AutoDispose is an RxJava 2 tool for automatically binding the execution of RxJava 2 streams to a provided scope via disposal/cancellation.
Often (especially in mobile applications), Rx subscriptions need to stop in response to some event (for instance, when Activity#onStop() executes in an Android app). In order to support this common scenario in RxJava 2, we built AutoDispose.
The idea is simple: construct your chain like any other, and then at subscription you simply drop in the relevant factory call + method for that type as a converter. In everyday use, it usually looks like this:
myObservable
.doStuff()
.as(autoDisposable(this)) // The magic
.subscribe(s -> ...);
By doing this, you will automatically unsubscribe from myObservable
as indicated by your
scope - this helps prevent many classes of errors when an observable emits and item, but the actions
taken in the subscription are no longer valid. For instance, if a network request comes back after a
UI has already been torn down, the UI can't be updated - this pattern prevents this type of bug.
The main entry point is via static factory autoDisposable()
methods in the AutoDispose
class.
There are two overloads: Completable
and ScopeProvider
. They return an
AutoDisposeConverter
object that implements all the RxJava Converter
interfaces for use with
the as()
operator in RxJava types.
The Completable
semantic is modeled after the takeUntil()
operator, which accepts an Observable
whose first emission is used as a notification to signal completion. This is logically the
behavior of a Single
, so we choose to make that explicit. Since the type doesn't matter, we
simplify this further to just be a Completable
, where the scope-end emission is just a completion event.
All scopes in AutoDispose eventually resolve to a Completable
that emits the end-of-scope notification
in onComplete
. onError
will pass through to the underlying subscription.
public interface ScopeProvider {
CompletableSource requestScope() throws Exception;
}
ScopeProvider
is an abstraction that allows objects to expose and control and provide their own scopes.
This is particularly useful for objects with simple scopes ("stop when I stop") or very custom state
that requires custom handling.
Note that Exceptions can be thrown in this, and will be routed through onError()
. If the thrown exception
is an instance of OutsideScopeException
, it will be routed through any OutsideScopeHandler
s (more below)
first, and sent through onError()
if not handled.
Modeled after RxJava's plugins, this allows you to customize the behavior of AutoDispose.
When a scope is bound to outside of its allowable boundary, AutoDispose
will send an error event with an
OutsideScopeException
to downstream consumers. If you want to customize this behavior, you can use
AutoDisposePlugins#setOutsideScopeHandler
to intercept these exceptions and rethrow something
else or nothing at all.
Example
AutoDisposePlugins.setOutsideScopeHandler(t -> {
// Swallow the exception, or rethrow it, or throw your own!
})
A good use case of this is, say, just silently disposing/logging observers outside of lifecycle exceptions in production but crashing on debug.
The supported mechanism to throw this is in ScopeProvider#requestScope()
implementations.
If you have your own handling of exceptions in scope boundary events, you can optionally set
AutoDisposePlugins#setFillInOutsideScopeExceptionStacktraces
to false
. This will result in
AutoDispose not
filling in stacktraces for exceptions, for a potential minor performance boost.
Similar to AutoDisposePlugins
, this allows you to customize the behavior of AutoDispose in Android environments.
This plugin allows for supplying a custom BooleanSupplier
that can customize how main thread
checks work. The conventional use case of this is Android JUnit tests, where the Looper
class is
not stubbed in the mock android.jar and fails explosively when touched.
Another potential use of this at runtime to customize checks for more fine-grained main thread checks behavior.
Example
AutoDisposeAndroidPlugins.setOnCheckMainThread(() -> {
return true; // Use whatever heuristics you prefer.
})
Under the hood, AutoDispose decorates RxJava's real observer with a custom AutoDisposing observer.
This custom observer leverages the scope to create a disposable, auto-disposing observer that acts
as a lambda observer (pass-through) unless the underlying scope CompletableSource
emits onComplete
. Both
scope emission and upstream termination result in immediate disposable of both the underlying scope
subscription and upstream disposable.
These custom AutoDisposing
observers are considered public read-only API, and can be found under the
observers
package. They also support retrieval of the underlying observer via delegateObserver()
methods. Read-only API means that the public signatures will follow semantic versioning, but we may
add new methods in the future (which would break compilation if you make custom implementations!).
To read this information, you can use RxJava's onSubscribe
hooks in RxJavaPlugins
to watch for
instances of these observers.
Flowable
, ParallelFlowable
, Observable
, Maybe
, Single
, and Completable
are all supported. Implementation is solely
based on their Observer
types, so conceivably any type that uses those for subscription should work.
There are also a number of extension artifacts available, detailed below.
public interface LifecycleScopeProvider<E> extends ScopeProvider {
Observable<E> lifecycle();
Function<E, E> correspondingEvents();
E peekLifecycle();
// Inherited from ScopeProvider
CompletableSource requestScope();
}
A common use case for this is objects that have implicit lifecycles, such as Android's Activity
,
Fragment
, and View
classes. Internally at subscription-time, AutoDispose
will resolve
a CompletableSource
representation of the target end
event in the lifecycle, and exposes an API to dictate what
corresponding events are for the current lifecycle state (e.g. ATTACH
-> DETACH
). This also allows
you to enforce lifecycle boundary requirements, and by default will error if the lifecycle has either
not started yet or has already ended.
LifecycleScopeProvider
is a special case targeted at binding to things with lifecycles. Its API is
as follows:
lifecycle()
- returns anObservable
of lifecycle events. This should be backed by aBehaviorSubject
or something similar (BehaviorRelay
, etc).correspondingEvents()
- a mapping of events to corresponding ones, i.e. Attach -> Detach.peekLifecycle()
- returns the current lifecycle state of the object.
In requestScope()
, the implementation expects to these pieces to construct a CompletableSource
representation
of the proper end scope, while also doing precondition checks for lifecycle boundaries. If a
lifecycle has not started, it will send you to onError
with a LifecycleNotStartedException
. If
the lifecycle as ended, it is recommended to throw a LifecycleEndedException
in your
correspondingEvents()
mapping, but it is up to the user.
To simplify implementations, there's an included LifecycleScopes
utility class with factories
for generating CompletableSource
representations from LifecycleScopeProvider
instances.
There are three artifacts with this support:
autodispose-lifecycle
: Contains the coreLifecycleScopeProvider
andLifecycleScopes
APIs. Also has a convenience test helper.autodispose-lifecycle-jdk8
: Contains a simpleDefaultLifecycleScopeProvider
with a Java 8default
method implementation ofrequestScope()
.autodispose-lifecycle-ktx
: Contains convenience kotlin extension functions and aKotlinLifecycleScopeProvider
that has a default implementation forrequestScope()
(similar to the jdk8 artifact, but for Kotlin).
There are three artifacts with extra support for Android:
autodispose-android
has aViewScopeProvider
for use with AndroidView
classes.autodispose-android-archcomponents
has aAndroidLifecycleScopeProvider
for use withLifecycleOwner
andLifecycle
implementations.autodispose-android-archcomponents-test
has aTestLifecycleOwner
for use in testing.
For each artifact, there is a corresponding kotlin extensions artifact with it. Example:
autodispose-android
-> autodispose-android-ktx
.
Kotlin extension artifacts are available for almost every artifact by adding -ktx
to the ID like
above.
As of 0.4.0 there is an RxLifecycle interop module under autodispose-rxlifecycle
. This is for interop
with RxLifecycle's LifecycleProvider
interfaces.
Each factory returns a subscribe proxies upon application that just proxy to real subscribe calls under the hood to "AutoDisposing" implementations of the types. These types decorate the actual observer at subscribe-time to achieve autodispose behavior. The types are not exposed directly because autodisposing has ordering requirements; specifically, it has to be done at the end of a chain to properly wrap all the upstream behavior. Lint could catch this too, but we have seen no use cases for disposing upstream (which can cause a lot of unexpected behavior). Thus, we optimize for the common case, and the API is designed to prevent ordering issues while still being a drop-in one-liner.
Lifecycle management with RxJava and Android is nothing new, so why yet another tool?
Two common patterns for binding execution in RxJava that we used prior to this were as follows:
CompositeSubscription
field that all subscriptions had to be manually added to.RxLifecycle
, which works viacompose()
to resolve the lifecycle end event and ultimately transform the given observable totakeUntil()
that event is emitted.
Both implementations are elegant and work well, but came with caveats that we sought to revisit and solve in AutoDispose.
CompositeSubscription
requires manual capture of the return value of subscribe
calls, and
gets tedious to reason about with regards to binding subscription until different events.
RxLifecycle
solves the caveats of CompositeSubscription
use by working in a dead-simple API and handling
resolution of corresponding events. It works great for Observable
types, but due to the nature of
how takeUntil()
works, we found that Single
and Completable
usage was risky to use (particularly in a
large team with varying levels of RxJava experience) considering lifecycle interruption would result
in a downstream CancellationException
every time. It's the contract of those types, but induced a lot of
ceremony for what would otherwise likely be our most commonly used type (Single
). Even with Observable
,
we were still burned occasionally by the completion event still coming through to an unsuspecting engineer.
Another caveat we often ran into (and later aggressively linted against) was that the compose()
call had
ordering implications, and needed to be as close to the subscribe()
call as possible to properly wrap upstream.
If binding to views, there were also threading requirements on the observable chain in order to work properly.
At the end of the day, we wanted true disposal/unsubscription-based behavior, but with RxLifecycle-esque
semantics around scope resolution. RxJava 2's Observer
interfaces provide the perfect mechanism for
this via their onSubscribe()
callbacks. The result is de-risked Single
/Completable
usage, no ordering
concerns, no threading concerns (fingers crossed), and true disposal with no further events of any kind
upon scope end. We're quite happy with it, and hope the community finds it useful as well.
Special thanks go to Dan Lew (creator of RxLifecycle), who helped pioneer this area for RxJava
in android and humored many of the discussions around lifecycle handling over the past couple years
that we've learned from. Much of the internal scope resolution mechanics of AutoDispose
are
inspired by RxLifecycle.
This pattern is sort of possible in RxJava 1, but only on Subscriber
(via onStart()
) and
CompletableObserver
(which matches RxJava 2's API). We are aggressively migrating our internal code
to RxJava 2, and do not plan to try to backport this to RxJava 1.
There is an optional error-prone checker you can use to enforce use of AutoDispose. Integration steps and more details can be found on the wiki
Java:
compile 'com.uber.autodispose:autodispose:x.y.z'
LifecycleScopeProvider:
compile 'com.uber.autodispose:autodispose-lifecycle:x.y.z'
compile 'com.uber.autodispose:autodispose-lifecycle-jdk8:x.y.z'
compile 'com.uber.autodispose:autodispose-lifecycle-ktx:x.y.z'
Android extensions:
compile 'com.uber.autodispose:autodispose-android:x.y.z'
Android Architecture Components extensions:
compile 'com.uber.autodispose:autodispose-android-archcomponents:x.y.z'
Android Architecture Components Test extensions:
compile 'com.uber.autodispose:autodispose-android-archcomponents-test:x.y.z'
RxLifecycle interop:
compile 'com.uber.autodispose:autodispose-rxlifecycle:x.y.z'
Kotlin extensions:
compile 'com.uber.autodispose:autodispose-ktx:x.y.z'
compile 'com.uber.autodispose:autodispose-android-ktx:x.y.z'
autodispose-android-archcomponents-ktx
compile 'com.uber.autodispose:autodispose-android-archcomponents-ktx:x.y.z'
autodispose-android-archcomponents-test-ktx
compile 'com.uber.autodispose:autodispose-android-archcomponents-test-ktx:x.y.z'
Javadocs and KDocs for the most recent release can be found here: https://uber.github.io/AutoDispose/0.x/
Snapshots of the development version are available in Sonatype's snapshots repository.
Copyright (C) 2017 Uber Technologies
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.