Why you should use RxJava in Android a short introduction to RxJava
In most Android applications, you are reacting to user interactions (clicks, swipes and etc.) while doing something else in the background (networking).
Orchestrating all of this is a hard thing and could quickly turn into an unmanageable code mess.
For example, it isn't trivial to send a request to a database over network and after it completes start fetching user messages and preferences at the same time, and after all of that is complete show a welcome message.
This is a case where RxJava (ReactiveX) excels - orchestrating multiple actions that happen due to certain events in the system.
Using RxJava you will be able to forget callbacks and hellish global state management.
Why?
Let's get back to the example:
send a request to a database over network and after that completes start fetching his messages and his preferences at the same time, and after all of that is complete - show a welcome message.
If this is dissected, there will be these main parts that all happen in the background:
- Fetch a user from database
- Fetch user settings and user's messages at the same time
- Combine results from both responses in to one
To do the same in Java SE and Android, you are going to need to use:
- 3-4 different AsyncTasks
- Create a Semaphore, that will wait until both of the requests (settings and messages) will complete
- Object-level fields to store the results
It can be already seen, that this involves management of state and playing with some locking mechanisms in Java.
All of that can be avoided with RxJava (see examples below) - everything can be expressed as a flow in one place based on a functional paradigm (see this).
Quick start in Android studio
To get libraries that you are most likely to need in your project, in your build.gradle insert these lines:
compile 'io.reactivex:rxjava:1.1.0'
compile 'io.reactivex:rxjava-async-util:0.21.0'
compile 'io.reactivex:rxandroid:1.1.0'
compile 'com.jakewharton.rxbinding:rxbinding:0.3.0'
compile 'com.trello:rxlifecycle:0.4.0'
compile 'com.trello:rxlifecycle-components:0.4.0'
These will include:
- RxJava - a core ReactiveX library for Java.
- RxAndroid - RxJava extensions for Android that will help you with Android threading and Loopers.
- RxBinding - this will provide bindings between RxJava and Android UI elements likes Buttons and TextViews
- RxJavaAsyncUtil - helps you to glue code between Callables and Futures.
Example
Let's start with an example:
Observable.just("1", "2")
.subscribe(new Action1<String>() {
@Override
public void call(String s) {
System.out.println(s);
}
});
Here we created an Observable that will be emit two items 1 and 2.
We subscribed to the observable and once receive an item, it will be printed out.
Some details
Observable is something that you can subscribe to to listen for the items that the observable will emit. They can be constructed in many different ways. However, they usually don't begin emitting items until you subscribe to them.
After you subscribe to an observable, you get a Subscription. The subscription will listen for the items from observable until it marks itself as completed or, otherwise, it will continue indefinitely (a very rare case).
Furthermore, all of these actions are going to be executed on the main thread.
Expanded example
Observable.from(fetchHttpNetworkContentFuture())
.subscribeOn(Schedulers.io())
.observeOn(AndroidSchedulers.mainThread())
.subscribe(new Action1<String>() {
@Override
public void call(String s) {
System.out.println(s);
}
}, new Action1<Throwable>() {
@Override
public void call(Throwable throwable) {
throwable.printStackTrace();
}
});
Here we can see a few new things:
.subscribeOn(Schedulers.io())- it will make the Observable to do its waiting and computations on a ThreadPool that's dedicated for I/O (Schedulers.io())..observeOn(AndroidSchedulers.mainThread())- makes subscriber action to execute its result on Android's main thread. This is needed if one wants to change anything on Android UI.- A second argument to
.subscribe()- introduces an error handler for subscription in case something goes wrong. It's something that should be present almost always.
Managing complicated flow.
Remember the complicated flow we described initially?
Here is how it would look with RxJava:
Observable.fromCallable(createNewUser())
.subscribeOn(Schedulers.io())
.flatMap(new Func1<User, Observable<Pair<Settings, List<Message>>>>() {
@Override
public Observable<Pair<Settings, List<Message>>> call(User user) {
return Observable.zip(
Observable.from(fetchUserSettings(user)),
Observable.from(fetchUserMessages(user))
, new Func2<Settings, List<Message>, Pair<Settings, List<Message>>>() {
@Override
public Pair<Settings, List<Message>> call(Settings settings, List<Message> messages) {
return Pair.create(settings, messages);
}
});
}
})
.doOnNext(new Action1<Pair<Settings, List<Message>>>() {
@Override
public void call(Pair<Settings, List<Message>> pair) {
System.out.println("Received settings" + pair.first);
}
})
.flatMap(new Func1<Pair<Settings, List<Message>>, Observable<Message>>() {
@Override
public Observable<Message> call(Pair<Settings, List<Message>> settingsListPair) {
return Observable.from(settingsListPair.second);
}
})
.subscribe(new Action1<Message>() {
@Override
public void call(Message message) {
System.out.println("New message " + message);
}
});
This will create a new user (createNewUser()) and when
it is created and result is returned, it continues to fetch
user messages (fetchUserMessages()) and user settings (fetchUserSettings)
at the same time. It will wait until both actions are completed
and will return a combined result (Pair.create()).
Keep in mind that all of this is happening in the background on a separate thread.
After that, it will print out settings that were received. Finally, the list of messages is transformed into another observable that will start emitting messages themselves instead of an entire list, and each of the messages are printed.
A functional approach
RxJava will be much easier if programmer is familiar with functional programming concepts such as map and zip. Also, they both share lots of similarities of how one would construct a generic logic flow.
How to create a custom observable?
If codes becomes heavily based on RxJava (as for example as Feedpresso is), you will find yourself often in a position where you need to write custom observables so they would fit your flow.
An example of that:
public Observable<String> customObservable() {
return rx.Observable.create(new rx.Observable.OnSubscribe<String>() {
@Override
public void call(final Subscriber<? super String> subscriber) {
// Execute in a background
Scheduler.Worker inner = Schedulers.io().createWorker();
subscriber.add(inner);
inner.schedule(new Action0() {
@Override
public void call() {
try {
String fancyText = getJson();
subscriber.onNext(fancyText);
} catch (Exception e) {
subscriber.onError(e);
} finally {
subscriber.onCompleted();
}
}
});
}
});
}
or a simpler version that doesn't enforce execution of action on a specific thread:
Observable<String> observable = Observable.create(
new Observable.OnSubscribe<String>() {
@Override
public void call(Subscriber<? super String> subscriber) {
subscriber.onNext("Hi");
subscriber.onCompleted();
}
}
);
It is important to note three methods here:
onNext(v)- send a new value to a subscriberonError(e)- notify observer about an error that has occurredonCompleted()- let subscriber know that it should unsubscribe as there won't be any more content from this observable.
Furthermore, it's might be handy to rely on RxJavaAsyncUtil.
Integration with other libraries
As RxJava is becoming more and more popular and becoming de-facto way of doing asynchronous programming on Android, more and more libraries are providing deep integration or reliance on it.
To name a few:
- Retrofit - "Type-safe HTTP client for Android and Java"
- SqlBrite - "A lightweight wrapper around SQLiteOpenHelper which introduces reactive stream semantics to SQL operations."
- StorIO - "Beautiful API for SQLiteDatabase and ContentResolver"
All of them, can make life a lot easier when working with HTTP requests and databases.
Interactive with Android UI
This intro wouldn't be complete without an example, how to use native Android UI elements.
TextView finalText;
EditText editText;
Button button;
...
RxView.clicks(button)
.subscribe(new Action1<Void>() {
@Override
public void call(Void aVoid) {
System.out.println("Click");
}
});
RxTextView.textChanges(editText)
.subscribe(new Action1<CharSequence>() {
@Override
public void call(CharSequence charSequence) {
finalText.setText(charSequence);
}
});
...
Obviously, it's easy to just rely on setOnClickListener
but RxBinding might suit your needs better in a long run as
it allows you to plugin UI into a general RxJava flow.
Tips
Over a time, we have noticed a few things that should be followed while working with RxJava.
Always use error handler
Skipping an error handler like here
.subscribe(new Action1<Void>() {
@Override
public void call(Void aVoid) {
System.out.println("Click");
}
});
is generally not a good idea. An exception thrown in observer or in one of the actions will most likely kill your entire application.
Having a generic handler, would be even better:
.subscribe(..., myErrorHandler);
Extract actions methods
Having lots of inner classes might not look so readable after a while (especially if you are not using RetroLambda).
So a code like this:
.doOnNext(new Action1<Pair<Settings, List<Message>>>() {
@Override
public void call(Pair<Settings, List<Message>> pair) {
System.out.println("Received settings" + pair.first);
}
})
could look a lot better if refactored into this:
.doOnNext(logSettings())
@NonNull
private Action1<Pair<Settings, List<Message>>> logSettings() {
return new Action1<Pair<Settings, List<Message>>>() {
@Override
public void call(Pair<Settings, List<Message>> pair) {
System.out.println("Received settings" + pair.first);
}
};
}
Use custom classes or tuples
There will be many occasions where one value depends on the first one (User and user settings) and you would like to get both of them using two asynchronous requests.
In such cases we would suggest using JavaTuples .
Example:
Observable.fromCallable(createNewUser())
.subscribeOn(Schedulers.io())
.flatMap(new Func1<User, Observable<Pair<User, Settings>>>() {
@Override
public Observable<Pair<User, Settings>> call(final User user) {
return Observable.from(fetchUserSettings(user))
.map(new Func1<Settings, Pair<User, Settings>>() {
@Override
public Pair<User, Settings> call(Settings o) {
return Pair.create(user, o);
}
});
}
});
Lifecycle management
It is going to be often a case when a background process (subscription) is going to survive longer than the Activity or Fragment that contains it. But what if you don't care about the result if user leaves the actvity?
RxLifecycle project will help you here.
Wrap your observable like this (taken from docs), it will unsubscribe when it is being destroyed:
public class MyActivity extends RxActivity {
@Override
public void onResume() {
super.onResume();
myObservable
.compose(bindToLifecycle())
.subscribe();
}
}
Conclusion
This is far from a complete guide about RxJava usage on Android but hopefully it gave a few arguments in favor of RxJava compared to regular AsyncTask.