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// FREEBIE
238 lines
7.1 KiB
Markdown
238 lines
7.1 KiB
Markdown
# JobManager
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An Android library that facilitates scheduling persistent jobs which are executed when their
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prerequisites have been met. Similar to Path's android-priority-queue.
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## The JobManager Way
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Android apps often need to perform blocking operations. A messaging app might need to make REST
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API calls over a network, send SMS messages, download attachments, and interact with a database.
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The standard Android way to do these things are with Services, AsyncTasks, or a dedicated Thread.
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However, some of an app's operations might need to wait until certain dependencies are available
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(such as a network connection), and some of the operations might need to be durable (complete even if the
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app restarts before they have a chance to run). The standard Android way can result in
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a lot of retry logic, timers for monitoring dependencies, and one-off code for making operations
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durable.
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By contrast, the JobManager way allows operations to be broken up into Jobs. A Job represents a
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unit of work to be done, the prerequisites that need to be met (such as network access) before the
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work can execute, and the characteristics of the job (such as durable persistence).
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Applications construct a `JobManager` at initialization time:
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```
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public class ApplicationContext extends Application {
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private JobManager jobManager;
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@Override
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public void onCreate() {
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initializeJobManager();
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}
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private void initializeJobManager() {
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this.jobManager = JobManager.newBuilder(this)
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.withName("SampleJobManager")
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.withConsumerThreads(5)
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.build();
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}
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...
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}
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```
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This constructs a new `JobManager` with 5 consumer threads dedicated to executing Jobs. A
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Job looks like this:
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```
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public class SampleJob extends Job {
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public SampleJob() {
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super(JobParameters.newBuilder().create());
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}
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@Override
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public onAdded() {
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// Called after the Job has been added to the queue.
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}
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@Override
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public void onRun() {
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// Here's where we execute our work.
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Log.w("SampleJob", "Hello, world!");
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}
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@Override
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public void onCanceled() {
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// This would be called if the job had failed.
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}
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@Override
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public boolean onShouldRetry(Exception exception) {
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// Called if onRun() had thrown an exception to determine whether
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// onRun() should be called again.
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return false;
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}
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}
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```
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A Job is scheduled simply by adding it to the JobManager:
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```
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this.jobManager.add(new SampleJob());
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```
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## Persistence
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To create durable Jobs, the JobManager needs to be given an interface responsible for serializing
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and deserializing Job objects. A `JavaJobSerializer` is included with JobManager that uses Java
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Serialization, but you can specify your own serializer if you wish:
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```
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public class ApplicationContext extends Application {
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private JobManager jobManager;
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@Override
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public void onCreate() {
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initializeJobManager();
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}
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private void initializeJobManager() {
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this.jobManager = JobManager.newBuilder(this)
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.withName("SampleJobManager")
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.withConsumerThreads(5)
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.withJobSerializer(new JavaJobSerializer())
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.build();
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}
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...
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}
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```
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The Job simply needs to declare itself as durable when constructed:
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```
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public class SampleJob extends Job {
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public SampleJob() {
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super(JobParameters.newBuilder()
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.withPersistence()
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.create());
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}
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...
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```
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Persistent jobs that are enqueued will be serialized to disk to ensure that they run even if
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the App restarts first. A Job's onAdded() method is called after the commit to disk is complete.
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## Requirements
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A Job might have certain requirements that need to be met before it can run. A requirement is
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represented by the `Requirement` interface. Each `Requirement` must also have a corresponding
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`RequirementProvider` that is registered with the JobManager.
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A `Requirement` tells you whether it is present when queried, while a `RequirementProvider`
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broadcasts to a listener when a Requirement's status might have changed. `Requirement` is attached
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to Job, while `RequirementProvider` is attached to JobManager.
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One common `Requirement` a `Job` might depend on is the presence of network connectivity.
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A `NetworkRequirement` is bundled with JobManager:
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```
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public class ApplicationContext extends Application {
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private JobManager jobManager;
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@Override
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public void onCreate() {
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initializeJobManager();
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}
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private void initializeJobManager() {
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this.jobManager = JobManager.newBuilder(this)
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.withName("SampleJobManager")
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.withConsumerThreads(5)
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.withJobSerializer(new JavaJobSerializer())
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.withRequirementProviders(new NetworkRequirementProvider(this))
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.build();
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}
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...
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}
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```
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The Job declares itself as having a `Requirement` when constructed:
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```
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public class SampleJob extends Job {
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public SampleJob(Context context) {
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super(JobParameters.newBuilder()
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.withPersistence()
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.withRequirement(new NetworkRequirement(context))
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.create());
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}
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...
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```
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## Dependency Injection
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It is possible that Jobs (and Requirements) might require dependency injection. A simple example
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is `Context`, which many Jobs might require, but can't be persisted to disk for durable Jobs. Or
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maybe Jobs require more complex DI through libraries such as Dagger.
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JobManager has an extremely primitive DI mechanism strictly for injecting `Context` objects into
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Jobs and Requirements after they're deserialized, and includes support for plugging in more complex
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DI systems such as Dagger.
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The JobManager `Context` injection works by having your `Job` and/or `Requirement` implement the
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`ContextDependent` interface. `Job`s and `Requirement`s implementing that interface will get a
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`setContext(Context context)` call immediately after the persistent `Job` or `Requirement` is
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deserialized.
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To plugin a more complex DI mechanism, simply pass an instance of the `DependencyInjector` interface
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to the `JobManager`:
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```
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public class ApplicationContext extends Application implements DependencyInjector {
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private JobManager jobManager;
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@Override
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public void onCreate() {
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initializeJobManager();
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}
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private void initializeJobManager() {
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this.jobManager = JobManager.newBuilder(this)
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.withName("SampleJobManager")
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.withConsumerThreads(5)
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.withJobSerializer(new JavaJobSerializer())
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.withRequirementProviders(new NetworkRequirementProvider(this))
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.withDependencyInjector(this)
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.build();
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}
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@Override
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public void injectDependencies(Object object) {
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// And here we do our DI magic.
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}
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...
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}
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```
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`injectDependencies(Object object)` will be called for a `Job` before the job's `onAdded()` method
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is called, or after a persistent job is deserialized. |