Provider vs Riverpod
This article recaps the defferences and the similarities between Provider and Riverpod.
Defining providers
The primary difference between both packages is how "providers" are defined.
With Provider, providers are widgets and as such placed inside the widget tree,
typically inside a MultiProvider
:
class Counter extends ChangeNotifier {
...
}
void main() {
runApp(
MultiProvider(
providers: [
ChangeNotifierProvider<Counter>(create: (context) => Counter()),
],
child: MyApp(),
)
);
}
With Riverpod, providers are not widgets. Instead they are plain Dart objects.
Similarly, providers are defined outside of the widget tree, and instead are declared
as global final variables.
Also, for Riverpod to work, it is necessary to add a ProviderScope
widget above the
entire application. As such, the equivalent of the Provider example using Riverpod
would be:
// Providers are now top-level variables
final counterProvider = ChangeNotifierProvider<Counter>((ref) => Counter());
void main() {
runApp(
// This widget enables Riverpod for the entire project
ProviderScope(
child: MyApp(),
),
);
}
Notice how the provider definition simply moved up a few lines.
Since with Riverpod providers are plain Dart objects, it is possible to use
Riverpod without Flutter.
For example, Riverpod can be used to write command line applications.
Reading providers: BuildContext
With Provider, one way of reading providers is to use a Widget's BuildContext
.
For example, if a provider was defined as:
Provider<Model>(...);
then reading it using Provider is done with:
class Example extends StatelessWidget {
Widget build(BuildContext context) {
Model model = context.watch<Model>();
}
}
The equivalent in Riverpod would be:
final modelProvider = Provider<Model>(...);
class Example extends ConsumerWidget {
Widget build(BuildContext context, WidgetRef ref) {
Model model = ref.watch(modelProvider);
}
}
Notice how:
Riverpod's snippet extends
ConsumerWidget
instead ofStatelessWidget
. That different widget type adds one extra parameter to ourbuild
function:WidgetRef
.Instead of
BuildContext.watch
, in Riverpod we doWidgetRef.watch
, using theWidgetRef
which we obtained fromConsumerWidget
.Riverpod does not rely on generic types. Instead it relies on the variable created using provider definition.
Notice too how similar the wording is. Both Provider and Riverpod use the keyword "watch" to describe "this widget should rebuild when the value changes".
Riverpod uses the same terminology as Provider for reading providers.
BuildContext.watch
->WidgetRef.watch
BuildContext.read
->WidgetRef.read
BuildContext.select
->WidgetRef.watch(myProvider.select)
The rules for context.watch
vs context.read
applies to Riverpod too:
Inside the build
method, use "watch". Inside click handlers and other events,
use "read". When in need of filtering out values and rebuilds, use "select".
Reading providers: Consumer
Provider optionally comes with a widget named Consumer
(and variants such as Consumer2
)
for reading providers.
Consumer
is helpful as a performance optimization, by allowing more granular rebuilds
of the widget tree - updating only the revelant widgets when the state changes:
As such, if a provider was defined as:
Provider<Model>(...);
Provider allows reading that provider using Consumer
with:
Consumer<Model>(
builder: (BuildContext context, Model model, Widget? child) {
}
)
Riverpod has the same principle. Riverpod, too, has a widget named Consumer
for the exact same purpose.
If we defined a provider as:
final modelProvider = Provider<Model>(...);
Then using Consumer
we could do:
Consumer(
builder: (BuildContext context, WidgetRef ref, Widget? child) {
Model model = ref.watch(modelProvider);
}
)
Notice how Consumer
gives us a WidgetRef
object. This is the same object
as we saw in the previous part related to ConsumerWidget
.
There is no ConsumerN
equivalent in Riverpod
Notice how pkg:Provider's Consumer2
, Consumer3
and such aren't needed nor missed in Riverpod.
With Riverpod, if you want to read values from multiple providers, you can simply write multiple ref.watch
statements,
like so:
Consumer(
builder: (context, ref, child) {
Model1 model = ref.watch(model1Provider);
Model2 model = ref.watch(model2Provider);
Model3 model = ref.watch(model3Provider);
// ...
}
)
When compared to pkg:Provider's ConsumerN
APIs, the above solution feels way less heavy and it should be easier to understand.
Combining providers: ProxyProvider with stateless objects
When using Provider, the official way of combining providers is using the
ProxyProvider
widget (or variants such as ProxyProvider2
).
For example we may define:
class UserIdNotifier extends ChangeNotifier {
String? userId;
}
// ...
ChangeNotifierProvider<UserIdNotifier>(create: (context) => UserIdNotifier()),
From there we have two options. We may combine UserIdNotifier
to create a new
"stateless" provider (typically an immutable value that possibly override ==).
Such as:
ProxyProvider<UserIdNotifier, String>(
update: (context, userIdNotifier, _) {
return 'The user ID of the the user is ${userIdNotifier.userId}';
}
)
This provider would automatically return a new String
whenever
UserIdNotifier.userId
changes.
We can do something similar in Riverpod, but the syntax is different.
First, in Riverpod, the definition of our UserIdNotifier
would be:
class UserIdNotifier extends ChangeNotifier {
String? userId;
}
// ...
final userIdNotifierProvider = ChangeNotifierProvider<UserIdNotifier>(
(ref) => UserIdNotifier(),
);
From there, to generate our String
based on the userId
, we could do:
final labelProvider = Provider<String>((ref) {
UserIdNotifier userIdNotifier = ref.watch(userIdNotifierProvider);
return 'The user ID of the the user is ${userIdNotifier.userId}';
});
Notice the line doing ref.watch(userIdNotifierProvider)
.
This line of code tells Riverpod to obtain the content of the userIdNotifierProvider
and that whenever that value changes, labelProvider
will be recomputed too.
As such, the String
emitted by our labelProvider
will automatically update
whenever the userId
changes.
This ref.watch
line should feel similar. This pattern was covered previously
when explaining how to read providers inside widgets.
Indeed, providers are now able to listen to other providers in the same way
that widgets do.
Combining providers: ProxyProvider with stateful objects
When combining providers, another alternative use-case is to expose
stateful objects, such as a ChangeNotifier
instance.
For that, we could use ChangeNotifierProxyProvider
(or variants such as ChangeNotifierProxyProvider2
).
For example we may define:
class UserIdNotifier extends ChangeNotifier {
String? userId;
}
// ...
ChangeNotifierProvider<UserIdNotifier>(create: (context) => UserIdNotifier()),
Then, we can define a new ChangeNotifier
that is based on UserIdNotifier.userId
.
For example we could do:
class UserNotifier extends ChangeNotifier {
String? _userId;
void setUserId(String? userId) {
if (userId != _userId) {
print('The user ID changed from $_userId to $userId');
_userId = userId;
}
}
}
// ...
ChangeNotifierProxyProvider<UserIdNotifier, UserNotifier>(
create: (context) => UserNotifier(),
update: (context, userIdNotifier, userNotifier) {
return userNotifier!
..setUserId(userIdNotifier.userId);
},
);
This new provider creates a single instance of UserNotifier
(which is never re-constructed)
and prints a string whenever the user ID changes.
Doing the same thing in provider is achieved differently.
First, in Riverpod, the definition of our UserIdNotifier
would be:
class UserIdNotifier extends ChangeNotifier {
String? userId;
}
// ...
final userIdNotifierProvider = ChangeNotifierProvider<UserIdNotifier>(
(ref) => UserIdNotifier(),
),
From there, the equivalent to the previous ChangeNotifierProxyProvider
would be:
class UserNotifier extends ChangeNotifier {
String? _userId;
void setUserId(String? userId) {
if (userId != _userId) {
print('The user ID changed from $_userId to $userId');
_userId = userId;
}
}
}
// ...
final userNotifierProvider = ChangeNotifierProvider<UserNotifier>((ref) {
final userNotifier = UserNotifier();
ref.listen<UserIdNotifier>(
userIdNotifierProvider,
(previous, next) {
if (previous?.userId != next.userId) {
userNotifier.setUserId(next.userId);
}
},
);
return userNotifier;
});
The core of this snippet is the ref.listen
line.
This ref.listen
function is a utility that allows listening to a provider,
and whenever the provider changes, executes a function.
The previous
and next
parameters of that function correspond to the
last value before the provider changed and the new value after it changed.
Scoping Providers vs .family
+ .autoDispose
In pkg:Provider, scoping was used for two things:
- destroying state when leaving a page
- having custom state per page
Using scoping just to destroy state isn't ideal.
The problem is that scoping doesn't work well over large applications.
For example, state often is created in one page, but destroyed later in a different page after navigation.
This doesn't allow for multiple caches to be active over different pages.
Similarly, the "custom state per page" approach quickly becomes difficult to handle if that state needs to be shared with another part of the widget tree, like you'd need with modals or a with a multi-step form.
Riverpod takes a different approach: first, scoping providers is kind-of discouraged; second,
.family
and .autoDispose
are a complete replacement solution for this.
Within Riverpod, Providers marked as .autoDispose
automatically destroy their state when they aren't used anymore.
When the last widget removing a provider is unmounted, Riverpod will detect this and destroy the provider.
Try using these two lifecycle methods in a provider to test this behavior:
ref.onCancel((){
print("No one listens to me anymore!");
});
ref.onDispose((){
print("If I've been defined as `.autoDispose`, I just got disposed!");
});
This inherently solves the "destroying state" problem.
Also it is possible to mark a Provider as .family
(and, at the same time, as .autoDispose
).
This enables passing parameters to providers, which make multiple providers to be spawned and tracked internally.
In other words, when passing parameters, a unique state is created per unique parameter.
int random(RandomRef ref, {required int seed, required int max}) {
return Random(seed).nextInt(max);
}
This solves the "custom state per page" problem. Actually, there's another advantage: such state is no-longer bound to one specific page.
Instead, if a different page tries to access the same state, such page will be able to do so by just reusing the parameters.
In many ways, passing parameters to providers is equivalent to a Map key.
If the key is the same, the value obtained is the same. If it's a different key, a different state will be obtained.