This is a reference architecture demo that can be used as a starting point for apps using Flutter & Firebase.
Also see my codewithandrea_flutter_packages repo, which contains the most reusable parts of this project as packages.
Flutter & Firebase are a great combo for getting apps to market in record time.
Without a sound architecture, codebases can quickly become hard to test, maintain, and reason about. This severely impacts the development speed, and results in buggy products, sad developers and unhappy users.
I have already witnessed this first-hand with various client projects, where the lack of a formal architecture led to days, weeks - even months of extra work.
Is "architecture" hard? How can one find the "right" or "correct" architecture in the ever-changing landscape of front-end development?
Every app has different requirements, so does the "right" architecture even exist in the first place?
While I don't claim to have a silver bullet, I have refined and fine-tuned a production-ready architecture that I have deployed successfully into multiple Flutter & Firebase apps.
I call this "Stream-based Architecture for Flutter & Firebase Realtime Apps".
Two words are key here: Stream and Realtime.
Unlike with traditional REST APIs, with Firebase we can build realtime apps.
That's because Firebase can push updates directly to subscribed clients when something changes.
For example, widgets can rebuild themselves when certain Firestore documents or collections are updated.
Many Firebase APIs are inherently stream-based. As a result, the simplest way of making our widgets reactive is to use StreamProvider
from the Riverpod package. This provides a convenient way of watching changes in your Firebase streams, and automatically rebuilding widgets with minimal boilerplate code.
Yes, you could use ChangeNotifier
or other state management techniques that implement observables/listeners. But you would need additional "glue" code if you want to "convert" your input streams into reactive models based on ChangeNotifier
.
Note: streams are the default way of pushing changes not only with Firebase, but with many other services as well. For example, you can get location updates with the
onLocationChanged()
stream of the location package. Whether you use Firestore, or want to get data from your device's input sensors, streams are the most convenient way of delivering asynchronous data over time.
A more detailed overview of this architecture is outlined below. But first, here are the goals for this project.
Define a reference architecture that can be used as the foundation for Flutter apps using Firebase (or other streaming APIs).
This architecture should:
- minimize mutable state by adopting an unidirectional data flow
- clearly define application layers and their boundaries
- require little boilerplate code
The resulting code should be:
- clear
- reusable
- scalable
- testable
- performant
- maintainable
These are all nice properties, but how do they all fit together in practice?
By introducing application layers with clear boundaries, and defining how the data flows through them.
To ensure a good separation of concerns, this architecture defines three main application layers.
- UI Layer: where the widgets live
- Logic & Presentation Layer: this contains the application's business and presentation logic
- Domain Layer: this contains domain-specific services for interacting with 3rd party APIs
These layers may be named differently in other literature.
What matters here is that the data flows from the services into the widgets, and the call flow goes in the opposite direction.
Widgets subscribe themselves as listeners, while view models publish updates when something changes.
The publish/subscribe pattern comes in many variants (e.g. ChangeNotifier, BLoC), and this architecture does not prescribe which one to use.
By using Riverpod, we can easily use the most convenient pattern on a case-by-case bsis. In practice, this means using Stream
s with StreamProvider
when reading and manipulating data from Firestore. But when dealing with local application state, StatefulWidget
+setState
or ChangeNotifier
are sometimes used.
Let's look at the three application layers in more detail.
Services are pure, functional components that don't hold any state.
Services serve as an abstraction from external data sources, and provide domain-specific APIs to the rest of the app (more on this below).
Because service APIs return strongly-typed, immutable, domain-specific model objects, the rest of the app doesn't directly manipulate the raw data from the outside world (e.g. Firestore documents represented as key-value pairs).
As a bonus, breaking changes in external packages are easier to deal with, because they only affect the corresponding service classes.
View models abstract the widgets' state and presentation.
View models do not have any reference to the widgets themselves. Rather, they define an interface for publishing updates when something changes.
View models can talk directly to service classes to read or write data, and access other domain-specific APIs.
But unlike service classes, they can hold and modify state, according to some business logic.
View models can also be used to hold local state. This is common when converting a StatefulWidget
into a StatelessWidget
NOTE: View models are completely independent from the UI. View model classes never import Flutter code (e.g.
material.dart
)
Widgets are used to specify how the application UI looks like, and provide callbacks in response to user interaction.
Strictly speaking, we can introduce a distinction:
- pure UI widgets: these are the usual buttons, texts, containers
- logic or presentational widgets: these are used to decide what widget to return, based on some condition (e.g. to return the home page or sign page based on the authentication status of the user).
This project contains a demo app as a practical implementation of this architecture.
The demo app is a time tracking application. It is complex enough to capture the various nuances of state management across multiple features. Here is a preview of the main screens:
After signing in, users can view, create, edit and delete their jobs. For each job they can view, create, edit and delete the corresponding entries.
A separate screen shows a daily breakdown of all jobs, hours worked and pay, along with the totals.
All the data is persisted with Firestore, and is kept in sync across multiple devices.
Riverpod is a rewrite of the popular Provider package, and improves on its weaknesses. It is a natural fit for this app.
Riverpod can be used to create global providers that are not tied to the widget tree, and these can then be accessed by reference. In this sense, Riverpod works more like a service locator.
For example, here are some providers that are created using Riverpod:
// 1
final firebaseAuthProvider =
Provider<FirebaseAuth>((ref) => FirebaseAuth.instance);
// 2
final authStateChangesProvider = StreamProvider<User>(
(ref) => ref.watch(firebaseAuthProvider).authStateChanges());
// 3
final databaseProvider = Provider<FirestoreDatabase?>((ref) {
final auth = ref.watch(authStateChangesProvider);
// we only have a valid DB if the user is signed in
if (auth.data?.value?.uid != null) {
return FirestoreDatabase(uid: auth.data!.value!.uid);
}
return null;
});
As we can see, authStateChangesProvider
depends on firebaseAuthProvider
, and can get access to it using ref.watch
.
Similarly, databaseProvider
depends on authStateChangesProvider
.
One powerful feature of Riverpod is that we can watch a provider's value and rebuild all dependent providers and widgets when the value changes.
An example of this is the databaseProvider
above. This provider's value is rebuilt every time the authStateChangesProvider
's value changes. This is used to return either a FirestoreDatabase
object or null
depending on the authentication state.
Widgets can access these providers with a ScopedReader
, either via Consumer
or ConsumerWidget
.
For example, here is some sample code demonstrating how to use StreamProvider
to read some data from a stream:
final jobStreamProvider =
StreamProvider.autoDispose.family<Job, String>((ref, jobId) {
final database = ref.watch(databaseProvider)!;
return database.jobStream(jobId: jobId);
});
In this case the StreamProvider
can auto-dispose itself when all its listeners unsubscribe. And we're using .family
to read a jobId
parameter that is only known at runtime.
Here's a widget that watches this StreamProvider
and uses it to show some UI based on the stream's latest state (data available / loading / error):
class JobEntriesAppBarTitle extends ConsumerWidget {
const JobEntriesAppBarTitle({required this.job});
final Job job;
@override
Widget build(BuildContext context, WidgetRef ref) {
// 1: watch changes in the stream
final jobAsyncValue = ref.watch(jobStreamProvider(job.id));
// 2: return the correct widget depending on the stream value
return jobAsyncValue.when(
data: (job) => Text(job.name),
loading: () => Container(),
error: (_, __) => Container(),
);
}
}
This widget class is as simple as it can be, as it only needs to watch for changes in the stream (step 1), and return the correct widget depending on the stream value (step 2).
This is great because all the logic for setting up the StreamProvider
lives inside the provider itself, and is completely separate from the UI code.
In addition to the top-level providers and the StreamProvider
s that read data from Firestore, Riverpod is also used to create and configure view models for widgets that require local state.
These view models can hold any app-specific business logic, and if they're based on ChangeNotifier
or StateNotifier
, they can be easily hooked up to their widgets with corresponding providers. See the SignInViewModel and SignInPage widget for an example of this.
Folders are grouped by feature/page. Each feature may define its own models and view models.
Services and routing classes are defined at the root, along with constants and common widgets shared by multiple features.
/lib
/app
/home
/account
/entries
/job_entries
/jobs
/models
/sign_in
/common_widgets
/constants
/routing
/services
This is an arbitrary structure. Choose what works best for your project.
Widgets can subscribe to updates from Firestore data via streams. Equally, write operations can be issued with Future-based APIs.
Here's the entire Database API for the demo app, showing all the supported CRUD operations:
class FirestoreDatabase { // implementation omitted for brevity
Future<void> setJob(Job job); // create / update
Future<void> deleteJob(Job job); // delete
Stream<List<Job>> jobsStream(); // read
Stream<Job> jobStream({required String jobId}); // read
Future<void> setEntry(Entry entry); // create / update
Future<void> deleteEntry(Entry entry); // delete
Stream<List<Entry>> entriesStream({Job job}); // read
}
As shown above, widgets can read these input streams via StreamProvider
s, and use a watch to reactively rebuild the UI.
For convenience, all available collections and documents are listed in a single class:
class APIPath {
static String job(String uid, String jobId) => 'users/$uid/jobs/$jobId';
static String jobs(String uid) => 'users/$uid/jobs';
static String entry(String uid, String entryId) =>
'users/$uid/entries/$entryId';
static String entries(String uid) => 'users/$uid/entries';
}
Domain-level model classes are defined, along with fromMap()
and toMap()
methods for serialization.
These classes are strongly-typed and immutable.
See the FirestoreDatabase and FirestoreService classes for a full picture of how everything fits together.
The app uses named routes, which are defined in a Routes
class:
class AppRoutes {
static const emailPasswordSignInPage = '/email-password-sign-in-page';
static const editJobPage = '/edit-job-page';
static const entryPage = '/entry-page';
}
A AppRouter
is then used to generate all the routes with a switch statement:
class AppRouter {
static Route<dynamic> onGenerateRoute(RouteSettings settings) {
final args = settings.arguments;
switch (settings.name) {
// all cases here
}
}
}
Given a page that needs to be presented inside a route, we can call pushNamed
with the name of the route, and pass all required arguments. If more than one argument is needed, we can use a map:
class EntryPage extends ConsumerStatefulWidget {
const EntryPage({required this.job, this.entry});
final Job job;
final Entry? entry;
static Future<void> show(
{required BuildContext context, required Job job, Entry? entry}) async {
await Navigator.of(context, rootNavigator: true).pushNamed(
AppRoutes.entryPage,
arguments: {
'job': job,
'entry': entry,
},
);
}
@override
_EntryPageState createState() => _EntryPageState();
}
Note: previously the app was using auto_route
, which uses code generation to make routes strongly-typed. This has caused subtle issues, that took some time to investigate. So the project now uses manual routes, which are much more predictable.
To use this project with Firebase, some configuration steps are required.
- Create a new project with the Firebase console.
- Add iOS and Android apps in the Firebase project settings.
- On Android, use
com.example.starter_architecture_flutter_firebase
as the package name. - then, download and copy
google-services.json
intoandroid/app
. - On iOS, use
com.example.starterArchitectureFlutterFirebase
as the bundle ID. - then, download and copy
GoogleService-Info.plist
intoiOS/Runner
, and add it to the Runner target in Xcode. - finally, enable the Email/Password Authentication Sign-in provider in the Firebase Console (Authentication > Sign-in method > Email/Password > Edit > Enable > Save)
See this page for full instructions:
This project now runs on Flutter web.
To test this, add a web app in the Firebase project settings, and export the generated firebaseConfig
variable inside a ./firebase-config.js
file in your project (this file is included in .gitignore
). Example:
export var firebaseConfig = {
apiKey: "<your-api-key>",
authDomain: "<your-auth-domain>",
databaseURL: "<your-database-url>",
projectId: "<your-project-id>",
storageBucket: "<your-storage-bucket>",
messagingSenderId: "<your-messaging-sender-id>",
appId: "<your-app-id>",
measurementId: "<your-measurement-id>"
};
This is then imported in the index.html
file:
<script src="./firebase-config.js"></script>
<!-- https://stackoverflow.com/questions/950087/how-do-i-include-a-javascript-file-in-another-javascript-file -->
<script type="module">
// Your web app's Firebase configuration
import { firebaseConfig } from './firebase-config.js';
// Initialize Firebase
firebase.initializeApp(firebaseConfig);
firebase.analytics();
</script>
firebase_auth
for authenticationcloud_firestore
for the remote databaseflutter_riverpod
for dependency injection and propagating stream values down the widget treerxdart
for combining multiple Firestore collections as neededintl
for currency, date, time formattingmockito
for testingequatable
to reduce boilerplate code in model classes
Also imported from my flutter_core_packages repo:
firestore_service
custom_buttons
alert_dialogs
email_password_sign_in_ui
This project borrows many ideas from my Flutter & Firebase Course, as well as my Reference Authentication Flow with Flutter & Firebase, and takes them to the next level by using Riverpod.
Here are some other GitHub projects that also attempt to formalize a good approach to Flutter development:
- Beyond - An approach to scalable Flutter development
- This starter app that includes many different production app features. Related articles: A Production-Quality Flutter Starter App, and this follow up.
Other relevant articles about app architecture: