
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<step id="step4" parent="s4"/>
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</job>
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<beans:bean id="taskExecutor" class="org.spr...SimpleAsyncTaskExecutor"/>
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----
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[role="javaContent"]
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When using java configuration, executing steps `(step1,step2)` in parallel with `step3`
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is straightforward, as shown in the following example:
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.Java Configuration
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[source, java, role="javaContent"]
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----
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@Bean
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public Job job() {
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return jobBuilderFactory.get("job")
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.start(splitFlow())
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.next(step4())
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.build() //builds FlowJobBuilder instance
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.build(); //builds Job instance
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}
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@Bean
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public Flow splitFlow() {
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return new FlowBuilder<SimpleFlow>("splitFlow")
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.split(taskExecutor())
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.add(flow1(), flow2())
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.build();
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}
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@Bean
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public Flow flow1() {
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return new FlowBuilder<SimpleFlow>("flow1")
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.start(step1())
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.next(step2())
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.build();
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}
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@Bean
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public Flow flow2() {
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return new FlowBuilder<SimpleFlow>("flow2")
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.start(step3())
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.build();
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}
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@Bean
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public TaskExecutor taskExecutor(){
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return new SimpleAsyncTaskExecutor("spring_batch");
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}
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----
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The configurable task executor is used to specify which `TaskExecutor`
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implementation should be used to execute the individual flows. The default is
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`SyncTaskExecutor`, but an asynchronous `TaskExecutor` is required to run the steps in
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parallel. Note that the job ensures that every flow in the split completes before
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aggregating the exit statuses and transitioning.
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See the section on <<step.adoc#split-flows,Split Flows>> for more detail.
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[[remoteChunking]]
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=== Remote Chunking
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In remote chunking, the `Step` processing is split across multiple processes,
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communicating with each other through some middleware. The following image shows the
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pattern:
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.Remote Chunking
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image::{batch-asciidoc}images/remote-chunking.png[Remote Chunking, scaledwidth="60%"]
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The manager component is a single process, and the workers are multiple remote processes.
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This pattern works best if the manager is not a bottleneck, so the processing must be more
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expensive than the reading of items (as is often the case in practice).
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The manager is an implementation of a Spring Batch `Step` with the `ItemWriter` replaced
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by a generic version that knows how to send chunks of items to the middleware as
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messages. The workers are standard listeners for whatever middleware is being used (for
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example, with JMS, they would be `MesssageListener` implementations), and their role is
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to process the chunks of items using a standard `ItemWriter` or `ItemProcessor` plus
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`ItemWriter`, through the `ChunkProcessor` interface. One of the advantages of using this
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pattern is that the reader, processor, and writer components are off-the-shelf (the same
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as would be used for a local execution of the step). The items are divided up dynamically
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and work is shared through the middleware, so that, if the listeners are all eager
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consumers, then load balancing is automatic.
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The middleware has to be durable, with guaranteed delivery and a single consumer for each
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message. JMS is the obvious candidate, but other options (such as JavaSpaces) exist in
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the grid computing and shared memory product space.
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See the section on
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<<spring-batch-integration.adoc#remote-chunking,Spring Batch Integration - Remote Chunking>>
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for more detail.
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[[partitioning]]
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=== Partitioning
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Spring Batch also provides an SPI for partitioning a `Step` execution and executing it
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remotely. In this case, the remote participants are `Step` instances that could just as
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easily have been configured and used for local processing. The following image shows the
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pattern:
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.Partitioning
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image::{batch-asciidoc}images/partitioning-overview.png[Partitioning Overview, scaledwidth="60%"]
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The `Job` runs on the left-hand side as a sequence of `Step` instances, and one of the
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`Step` instances is labeled as a manager. The workers in this picture are all identical
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instances of a `Step`, which could in fact take the place of the manager, resulting in the
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same outcome for the `Job`. The workers are typically going to be remote services but
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could also be local threads of execution. The messages sent by the manager to the workers
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in this pattern do not need to be durable or have guaranteed delivery. Spring Batch
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metadata in the `JobRepository` ensures that each worker is executed once and only once for
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each `Job` execution.
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The SPI in Spring Batch consists of a special implementation of `Step` (called the
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`PartitionStep`) and two strategy interfaces that need to be implemented for the specific
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environment. The strategy interfaces are `PartitionHandler` and `StepExecutionSplitter`,
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and their role is shown in the following sequence diagram:
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.Partitioning SPI
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image::{batch-asciidoc}images/partitioning-spi.png[Partitioning SPI, scaledwidth="60%"]
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The `Step` on the right in this case is the "`remote`" worker, so, potentially, there are
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many objects and or processes playing this role, and the `PartitionStep` is shown driving
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the execution.
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[role="xmlContent"]
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The following example shows the `PartitionStep` configuration:
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[source, xml, role="xmlContent"]
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----
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<step id="step1.manager">
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<partition step="step1" partitioner="partitioner">
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<handler grid-size="10" task-executor="taskExecutor"/>
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</partition>
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</step>
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----
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[role="javaContent"]
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The following example shows the `PartitionStep` configuration using java configuration:
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.Java Configuration
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[source, java, role="javaContent"]
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----
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@Bean
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public Step step1Manager() {
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return stepBuilderFactory.get("step1.manager")
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.<String, String>partitioner("step1", partitioner())
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.step(step1())
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.gridSize(10)
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.taskExecutor(taskExecutor())
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.build();
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}
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----
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Similar to the multi-threaded step's `throttle-limit` attribute, the `grid-size`
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attribute prevents the task executor from being saturated with requests from a single
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step.
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There is a simple example that can be copied and extended in the unit test suite for
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https://github.com/spring-projects/spring-batch/tree/master/spring-batch-samples/src/main/resources/jobs[Spring
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Batch Samples] (see `Partition*Job.xml` configuration).
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Spring Batch creates step executions for the partitions called "step1:partition0", and so
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on. Many people prefer to call the manager step "step1:manager" for consistency. You can
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use an alias for the step (by specifying the `name` attribute instead of the `id`
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attribute).
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[[partitionHandler]]
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==== PartitionHandler
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The `PartitionHandler` is the component that knows about the fabric of the remoting or
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grid environment. It is able to send `StepExecution` requests to the remote `Step`
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instances, wrapped in some fabric-specific format, like a DTO. It does not have to know
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how to split the input data or how to aggregate the result of multiple `Step` executions.
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Generally speaking, it probably also does not need to know about resilience or failover,
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since those are features of the fabric in many cases. In any case, Spring Batch always
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provides restartability independent of the fabric. A failed `Job` can always be restarted
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and only the failed `Steps` are re-executed.
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The `PartitionHandler` interface can have specialized implementations for a variety of
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fabric types, including simple RMI remoting, EJB remoting, custom web service, JMS, Java
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Spaces, shared memory grids (like Terracotta or Coherence), and grid execution fabrics
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(like GridGain). Spring Batch does not contain implementations for any proprietary grid
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or remoting fabrics.
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Spring Batch does, however, provide a useful implementation of `PartitionHandler` that
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executes `Step` instances locally in separate threads of execution, using the
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`TaskExecutor` strategy from Spring. The implementation is called
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`TaskExecutorPartitionHandler`.
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[role="xmlContent"]
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The `TaskExecutorPartitionHandler` is the default for a step configured with the XML
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namespace shown previously. It can also be configured explicitly, as shown in the
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following example:
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[source, xml, role="xmlContent"]
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----
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<step id="step1.manager">
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<partition step="step1" handler="handler"/>
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</step>
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<bean class="org.spr...TaskExecutorPartitionHandler">
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<property name="taskExecutor" ref="taskExecutor"/>
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<property name="step" ref="step1" />
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<property name="gridSize" value="10" />
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</bean>
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----
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[role="javaContent"]
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The `TaskExecutorPartitionHandler` can be configured explicitly within java configuration,
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as shown in the following example:
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.Java Configuration
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[source, java, role="javaContent"]
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----
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@Bean
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public Step step1Manager() {
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return stepBuilderFactory.get("step1.manager")
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.partitioner("step1", partitioner())
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.partitionHandler(partitionHandler())
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.build();
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}
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@Bean
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public PartitionHandler partitionHandler() {
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TaskExecutorPartitionHandler retVal = new TaskExecutorPartitionHandler();
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retVal.setTaskExecutor(taskExecutor());
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retVal.setStep(step1());
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retVal.setGridSize(10);
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return retVal;
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}
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----
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The `gridSize` attribute determines the number of separate step executions to create, so
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it can be matched to the size of the thread pool in the `TaskExecutor`. Alternatively, it
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can be set to be larger than the number of threads available, which makes the blocks of
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work smaller.
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The `TaskExecutorPartitionHandler` is useful for IO-intensive `Step` instances, such as
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copying large numbers of files or replicating filesystems into content management
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systems. It can also be used for remote execution by providing a `Step` implementation
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that is a proxy for a remote invocation (such as using Spring Remoting).
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[[partitioner]]
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==== Partitioner
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The `Partitioner` has a simpler responsibility: to generate execution contexts as input
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parameters for new step executions only (no need to worry about restarts). It has a
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single method, as shown in the following interface definition:
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[source, java]
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----
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public interface Partitioner {
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Map<String, ExecutionContext> partition(int gridSize);
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}
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----
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The return value from this method associates a unique name for each step execution (the
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`String`) with input parameters in the form of an `ExecutionContext`. The names show up
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later in the Batch metadata as the step name in the partitioned `StepExecutions`. The
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`ExecutionContext` is just a bag of name-value pairs, so it might contain a range of
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primary keys, line numbers, or the location of an input file. The remote `Step` then
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normally binds to the context input using `#{...}` placeholders (late binding in step
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scope), as illustrated in the next section.
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The names of the step executions (the keys in the `Map` returned by `Partitioner`) need
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to be unique amongst the step executions of a `Job` but do not have any other specific
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requirements. The easiest way to do this (and to make the names meaningful for users) is
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to use a prefix+suffix naming convention, where the prefix is the name of the step that
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is being executed (which itself is unique in the `Job`), and the suffix is just a
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counter. There is a `SimplePartitioner` in the framework that uses this convention.
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An optional interface called `PartitionNameProvider` can be used to provide the partition
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names separately from the partitions themselves. If a `Partitioner` implements this
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interface, then, on a restart, only the names are queried. If partitioning is expensive,
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this can be a useful optimization. The names provided by the `PartitionNameProvider` must
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match those provided by the `Partitioner`.
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[[bindingInputDataToSteps]]
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==== Binding Input Data to Steps
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It is very efficient for the steps that are executed by the `PartitionHandler` to have
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identical configuration and for their input parameters to be bound at runtime from the
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`ExecutionContext`. This is easy to do with the StepScope feature of Spring Batch
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(covered in more detail in the section on <<step.adoc#late-binding,Late Binding>>). For
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example, if the `Partitioner` creates `ExecutionContext` instances with an attribute key
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called `fileName`, pointing to a different file (or directory) for each step invocation,
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the `Partitioner` output might resemble the content of the following table:
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.Example step execution name to execution context provided by `Partitioner` targeting directory processing
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|===============
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|__Step Execution Name (key)__|__ExecutionContext (value)__
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|filecopy:partition0|fileName=/home/data/one
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|filecopy:partition1|fileName=/home/data/two
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|filecopy:partition2|fileName=/home/data/three
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|===============
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Then the file name can be bound to a step using late binding to the execution context, as
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shown in the following example:
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|
|
.XML Configuration
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[source, xml, role="xmlContent"]
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----
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<bean id="itemReader" scope="step"
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class="org.spr...MultiResourceItemReader">
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<property name="resources" value="#{stepExecutionContext[fileName]}/*"/>
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</bean>
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----
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.Java Configuration
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[source, java, role="javaContent"]
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----
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@Bean
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public MultiResourceItemReader itemReader(
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@Value("#{stepExecutionContext['fileName']}/*") Resource [] resources) {
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return new MultiResourceItemReaderBuilder<String>()
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.delegate(fileReader())
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.name("itemReader")
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.resources(resources)
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.build();
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}
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----
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