LiveData overview Part of Android Jetpack.
LiveData
is an observable
data holder class. Unlike a regular observable, LiveData is lifecycle-aware,
meaning it respects the lifecycle of other app components, such as activities,
fragments, or services. This awareness ensures LiveData only updates app
component observers that are in an active lifecycle state.
LiveData considers an observer, which is represented by the
Observer
class, to be in an
active state if its lifecycle is in the
STARTED
or
RESUMED
state. LiveData only notifies active observers about updates. Inactive
observers registered to watch
LiveData
objects aren't
notified about changes.
You can register an observer paired with an object that implements the
LifecycleOwner
interface. This relationship allows the observer to be removed when the state of
the corresponding
Lifecycle
object changes
to
DESTROYED
.
This is especially useful for activities and fragments because they can safely
observe LiveData
objects
and not worry about leaks—activities and fragments are instantly
unsubscribed when their lifecycles are destroyed.
For more information about how to use LiveData, see Work with LiveData objects.
The advantages of using LiveData
Using LiveData provides the following advantages:
- Ensures your UI matches your data state
- LiveData follows the observer pattern. LiveData notifies
Observer
objects when underlying data changes. You can consolidate your code to update the UI in theseObserver
objects. That way, you don't need to update the UI every time the app data changes because the observer does it for you. - No memory leaks
- Observers are bound to
Lifecycle
objects and clean up after themselves when their associated lifecycle is destroyed. - No crashes due to stopped activities
- If the observer's lifecycle is inactive, such as in the case of an activity in the back stack, then it doesn’t receive any LiveData events.
- No more manual lifecycle handling
- UI components just observe relevant data and don’t stop or resume observation. LiveData automatically manages all of this since it’s aware of the relevant lifecycle status changes while observing.
- Always up to date data
- If a lifecycle becomes inactive, it receives the latest data upon becoming active again. For example, an activity that was in the background receives the latest data right after it returns to the foreground.
- Proper configuration changes
- If an activity or fragment is recreated due to a configuration change, like device rotation, it immediately receives the latest available data.
- Sharing resources
- You can extend a
LiveData
object using the singleton pattern to wrap system services so that they can be shared in your app. TheLiveData
object connects to the system service once, and then any observer that needs the resource can just watch theLiveData
object. For more information, see Extend LiveData.
Work with LiveData objects
Follow these steps to work with
LiveData
objects:
- Create an instance of
LiveData
to hold a certain type of data. This is usually done within yourViewModel
class. - Create an
Observer
object that defines theonChanged()
method, which controls what happens when theLiveData
object's held data changes. You usually create anObserver
object in a UI controller, such as an activity or fragment. Attach the
Observer
object to theLiveData
object using theobserve()
method. Theobserve()
method takes aLifecycleOwner
object. This subscribes theObserver
object to theLiveData
object so that it is notified of changes. You usually attach theObserver
object in a UI controller, such as an activity or fragment.
When you update the value stored in the LiveData
object, it triggers all
registered observers as long as the attached LifecycleOwner
is in the active
state.
LiveData allows UI controller observers to subscribe to updates. When the data
held by the LiveData
object changes, the UI automatically updates in response.
Create LiveData objects
LiveData is a wrapper that can be used with any data, including objects that
implement Collections
, such as List
. A
LiveData
object is usually
stored within a ViewModel
object and is accessed via a getter method, as demonstrated in the following
example:
Kotlin
class NameViewModel : ViewModel() { // Create a LiveData with a String val currentName: MutableLiveData<String> by lazy { MutableLiveData<String>() } // Rest of the ViewModel... }
Java
public class NameViewModel extends ViewModel { // Create a LiveData with a String private MutableLiveData<String> currentName; public MutableLiveData<String> getCurrentName() { if (currentName == null) { currentName = new MutableLiveData<String>(); } return currentName; } // Rest of the ViewModel... }
Initially, the data in a LiveData
object is not set.
You can read more about the benefits and usage of the ViewModel
class in the
ViewModel guide.
Observe LiveData objects
In most cases, an app component’s onCreate()
method is the right place to begin observing a
LiveData
object for the
following reasons:
- To ensure the system doesn’t make redundant calls from an activity or
fragment’s
onResume()
method. - To ensure that the activity or fragment has data that it can display as soon
as it becomes active. As soon as an app component is in the
STARTED
state, it receives the most recent value from theLiveData
objects it’s observing. This only occurs if theLiveData
object to be observed has been set.
Generally, LiveData delivers updates only when data changes, and only to active observers. An exception to this behavior is that observers also receive an update when they change from an inactive to an active state. Furthermore, if the observer changes from inactive to active a second time, it only receives an update if the value has changed since the last time it became active.
The following sample code illustrates how to start observing a LiveData
object:
Kotlin
class NameActivity : AppCompatActivity() { // Use the 'by viewModels()' Kotlin property delegate // from the activity-ktx artifact private val model: NameViewModel by viewModels() override fun onCreate(savedInstanceState: Bundle?) { super.onCreate(savedInstanceState) // Other code to setup the activity... // Create the observer which updates the UI. val nameObserver = Observer<String> { newName -> // Update the UI, in this case, a TextView. nameTextView.text = newName } // Observe the LiveData, passing in this activity as the LifecycleOwner and the observer. model.currentName.observe(this, nameObserver) } }
Java
public class NameActivity extends AppCompatActivity { private NameViewModel model; @Override protected void onCreate(Bundle savedInstanceState) { super.onCreate(savedInstanceState); // Other code to setup the activity... // Get the ViewModel. model = new ViewModelProvider(this).get(NameViewModel.class); // Create the observer which updates the UI. final Observer<String> nameObserver = new Observer<String>() { @Override public void onChanged(@Nullable final String newName) { // Update the UI, in this case, a TextView. nameTextView.setText(newName); } }; // Observe the LiveData, passing in this activity as the LifecycleOwner and the observer. model.getCurrentName().observe(this, nameObserver); } }
After
observe()
is called with nameObserver
passed as
parameter,
onChanged()
is immediately invoked providing the most recent value stored in mCurrentName
.
If the LiveData
object hasn't set a value in mCurrentName
, onChanged()
is
not called.
Update LiveData objects
LiveData has no publicly available methods to update the stored data. The
MutableLiveData
class exposes the
setValue(T)
and
postValue(T)
methods publicly and you must use these if you need to edit the value stored in
a LiveData
object. Usually
MutableLiveData
is used in the
ViewModel
and then the
ViewModel
only exposes immutable LiveData
objects to the observers.
After you have set up the observer relationship, you can then update the value
of the LiveData
object, as illustrated by the following example, which
triggers all observers when the user taps a button:
Kotlin
button.setOnClickListener { val anotherName = "John Doe" model.currentName.setValue(anotherName) }
Java
button.setOnClickListener(new OnClickListener() { @Override public void onClick(View v) { String anotherName = "John Doe"; model.getCurrentName().setValue(anotherName); } });
Calling setValue(T)
in the example results in the observers calling their
onChanged()
methods with the value John Doe
. The example shows a button press, but
setValue()
or postValue()
could be called to update mName
for a variety of
reasons, including in response to a network request or a database load
completing; in all cases, the call to setValue()
or postValue()
triggers
observers and updates the UI.
Use LiveData with Room
The Room persistence library supports
observable queries, which return
LiveData
objects.
Observable queries are written as part of a Database Access Object (DAO).
Room generates all the necessary code to update the LiveData
object when a
database is updated. The generated code runs the query asynchronously on a
background thread when needed. This pattern is useful for keeping the data
displayed in a UI in sync with the data stored in a database. You can read more
about Room and DAOs in the Room persistent library
guide.
Use coroutines with LiveData
LiveData
includes support for Kotlin coroutines. For more information, see
Use Kotlin coroutines with Android Architecture Components.
LiveData in an app's architecture
LiveData
is lifecycle-aware, following the lifecycle of entities such as
activities and fragments. Use LiveData
to communicate between these lifecycle
owners and other objects with a different lifespan, such as ViewModel
objects.
The main responsibility of the ViewModel
is to load and manage UI-related
data, which makes it a great candidate for holding LiveData
objects. Create
LiveData
objects in the ViewModel
and use them to expose state to the UI
layer.
Activities and fragments should not hold LiveData
instances because their role
is to display data, not hold state. Also, keeping activities and fragments free
from holding data makes it easier to write unit tests.
It may be tempting to work LiveData
objects in your data layer class, but
LiveData
is not designed to handle asynchronous streams of data. Even though
you can use LiveData
transformations and MediatorLiveData
to achieve this, this approach has drawbacks: the capability to combine streams
of data is very limited and all LiveData
objects (including ones created
through transformations) are observed on the main thread. The code below is an
example of how holding a LiveData
in the Repository
can block the main
thread:
Kotlin
class UserRepository { // DON'T DO THIS! LiveData objects should not live in the repository. fun getUsers(): LiveData<List<User>> { ... } fun getNewPremiumUsers(): LiveData<List<User>> { return getUsers().map { users -> // This is an expensive call being made on the main thread and may // cause noticeable jank in the UI! users .filter { user -> user.isPremium } .filter { user -> val lastSyncedTime = dao.getLastSyncedTime() user.timeCreated > lastSyncedTime } } }
Java
class UserRepository { // DON'T DO THIS! LiveData objects should not live in the repository. LiveData<List<User>> getUsers() { ... } LiveData<List<User>> getNewPremiumUsers() { return Transformations.map(getUsers(), // This is an expensive call being made on the main thread and may cause // noticeable jank in the UI! users -> users.stream() .filter(User::isPremium) .filter(user -> user.getTimeCreated() > dao.getLastSyncedTime()) .collect(Collectors.toList())); } }
If you need to use streams of data in other layers of your app, consider
using Kotlin Flows and then converting them to LiveData
in the
ViewModel
using asLiveData()
.
Learn more about using Kotlin Flow
with LiveData
in this codelab.
For codebases built with Java, consider using Executors
in conjunction with callbacks or RxJava
.
Extend LiveData
LiveData considers an observer to be in an active state if the observer's
lifecycle is in either the
STARTED
or RESUMED
states. The following sample code illustrates how to extend the
LiveData
class:
Kotlin
class StockLiveData(symbol: String) : LiveData<BigDecimal>() { private val stockManager = StockManager(symbol) private val listener = { price: BigDecimal -> value = price } override fun onActive() { stockManager.requestPriceUpdates(listener) } override fun onInactive() { stockManager.removeUpdates(listener) } }
Java
public class StockLiveData extends LiveData<BigDecimal> { private StockManager stockManager; private SimplePriceListener listener = new SimplePriceListener() { @Override public void onPriceChanged(BigDecimal price) { setValue(price); } }; public StockLiveData(String symbol) { stockManager = new StockManager(symbol); } @Override protected void onActive() { stockManager.requestPriceUpdates(listener); } @Override protected void onInactive() { stockManager.removeUpdates(listener); } }
The implementation of the price listener in this example includes the following important methods:
- The
onActive()
method is called when theLiveData
object has an active observer. This means you need to start observing the stock price updates from this method. - The
onInactive()
method is called when theLiveData
object doesn't have any active observers. Since no observers are listening, there is no reason to stay connected to theStockManager
service. - The
setValue(T)
method updates the value of theLiveData
instance and notifies any active observers about the change.
You can use the StockLiveData
class as follows:
Kotlin
public class MyFragment : Fragment() { override fun onViewCreated(view: View, savedInstanceState: Bundle?) { super.onViewCreated(view, savedInstanceState) val myPriceListener: LiveData<BigDecimal> = ... myPriceListener.observe(viewLifecycleOwner, Observer<BigDecimal> { price: BigDecimal? -> // Update the UI. }) } }
Java
public class MyFragment extends Fragment { @Override public void onViewCreated(@NonNull View view, @Nullable Bundle savedInstanceState) { super.onViewCreated(view, savedInstanceState); LiveData<BigDecimal> myPriceListener = ...; myPriceListener.observe(getViewLifecycleOwner(), price -> { // Update the UI. }); } }
The
observe()
method passes the LifecycleOwner
associated with the fragment's view as the first argument. Doing so denotes that
this observer is bound to the Lifecycle
object
associated with the owner, meaning:
- If the
Lifecycle
object is not in an active state, then the observer isn't called even if the value changes. - After the
Lifecycle
object is destroyed, the observer is automatically removed.
The fact that LiveData
objects are lifecycle-aware means that you can share
them between multiple activities, fragments, and services. To keep the example
simple, you can implement the LiveData
class as a singleton as follows:
Kotlin
class StockLiveData(symbol: String) : LiveData<BigDecimal>() { private val stockManager: StockManager = StockManager(symbol) private val listener = { price: BigDecimal -> value = price } override fun onActive() { stockManager.requestPriceUpdates(listener) } override fun onInactive() { stockManager.removeUpdates(listener) } companion object { private lateinit var sInstance: StockLiveData @MainThread fun get(symbol: String): StockLiveData { sInstance = if (::sInstance.isInitialized) sInstance else StockLiveData(symbol) return sInstance } } }
Java
public class StockLiveData extends LiveData<BigDecimal> { private static StockLiveData sInstance; private StockManager stockManager; private SimplePriceListener listener = new SimplePriceListener() { @Override public void onPriceChanged(BigDecimal price) { setValue(price); } }; @MainThread public static StockLiveData get(String symbol) { if (sInstance == null) { sInstance = new StockLiveData(symbol); } return sInstance; } private StockLiveData(String symbol) { stockManager = new StockManager(symbol); } @Override protected void onActive() { stockManager.requestPriceUpdates(listener); } @Override protected void onInactive() { stockManager.removeUpdates(listener); } }
And you can use it in the fragment as follows:
Kotlin
class MyFragment : Fragment() { override fun onViewCreated(view: View, savedInstanceState: Bundle?) { super.onViewCreated(view, savedInstanceState) StockLiveData.get(symbol).observe(viewLifecycleOwner, Observer<BigDecimal> { price: BigDecimal? -> // Update the UI. }) }
Java
public class MyFragment extends Fragment { @Override public void onViewCreated(@NonNull View view, @Nullable Bundle savedInstanceState) { super.onViewCreated(view, savedInstanceState); StockLiveData.get(symbol).observe(getViewLifecycleOwner(), price -> { // Update the UI. }); } }
Multiple fragments and activities can observe the MyPriceListener
instance.
LiveData only connects to the system service if one or more of them is visible
and active.
Transform LiveData
You may want to make changes to the value stored in a
LiveData
object before
dispatching it to the observers, or you may need to return a different
LiveData
instance based on the value of another one. The
Lifecycle
package
provides the
Transformations
class which includes helper methods that support these scenarios.
Transformations.map()
- Applies a function on the value stored in the
LiveData
object, and propagates the result downstream.
Kotlin
val userLiveData: LiveData<User> = UserLiveData() val userName: LiveData<String> = userLiveData.map { user -> "${user.name} ${user.lastName}" }
Java
LiveData<User> userLiveData = ...; LiveData<String> userName = Transformations.map(userLiveData, user -> { user.name + " " + user.lastName });
Transformations.switchMap()
- Similar to
map()
, applies a function to the value stored in theLiveData
object and unwraps and dispatches the result downstream. The function passed toswitchMap()
must return aLiveData
object, as illustrated by the following example:
Kotlin
private fun getUser(id: String): LiveData<User> { ... } val userId: LiveData<String> = ... val user = userId.switchMap { id -> getUser(id) }
Java
private LiveData<User> getUser(String id) { ...; } LiveData<String> userId = ...; LiveData<User> user = Transformations.switchMap(userId, id -> getUser(id) );
You can use transformation methods to carry information across the observer's
lifecycle. The transformations aren't calculated unless an observer is watching
the returned LiveData
object. Because the transformations are calculated
lazily, lifecycle-related behavior is implicitly passed down without requiring
additional explicit calls or dependencies.
If you think you need a Lifecycle
object inside a
ViewModel
object, a
transformation is probably a better solution. For example, assume that you have
a UI component that accepts an address and returns the postal code for that
address. You can implement the naive ViewModel
for this component as
illustrated by the following sample code:
Kotlin
class MyViewModel(private val repository: PostalCodeRepository) : ViewModel() { private fun getPostalCode(address: String): LiveData<String> { // DON'T DO THIS return repository.getPostCode(address) } }
Java
class MyViewModel extends ViewModel { private final PostalCodeRepository repository; public MyViewModel(PostalCodeRepository repository) { this.repository = repository; } private LiveData<String> getPostalCode(String address) { // DON'T DO THIS return repository.getPostCode(address); } }
The UI component then needs to unregister from the previous LiveData
object
and register to the new instance each time it calls getPostalCode()
. In
addition, if the UI component is recreated, it triggers another call to the
repository.getPostCode()
method instead of using the previous call’s result.
Instead, you can implement the postal code lookup as a transformation of the address input, as shown in the following example:
Kotlin
class MyViewModel(private val repository: PostalCodeRepository) : ViewModel() { private val addressInput = MutableLiveData<String>() val postalCode: LiveData<String> = addressInput.switchMap { address -> repository.getPostCode(address) } private fun setInput(address: String) { addressInput.value = address } }
Java
class MyViewModel extends ViewModel { private final PostalCodeRepository repository; private final MutableLiveData<String> addressInput = new MutableLiveData(); public final LiveData<String> postalCode = Transformations.switchMap(addressInput, (address) -> { return repository.getPostCode(address); }); public MyViewModel(PostalCodeRepository repository) { this.repository = repository } private void setInput(String address) { addressInput.setValue(address); } }
In this case, the postalCode
field is defined as a transformation of the
addressInput
. As long as your app has an active observer associated with the
postalCode
field, the field's value is recalculated and retrieved whenever
addressInput
changes.
This mechanism allows lower levels of the app to create LiveData
objects that
are lazily calculated on demand. A ViewModel
object can easily obtain
references to LiveData
objects and then define transformation rules on top of
them.
Create new transformations
There are a dozen different specific transformation that may be useful in your
app, but they aren’t provided by default. To implement your own transformation
you can you use the MediatorLiveData
class, which listens to other
LiveData
objects and
processes events emitted by them. MediatorLiveData
correctly propagates its
state to the source LiveData
object. To learn more about this pattern, see the
reference documentation of the
Transformations
class.
Merge multiple LiveData sources
MediatorLiveData
is
a subclass of LiveData
that
allows you to merge multiple LiveData sources. Observers of MediatorLiveData
objects are then triggered whenever any of the original LiveData source objects
change.
For example, if you have a LiveData
object in your UI that can be updated from
a local database or a network, then you can add the following sources to the
MediatorLiveData
object:
- A
LiveData
object associated with the data stored in the database. - A
LiveData
object associated with the data accessed from the network.
Your activity only needs to observe the MediatorLiveData
object to receive
updates from both sources. For a detailed example, see the Addendum: exposing
network status
section of the Guide to App
Architecture.
Additional resources
To learn more about the
LiveData
class, consult
the following resources.
Samples
- Sunflower, a demo app demonstrating best practices with Architecture Components
Codelabs
- Android Room with a View (Java) (Kotlin)
- Learn advanced coroutines with Kotlin Flow and LiveData
Blogs
- ViewModels and LiveData: Patterns + AntiPatterns
- LiveData beyond the ViewModel — Reactive patterns using Transformations and MediatorLiveData
- LiveData with SnackBar, Navigation and other events (the SingleLiveEvent case)
Videos
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