Flutter for Android developers

This document is meant for Android developers looking to apply their existing Android knowledge to build mobile apps with Flutter. If you understand the fundamentals of the Android framework then you can use this document as a jump start to Flutter development.

Your Android knowledge and skill set are highly valuable when building with Flutter, because Flutter relies on the mobile operating system for numerous capabilities and configurations. Flutter is a new way to build UIs for mobile, but it has a plugin system to communicate with Android (and iOS) for non-UI tasks. If you're an expert with Android, you don't have to relearn everything to use Flutter.

This document can be used as a cookbook by jumping around and finding questions that are most relevant to your needs.

In Android, the View is the foundation of everything that shows up on the screen. Buttons, toolbars, and inputs, everything is a View. In Flutter, the rough equivalent to a View is a Widget. Widgets don't map exactly to Android views, but while you're getting acquainted with how Flutter works you can think of them as "the way you declare and construct UI".

However, these have a few differences to a View. To start, widgets have a different lifespan: they are immutable and only exist until they need to be changed. Whenever widgets or their state change, Flutter's framework creates a new tree of widget instances. In comparison, an Android view is drawn once and does not redraw until invalidate is called.

Flutter's widgets are lightweight, in part due to their immutability. Because they aren't views themselves, and aren't directly drawing anything, but rather are a description of the UI and its semantics that get "inflated" into actual view objects under the hood.

Flutter includes the Material Components library. These are widgets that implement the Material Design guidelines. Material Design is a flexible design system optimized for all platforms, including iOS.

But Flutter is flexible and expressive enough to implement any design language. For example, on iOS, you can use the Cupertino widgets to produce an interface that looks like Apple's iOS design language.

In Android, you update your views by directly mutating them. However, in Flutter, Widgets are immutable and are not updated directly, instead you have to work with the widget's state.

This is where the concept of Stateful and Stateless widgets comes from. A StatelessWidget is just what it sounds like—a widget with no state information.

StatelessWidgets are useful when the part of the user interface you are describing does not depend on anything other than the configuration information in the object.

For example, in Android, this is similar to placing an ImageView with your logo. The logo is not going to change during runtime, so use a StatelessWidget in Flutter.

If you want to dynamically change the UI based on data received after making an HTTP call or user interaction then you have to work with StatefulWidget and tell the Flutter framework that the widget's State has been updated so it can update that widget.

The important thing to note here is at the core both stateless and stateful widgets behave the same. They rebuild every frame, the difference is the StatefulWidget has a State object that stores state data across frames and restores it.

If you are in doubt, then always remember this rule: if a widget changes (because of user interactions, for example) it's stateful. However, if a widget reacts to change, the containing parent widget can still be stateless if it doesn't itself react to change.

The following example shows how to use a StatelessWidget. A common StatelessWidget is the Text widget. If you look at the implementation of the Text widget you'll find that it subclasses StatelessWidget.

Text(
  'I like Flutter!',
  style: TextStyle(fontWeight: FontWeight.bold),
);

As you can see, the Text Widget has no state information associated with it, it renders what is passed in its constructors and nothing more.

But, what if you want to make "I Like Flutter" change dynamically, for example when clicking a FloatingActionButton?

To achieve this, wrap the Text widget in a StatefulWidget and update it when the user clicks the button.

For example:

import 'package:flutter/material.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});
  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  // Default placeholder text.
  String textToShow = 'I Like Flutter';

  void _updateText() {
    setState(() {
      // Update the text.
      textToShow = 'Flutter is Awesome!';
    });
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: Center(child: Text(textToShow)),
      floatingActionButton: FloatingActionButton(
        onPressed: _updateText,
        tooltip: 'Update Text',
        child: const Icon(Icons.update),
      ),
    );
  }
}

In Android, you write layouts in XML, but in Flutter you write your layouts with a widget tree.

The following example shows how to display a simple widget with padding:

@override
Widget build(BuildContext context) {
  return Scaffold(
    appBar: AppBar(
      title: const Text('Sample App'),
    ),
    body: Center(
      child: ElevatedButton(
        style: ElevatedButton.styleFrom(
          padding: const EdgeInsets.only(left: 20, right: 30),
        ),
        onPressed: () {},
        child: const Text('Hello'),
      ),
    ),
  );
}

You can view some of the layouts that Flutter has to offer in the widget catalog.

In Android, you call addChild() or removeChild() on a parent to dynamically add or remove child views. In Flutter, because widgets are immutable there is no direct equivalent to addChild(). Instead, you can pass a function to the parent that returns a widget, and control that child's creation with a boolean flag.

For example, here is how you can toggle between two widgets when you click on a FloatingActionButton:

import 'package:flutter/material.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});

  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  // Default value for toggle.
  bool toggle = true;
  void _toggle() {
    setState(() {
      toggle = !toggle;
    });
  }

  Widget _getToggleChild() {
    if (toggle) {
      return const Text('Toggle One');
    } else {
      return ElevatedButton(
        onPressed: () {},
        child: const Text('Toggle Two'),
      );
    }
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: Center(
        child: _getToggleChild(),
      ),
      floatingActionButton: FloatingActionButton(
        onPressed: _toggle,
        tooltip: 'Update Text',
        child: const Icon(Icons.update),
      ),
    );
  }
}

In Android, you either create animations using XML, or call the animate() method on a view. In Flutter, animate widgets using the animation library by wrapping widgets inside an animated widget.

In Flutter, use an AnimationController which is an Animation<double> that can pause, seek, stop and reverse the animation. It requires a Ticker that signals when vsync happens, and produces a linear interpolation between 0 and 1 on each frame while it's running. You then create one or more Animations and attach them to the controller.

For example, you might use CurvedAnimation to implement an animation along an interpolated curve. In this sense, the controller is the "master" source of the animation progress and the CurvedAnimation computes the curve that replaces the controller's default linear motion. Like widgets, animations in Flutter work with composition.

When building the widget tree you assign the Animation to an animated property of a widget, such as the opacity of a FadeTransition, and tell the controller to start the animation.

The following example shows how to write a FadeTransition that fades the widget into a logo when you press the FloatingActionButton:

import 'package:flutter/material.dart';

void main() {
  runApp(const FadeAppTest());
}

class FadeAppTest extends StatelessWidget {
  const FadeAppTest({super.key});
  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Fade Demo',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const MyFadeTest(title: 'Fade Demo'),
    );
  }
}

class MyFadeTest extends StatefulWidget {
  const MyFadeTest({super.key, required this.title});

  final String title;
  @override
  State<MyFadeTest> createState() => _MyFadeTest();
}

class _MyFadeTest extends State<MyFadeTest> with TickerProviderStateMixin {
  late AnimationController controller;
  late CurvedAnimation curve;

  @override
  void initState() {
    super.initState();
    controller = AnimationController(
      duration: const Duration(milliseconds: 2000),
      vsync: this,
    );
    curve = CurvedAnimation(
      parent: controller,
      curve: Curves.easeIn,
    );
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: Text(widget.title),
      ),
      body: Center(
        child: FadeTransition(
          opacity: curve,
          child: const FlutterLogo(
            size: 100,
          ),
        ),
      ),
      floatingActionButton: FloatingActionButton(
        tooltip: 'Fade',
        onPressed: () {
          controller.forward();
        },
        child: const Icon(Icons.brush),
      ),
    );
  }
}

For more information, see Animation & Motion widgets, the Animations tutorial, and the Animations overview.

In Android, you would use the Canvas and Drawable to draw images and shapes to the screen. Flutter has a similar Canvas API as well, since it's based on the same low-level rendering engine, Skia. As a result, painting to a canvas in Flutter is a very familiar task for Android developers.

Flutter has two classes that help you draw to the canvas: CustomPaint and CustomPainter, the latter of which implements your algorithm to draw to the canvas.

To learn how to implement a signature painter in Flutter, see Collin's answer on Custom Paint.

import 'package:flutter/material.dart';

void main() => runApp(const MaterialApp(home: DemoApp()));

class DemoApp extends StatelessWidget {
  const DemoApp({super.key});

  @override
  Widget build(BuildContext context) => const Scaffold(body: Signature());
}

class Signature extends StatefulWidget {
  const Signature({super.key});

  @override
  SignatureState createState() => SignatureState();
}

class SignatureState extends State<Signature> {
  List<Offset?> _points = <Offset>[];
  @override
  Widget build(BuildContext context) {
    return GestureDetector(
      onPanUpdate: (details) {
        setState(() {
          RenderBox? referenceBox = context.findRenderObject() as RenderBox;
          Offset localPosition =
              referenceBox.globalToLocal(details.globalPosition);
          _points = List.from(_points)..add(localPosition);
        });
      },
      onPanEnd: (details) => _points.add(null),
      child: CustomPaint(
        painter: SignaturePainter(_points),
        size: Size.infinite,
      ),
    );
  }
}

class SignaturePainter extends CustomPainter {
  SignaturePainter(this.points);
  final List<Offset?> points;
  @override
  void paint(Canvas canvas, Size size) {
    var paint = Paint()
      ..color = Colors.black
      ..strokeCap = StrokeCap.round
      ..strokeWidth = 5;
    for (int i = 0; i < points.length - 1; i++) {
      if (points[i] != null && points[i + 1] != null) {
        canvas.drawLine(points[i]!, points[i + 1]!, paint);
      }
    }
  }

  @override
  bool shouldRepaint(SignaturePainter oldDelegate) =>
      oldDelegate.points != points;
}

In Android, you typically subclass View, or use a pre-existing view, to override and implement methods that achieve the desired behavior.

In Flutter, build a custom widget by composing smaller widgets (instead of extending them). It is somewhat similar to implementing a custom ViewGroup in Android, where all the building blocks are already existing, but you provide a different behavior—for example, custom layout logic.

For example, how do you build a CustomButton that takes a label in the constructor? Create a CustomButton that composes a ElevatedButton with a label, rather than by extending ElevatedButton:

class CustomButton extends StatelessWidget {
  final String label;

  const CustomButton(this.label, {super.key});

  @override
  Widget build(BuildContext context) {
    return ElevatedButton(
      onPressed: () {},
      child: Text(label),
    );
  }
}

Then use CustomButton, just as you'd use any other Flutter widget:

@override
Widget build(BuildContext context) {
  return const Center(
    child: CustomButton('Hello'),
  );
}

In Android, there are two main use cases for Intents: navigating between Activities, and communicating with components. Flutter, on the other hand, does not have the concept of intents, although you can still start intents through native integrations (using a plugin).

Flutter doesn't really have a direct equivalent to activities and fragments; rather, in Flutter you navigate between screens, using a Navigator and Routes, all within the same Activity.

A Route is an abstraction for a "screen" or "page" of an app, and a Navigator is a widget that manages routes. A route roughly maps to an Activity, but it does not carry the same meaning. A navigator can push and pop routes to move from screen to screen. Navigators work like a stack on which you can push() new routes you want to navigate to, and from which you can pop() routes when you want to "go back".

In Android, you declare your activities inside the app's AndroidManifest.xml.

In Flutter, you have a couple options to navigate between pages:

• Specify a Map of route names. (using MaterialApp)
• Directly navigate to a route. (using WidgetsApp)

The following example builds a Map.

void main() {
  runApp(MaterialApp(
    home: const MyAppHome(), // Becomes the route named '/'.
    routes: <String, WidgetBuilder>{
      '/a': (context) => const MyPage(title: 'page A'),
      '/b': (context) => const MyPage(title: 'page B'),
      '/c': (context) => const MyPage(title: 'page C'),
    },
  ));
}

Navigate to a route by pushing its name to the Navigator.

Navigator.of(context).pushNamed('/b');

The other popular use-case for Intents is to call external components such as a Camera or File picker. For this, you would need to create a native platform integration (or use an existing plugin).

To learn how to build a native platform integration, see developing packages and plugins.

Flutter can handle incoming intents from Android by directly talking to the Android layer and requesting the data that was shared.

The following example registers a text share intent filter on the native activity that runs our Flutter code, so other apps can share text with our Flutter app.

The basic flow implies that we first handle the shared text data on the Android native side (in our Activity), and then wait until Flutter requests for the data to provide it using a MethodChannel.

First, register the intent filter for all intents in AndroidManifest.xml:

<activity
  android:name=".MainActivity"
  android:launchMode="singleTop"
  android:theme="@style/LaunchTheme"
  android:configChanges="orientation|keyboardHidden|keyboard|screenSize|locale|layoutDirection"
  android:hardwareAccelerated="true"
  android:windowSoftInputMode="adjustResize">
  <!-- ... -->
  <intent-filter>
    <action android:name="android.intent.action.SEND" />
    <category android:name="android.intent.category.DEFAULT" />
    <data android:mimeType="text/plain" />
  </intent-filter>
</activity>

Then in MainActivity, handle the intent, extract the text that was shared from the intent, and hold onto it. When Flutter is ready to process, it requests the data using a platform channel, and it's sent across from the native side:

package com.example.shared;

import android.content.Intent;
import android.os.Bundle;

import androidx.annotation.NonNull;

import io.flutter.plugin.common.MethodChannel;
import io.flutter.embedding.android.FlutterActivity;
import io.flutter.embedding.engine.FlutterEngine;
import io.flutter.plugins.GeneratedPluginRegistrant;

public class MainActivity extends FlutterActivity {

  private String sharedText;
  private static final String CHANNEL = "app.channel.shared.data";

  @Override
  protected void onCreate(Bundle savedInstanceState) {
    super.onCreate(savedInstanceState);
    Intent intent = getIntent();
    String action = intent.getAction();
    String type = intent.getType();

    if (Intent.ACTION_SEND.equals(action) && type != null) {
      if ("text/plain".equals(type)) {
        handleSendText(intent); // Handle text being sent
      }
    }
  }

  @Override
  public void configureFlutterEngine(@NonNull FlutterEngine flutterEngine) {
      GeneratedPluginRegistrant.registerWith(flutterEngine);

      new MethodChannel(flutterEngine.getDartExecutor().getBinaryMessenger(), CHANNEL)
              .setMethodCallHandler(
                      (call, result) -> {
                          if (call.method.contentEquals("getSharedText")) {
                              result.success(sharedText);
                              sharedText = null;
                          }
                      }
              );
  }

  void handleSendText(Intent intent) {
    sharedText = intent.getStringExtra(Intent.EXTRA_TEXT);
  }
}

Finally, request the data from the Flutter side when the widget is rendered:

import 'package:flutter/material.dart';
import 'package:flutter/services.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});

  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample Shared App Handler',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  static const platform = MethodChannel('app.channel.shared.data');
  String dataShared = 'No data';

  @override
  void initState() {
    super.initState();
    getSharedText();
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(body: Center(child: Text(dataShared)));
  }

  Future<void> getSharedText() async {
    var sharedData = await platform.invokeMethod('getSharedText');
    if (sharedData != null) {
      setState(() {
        dataShared = sharedData;
      });
    }
  }
}

The Navigator class handles routing in Flutter and is used to get a result back from a route that you have pushed on the stack. This is done by awaiting on the Future returned by push().

For example, to start a location route that lets the user select their location, you could do the following:

Object? coordinates = await Navigator.of(context).pushNamed('/location');

And then, inside your location route, once the user has selected their location you can pop the stack with the result:

Navigator.of(context).pop({'lat': 43.821757, 'long': -79.226392});

Dart has a single-threaded execution model, with support for Isolates (a way to run Dart code on another thread), an event loop, and asynchronous programming. Unless you spawn an Isolate, your Dart code runs in the main UI thread and is driven by an event loop. Flutter's event loop is equivalent to Android's main Looper—that is, the Looper that is attached to the main thread.

Dart's single-threaded model doesn't mean you need to run everything as a blocking operation that causes the UI to freeze. Unlike Android, which requires you to keep the main thread free at all times, in Flutter, use the asynchronous facilities that the Dart language provides, such as async/await, to perform asynchronous work. You might be familiar with the async/await paradigm if you've used it in C#, Javascript, or if you have used Kotlin's coroutines.

For example, you can run network code without causing the UI to hang by using async/await and letting Dart do the heavy lifting:

Future<void> loadData() async {
  var dataURL = Uri.parse('https://jsonplaceholder.typicode.com/posts');
  http.Response response = await http.get(dataURL);
  setState(() {
    widgets = jsonDecode(response.body);
  });
}

Once the awaited network call is done, update the UI by calling setState(), which triggers a rebuild of the widget subtree and updates the data.

The following example loads data asynchronously and displays it in a ListView:

import 'dart:convert';

import 'package:flutter/material.dart';
import 'package:http/http.dart' as http;

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  List widgets = [];

  @override
  void initState() {
    super.initState();
    loadData();
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: ListView.builder(
        itemCount: widgets.length,
        itemBuilder: (context, position) {
          return getRow(position);
        },
      ),
    );
  }

  Widget getRow(int i) {
    return Padding(
      padding: const EdgeInsets.all(10),
      child: Text("Row ${widgets[i]["title"]}"),
    );
  }

  Future<void> loadData() async {
    var dataURL = Uri.parse('https://jsonplaceholder.typicode.com/posts');
    http.Response response = await http.get(dataURL);
    setState(() {
      widgets = jsonDecode(response.body);
    });
  }
}

Refer to the next section for more information on doing work in the background, and how Flutter differs from Android.

In Android, when you want to access a network resource you would typically move to a background thread and do the work, as to not block the main thread, and avoid ANRs. For example, you might be using an AsyncTask, a LiveData, an IntentService, a JobScheduler job, or an RxJava pipeline with a scheduler that works on background threads.

Since Flutter is single threaded and runs an event loop (like Node.js), you don't have to worry about thread management or spawning background threads. If you're doing I/O-bound work, such as disk access or a network call, then you can safely use async/await and you're all set. If, on the other hand, you need to do computationally intensive work that keeps the CPU busy, you want to move it to an Isolate to avoid blocking the event loop, like you would keep any sort of work out of the main thread in Android.

For I/O-bound work, declare the function as an async function, and await on long-running tasks inside the function:

Future<void> loadData() async {
  var dataURL = Uri.parse('https://jsonplaceholder.typicode.com/posts');
  http.Response response = await http.get(dataURL);
  setState(() {
    widgets = jsonDecode(response.body);
  });
}

This is how you would typically do network or database calls, which are both I/O operations.

On Android, when you extend AsyncTask, you typically override 3 methods, onPreExecute(), doInBackground() and onPostExecute(). There is no equivalent in Flutter, since you await on a long-running function, and Dart's event loop takes care of the rest.

However, there are times when you might be processing a large amount of data and your UI hangs. In Flutter, use Isolates to take advantage of multiple CPU cores to do long-running or computationally intensive tasks.

Isolates are separate execution threads that do not share any memory with the main execution memory heap. This means you can't access variables from the main thread, or update your UI by calling setState(). Unlike Android threads, Isolates are true to their name, and cannot share memory (in the form of static fields, for example).

The following example shows, in a simple isolate, how to share data back to the main thread to update the UI.

Future<void> loadData() async {
  ReceivePort receivePort = ReceivePort();
  await Isolate.spawn(dataLoader, receivePort.sendPort);

  // The 'echo' isolate sends its SendPort as the first message.
  SendPort sendPort = await receivePort.first;

  List msg = await sendReceive(
    sendPort,
    'https://jsonplaceholder.typicode.com/posts',
  );

  setState(() {
    widgets = msg;
  });
}

// The entry point for the isolate.
static Future<void> dataLoader(SendPort sendPort) async {
  // Open the ReceivePort for incoming messages.
  ReceivePort port = ReceivePort();

  // Notify any other isolates what port this isolate listens to.
  sendPort.send(port.sendPort);

  await for (var msg in port) {
    String data = msg[0];
    SendPort replyTo = msg[1];

    String dataURL = data;
    http.Response response = await http.get(Uri.parse(dataURL));
    // Lots of JSON to parse
    replyTo.send(jsonDecode(response.body));
  }
}

Future sendReceive(SendPort port, msg) {
  ReceivePort response = ReceivePort();
  port.send([msg, response.sendPort]);
  return response.first;
}

Here, dataLoader() is the Isolate that runs in its own separate execution thread. In the isolate you can perform more CPU intensive processing (parsing a big JSON, for example), or perform computationally intensive math, such as encryption or signal processing.

You can run the full example below:

import 'dart:async';
import 'dart:convert';
import 'dart:isolate';

import 'package:flutter/material.dart';
import 'package:http/http.dart' as http;

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});

  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  List widgets = [];

  @override
  void initState() {
    super.initState();
    loadData();
  }

  Widget getBody() {
    bool showLoadingDialog = widgets.isEmpty;
    if (showLoadingDialog) {
      return getProgressDialog();
    } else {
      return getListView();
    }
  }

  Widget getProgressDialog() {
    return const Center(child: CircularProgressIndicator());
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: getBody(),
    );
  }

  ListView getListView() {
    return ListView.builder(
      itemCount: widgets.length,
      itemBuilder: (context, position) {
        return getRow(position);
      },
    );
  }

  Widget getRow(int i) {
    return Padding(
      padding: const EdgeInsets.all(10),
      child: Text("Row ${widgets[i]["title"]}"),
    );
  }

  Future<void> loadData() async {
    ReceivePort receivePort = ReceivePort();
    await Isolate.spawn(dataLoader, receivePort.sendPort);

    // The 'echo' isolate sends its SendPort as the first message.
    SendPort sendPort = await receivePort.first;

    List msg = await sendReceive(
      sendPort,
      'https://jsonplaceholder.typicode.com/posts',
    );

    setState(() {
      widgets = msg;
    });
  }

  // The entry point for the isolate.
  static Future<void> dataLoader(SendPort sendPort) async {
    // Open the ReceivePort for incoming messages.
    ReceivePort port = ReceivePort();

    // Notify any other isolates what port this isolate listens to.
    sendPort.send(port.sendPort);

    await for (var msg in port) {
      String data = msg[0];
      SendPort replyTo = msg[1];

      String dataURL = data;
      http.Response response = await http.get(Uri.parse(dataURL));
      // Lots of JSON to parse
      replyTo.send(jsonDecode(response.body));
    }
  }

  Future sendReceive(SendPort port, msg) {
    ReceivePort response = ReceivePort();
    port.send([msg, response.sendPort]);
    return response.first;
  }
}

Making a network call in Flutter is easy when you use the popular http package.

While the http package doesn't have every feature found in OkHttp, it abstracts away much of the networking that you would normally implement yourself, making it a simple way to make network calls.

To add the http package as a dependency, run flutter pub add:

$ flutter pub add http

To make a network call, call await on the async function http.get():

import 'dart:developer' as developer;
import 'package:http/http.dart' as http;

Future<void> loadData() async {
  var dataURL = Uri.parse('https://jsonplaceholder.typicode.com/posts');
  http.Response response = await http.get(dataURL);
  developer.log(response.body);
}

In Android you would typically show a ProgressBar view in your UI while executing a long-running task on a background thread.

In Flutter, use a ProgressIndicator widget. Show the progress programmatically by controlling when it's rendered through a boolean flag. Tell Flutter to update its state before your long-running task starts, and hide it after it ends.

In the following example, the build function is separated into three different functions. If showLoadingDialog is true (when widgets.isEmpty), then render the ProgressIndicator. Otherwise, render the ListView with the data returned from a network call.

import 'dart:convert';

import 'package:flutter/material.dart';
import 'package:http/http.dart' as http;

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});

  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  List widgets = [];

  @override
  void initState() {
    super.initState();
    loadData();
  }

  Widget getBody() {
    bool showLoadingDialog = widgets.isEmpty;
    if (showLoadingDialog) {
      return getProgressDialog();
    } else {
      return getListView();
    }
  }

  Widget getProgressDialog() {
    return const Center(child: CircularProgressIndicator());
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: getBody(),
    );
  }

  ListView getListView() {
    return ListView.builder(
      itemCount: widgets.length,
      itemBuilder: (context, position) {
        return getRow(position);
      },
    );
  }

  Widget getRow(int i) {
    return Padding(
      padding: const EdgeInsets.all(10),
      child: Text("Row ${widgets[i]["title"]}"),
    );
  }

  Future<void> loadData() async {
    var dataURL = Uri.parse('https://jsonplaceholder.typicode.com/posts');
    http.Response response = await http.get(dataURL);
    setState(() {
      widgets = jsonDecode(response.body);
    });
  }
}

While Android treats resources and assets as distinct items, Flutter apps have only assets. All resources that would live in the res/drawable-* folders on Android, are placed in an assets folder for Flutter.

Flutter follows a simple density-based format like iOS. Assets might be 1.0x, 2.0x, 3.0x, or any other multiplier. Flutter doesn't have dps but there are logical pixels, which are basically the same as device-independent pixels. Flutter's devicePixelRatio expresses the ratio of physical pixels in a single logical pixel.

The equivalent to Android's density buckets are:

Assets are located in any arbitrary folder—Flutter has no predefined folder structure. You declare the assets (with location) in the pubspec.yaml file, and Flutter picks them up.

Assets stored in the native asset folder are accessed on the native side using Android's AssetManager:

val flutterAssetStream = assetManager.open("flutter_assets/assets/my_flutter_asset.png")

Flutter can't access native resources or assets.

To add a new image asset called my_icon.png to our Flutter project, for example, and deciding that it should live in a folder we arbitrarily called images, you would put the base image (1.0x) in the images folder, and all the other variants in sub-folders called with the appropriate ratio multiplier:

images/my_icon.png       // Base: 1.0x image
images/2.0x/my_icon.png  // 2.0x image
images/3.0x/my_icon.png  // 3.0x image

Next, you'll need to declare these images in your pubspec.yaml file:

assets:
 - images/my_icon.jpeg

You can then access your images using AssetImage:

AssetImage('images/my_icon.jpeg')

or directly in an Image widget:

@override
Widget build(BuildContext context) {
  return Image.asset('images/my_image.png');
}

Flutter currently doesn't have a dedicated resources-like system for strings. The best and recommended practice is to hold your strings in a .arb file as key-value pairs For example:

{
   "@@locale": "en",
   "hello":"Hello {userName}",
   "@hello":{
      "description":"A message with a single parameter",
      "placeholders":{
         "userName":{
            "type":"String",
            "example":"Bob"
         }
      }
   }
}

Then in your code, you can access your strings as such:

Text(AppLocalizations.of(context)!.hello('John'));

Flutter has basic support for accessibility on Android, though this feature is a work in progress.

See Internationalizing Flutter apps for more information on this.

In Android, you add dependencies by adding to your Gradle build script. Flutter uses Dart's own build system, and the Pub package manager. The tools delegate the building of the native Android and iOS wrapper apps to the respective build systems.

While there are Gradle files under the android folder in your Flutter project, only use these if you are adding native dependencies needed for per-platform integration. In general, use pubspec.yaml to declare external dependencies to use in Flutter. A good place to find Flutter packages is pub.dev.

In Android, an Activity represents a single focused thing the user can do. A Fragment represents a behavior or a portion of user interface. Fragments are a way to modularize your code, compose sophisticated user interfaces for larger screens, and help scale your application UI. In Flutter, both of these concepts fall under the umbrella of Widgets.

To learn more about the UI for building Activities and Fragments, see the community-contributed Medium article, Flutter for Android Developers: How to design Activity UI in Flutter.

As mentioned in the Intents section, screens in Flutter are represented by Widgets since everything is a widget in Flutter. Use a Navigator to move between different Routes that represent different screens or pages, or perhaps different states or renderings of the same data.

In Android, you can override methods from the Activity to capture lifecycle methods for the activity itself, or register ActivityLifecycleCallbacks on the Application. In Flutter, you have neither concept, but you can instead listen to lifecycle events by hooking into the WidgetsBinding observer and listening to the didChangeAppLifecycleState() change event.

The observable lifecycle events are:

• detached — The application is still hosted on a flutter engine but is detached from any host views.
• inactive — The application is in an inactive state and is not receiving user input.
• paused — The application is not currently visible to the user, not responding to user input, and running in the background. This is equivalent to onPause() in Android.
• resumed — The application is visible and responding to user input. This is equivalent to onPostResume() in Android.

For more details on the meaning of these states, see the AppLifecycleStatus documentation.

As you might have noticed, only a small minority of the Activity lifecycle events are available; while FlutterActivity does capture almost all the activity lifecycle events internally and send them over to the Flutter engine, they're mostly shielded away from you. Flutter takes care of starting and stopping the engine for you, and there is little reason for needing to observe the activity lifecycle on the Flutter side in most cases. If you need to observe the lifecycle to acquire or release any native resources, you should likely be doing it from the native side, at any rate.

Here's an example of how to observe the lifecycle status of the containing activity:

import 'package:flutter/widgets.dart';

class LifecycleWatcher extends StatefulWidget {
  const LifecycleWatcher({super.key});

  @override
  State<LifecycleWatcher> createState() => _LifecycleWatcherState();
}

class _LifecycleWatcherState extends State<LifecycleWatcher>
    with WidgetsBindingObserver {
  AppLifecycleState? _lastLifecycleState;

  @override
  void initState() {
    super.initState();
    WidgetsBinding.instance.addObserver(this);
  }

  @override
  void dispose() {
    WidgetsBinding.instance.removeObserver(this);
    super.dispose();
  }

  @override
  void didChangeAppLifecycleState(AppLifecycleState state) {
    setState(() {
      _lastLifecycleState = state;
    });
  }

  @override
  Widget build(BuildContext context) {
    if (_lastLifecycleState == null) {
      return const Text(
        'This widget has not observed any lifecycle changes.',
        textDirection: TextDirection.ltr,
      );
    }

    return Text(
      'The most recent lifecycle state this widget observed was: $_lastLifecycleState.',
      textDirection: TextDirection.ltr,
    );
  }
}

void main() {
  runApp(const Center(child: LifecycleWatcher()));
}

In Android, a LinearLayout is used to lay your widgets out linearly—either horizontally or vertically. In Flutter, use the Row or Column widgets to achieve the same result.

If you notice the two code samples are identical with the exception of the "Row" and "Column" widget. The children are the same and this feature can be exploited to develop rich layouts that can change overtime with the same children.

@override
Widget build(BuildContext context) {
  return const Row(
    mainAxisAlignment: MainAxisAlignment.center,
    children: <Widget>[
      Text('Row One'),
      Text('Row Two'),
      Text('Row Three'),
      Text('Row Four'),
    ],
  );
}

@override
Widget build(BuildContext context) {
  return const Column(
    mainAxisAlignment: MainAxisAlignment.center,
    children: <Widget>[
      Text('Column One'),
      Text('Column Two'),
      Text('Column Three'),
      Text('Column Four'),
    ],
  );
}

To learn more about building linear layouts, see the community-contributed Medium article Flutter for Android Developers: How to design LinearLayout in Flutter.

A RelativeLayout lays your widgets out relative to each other. In Flutter, there are a few ways to achieve the same result.

You can achieve the result of a RelativeLayout by using a combination of Column, Row, and Stack widgets. You can specify rules for the widgets constructors on how the children are laid out relative to the parent.

For a good example of building a RelativeLayout in Flutter, see Collin's answer on StackOverflow.

In Android, use a ScrollView to lay out your widgets—if the user's device has a smaller screen than your content, it scrolls.

In Flutter, the easiest way to do this is using the ListView widget. This might seem like overkill coming from Android, but in Flutter a ListView widget is both a ScrollView and an Android ListView.

@override
Widget build(BuildContext context) {
  return ListView(
    children: const <Widget>[
      Text('Row One'),
      Text('Row Two'),
      Text('Row Three'),
      Text('Row Four'),
    ],
  );
}

FlutterView handles the config change if AndroidManifest.xml contains:

android:configChanges="orientation|screenSize"

In Android, you can attach onClick to views such as button by calling the method 'setOnClickListener'.

In Flutter there are two ways of adding touch listeners:

1. If the Widget supports event detection, pass a function to it and handle it in the function. For example, the ElevatedButton has an onPressed parameter:

@override
Widget build(BuildContext context) {
  return ElevatedButton(
    onPressed: () {
      developer.log('click');
    },
    child: const Text('Button'),
  );
}

2. If the Widget doesn't support event detection, wrap the widget in a GestureDetector and pass a function to the onTap parameter.

class SampleTapApp extends StatelessWidget {
  const SampleTapApp({super.key});

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      body: Center(
        child: GestureDetector(
          onTap: () {
            developer.log('tap');
          },
          child: const FlutterLogo(
            size: 200,
          ),
        ),
      ),
    );
  }
}

Using the GestureDetector, you can listen to a wide range of Gestures such as:

• Tap

  • onTapDown - A pointer that might cause a tap has contacted the screen at a particular location.
  • onTapUp - A pointer that triggers a tap has stopped contacting the screen at a particular location.
  • onTap - A tap has occurred.
  • onTapCancel - The pointer that previously triggered the onTapDown won't cause a tap.

• Double tap

  • onDoubleTap - The user tapped the screen at the same location twice in quick succession.

• Long press

  • onLongPress - A pointer has remained in contact with the screen at the same location for a long period of time.

• Vertical drag

  • onVerticalDragStart - A pointer has contacted the screen and might begin to move vertically.
  • onVerticalDragUpdate - A pointer in contact with the screen has moved further in the vertical direction.
  • onVerticalDragEnd - A pointer that was previously in contact with the screen and moving vertically is no longer in contact with the screen and was moving at a specific velocity when it stopped contacting the screen.

• Horizontal drag

  • onHorizontalDragStart - A pointer has contacted the screen and might begin to move horizontally.
  • onHorizontalDragUpdate - A pointer in contact with the screen has moved further in the horizontal direction.
  • onHorizontalDragEnd - A pointer that was previously in contact with the screen and moving horizontally is no longer in contact with the screen and was moving at a specific velocity when it stopped contacting the screen.

The following example shows a GestureDetector that rotates the Flutter logo on a double tap:

class SampleApp extends StatefulWidget {
  const SampleApp({super.key});

  @override
  State<SampleApp> createState() => _SampleAppState();
}

class _SampleAppState extends State<SampleApp>
    with SingleTickerProviderStateMixin {
  late AnimationController controller;
  late CurvedAnimation curve;

  @override
  void initState() {
    super.initState();
    controller = AnimationController(
      vsync: this,
      duration: const Duration(milliseconds: 2000),
    );
    curve = CurvedAnimation(
      parent: controller,
      curve: Curves.easeIn,
    );
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      body: Center(
        child: GestureDetector(
          onDoubleTap: () {
            if (controller.isCompleted) {
              controller.reverse();
            } else {
              controller.forward();
            }
          },
          child: RotationTransition(
            turns: curve,
            child: const FlutterLogo(
              size: 200,
            ),
          ),
        ),
      ),
    );
  }
}

The equivalent to a ListView in Flutter is … a ListView!

In an Android ListView, you create an adapter and pass it into the ListView, which renders each row with what your adapter returns. However, you have to make sure you recycle your rows, otherwise, you get all sorts of crazy visual glitches and memory issues.

Due to Flutter's immutable widget pattern, you pass a list of widgets to your ListView, and Flutter takes care of making sure that scrolling is fast and smooth.

import 'package:flutter/material.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});
  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: ListView(children: _getListData()),
    );
  }

  List<Widget> _getListData() {
    List<Widget> widgets = [];
    for (int i = 0; i < 100; i++) {
      widgets.add(Padding(
        padding: const EdgeInsets.all(10),
        child: Text('Row $i'),
      ));
    }
    return widgets;
  }
}

In Android, the ListView has a method to find out which item was clicked, 'onItemClickListener'. In Flutter, use the touch handling provided by the passed-in widgets.

import 'dart:developer' as developer;

import 'package:flutter/material.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});
  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: ListView(children: _getListData()),
    );
  }

  List<Widget> _getListData() {
    List<Widget> widgets = [];
    for (int i = 0; i < 100; i++) {
      widgets.add(
        GestureDetector(
          onTap: () {
            developer.log('row tapped');
          },
          child: Padding(
            padding: const EdgeInsets.all(10),
            child: Text('Row $i'),
          ),
        ),
      );
    }
    return widgets;
  }
}

On Android, you update the adapter and call notifyDataSetChanged.

In Flutter, if you were to update the list of widgets inside a setState(), you would quickly see that your data did not change visually. This is because when setState() is called, the Flutter rendering engine looks at the widget tree to see if anything has changed. When it gets to your ListView, it performs a == check, and determines that the two ListViews are the same. Nothing has changed, so no update is required.

For a simple way to update your ListView, create a new List inside of setState(), and copy the data from the old list to the new list. While this approach is simple, it is not recommended for large data sets, as shown in the next example.

import 'dart:developer' as developer;

import 'package:flutter/material.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});
  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  List<Widget> widgets = [];

  @override
  void initState() {
    super.initState();
    for (int i = 0; i < 100; i++) {
      widgets.add(getRow(i));
    }
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: ListView(children: widgets),
    );
  }

  Widget getRow(int i) {
    return GestureDetector(
      onTap: () {
        setState(() {
          widgets = List.from(widgets);
          widgets.add(getRow(widgets.length));
          developer.log('row $i');
        });
      },
      child: Padding(
        padding: const EdgeInsets.all(10),
        child: Text('Row $i'),
      ),
    );
  }
}

The recommended, efficient, and effective way to build a list uses a ListView.Builder. This method is great when you have a dynamic List or a List with very large amounts of data. This is essentially the equivalent of RecyclerView on Android, which automatically recycles list elements for you:

import 'dart:developer' as developer;

import 'package:flutter/material.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});
  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  List<Widget> widgets = [];

  @override
  void initState() {
    super.initState();
    for (int i = 0; i < 100; i++) {
      widgets.add(getRow(i));
    }
  }

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: ListView.builder(
        itemCount: widgets.length,
        itemBuilder: (context, position) {
          return getRow(position);
        },
      ),
    );
  }

  Widget getRow(int i) {
    return GestureDetector(
      onTap: () {
        setState(() {
          widgets.add(getRow(widgets.length));
          developer.log('row $i');
        });
      },
      child: Padding(
        padding: const EdgeInsets.all(10),
        child: Text('Row $i'),
      ),
    );
  }
}

Instead of creating a "ListView", create a ListView.builder that takes two key parameters: the initial length of the list, and an ItemBuilder function.

The ItemBuilder function is similar to the getView function in an Android adapter; it takes a position, and returns the row you want rendered at that position.

Finally, but most importantly, notice that the onTap() function doesn't recreate the list anymore, but instead .adds to it.

In Android SDK (as of Android O), you create a Font resource file and pass it into the FontFamily param for your TextView.

In Flutter, place the font file in a folder and reference it in the pubspec.yaml file, similar to how you import images.

fonts:
   - family: MyCustomFont
     fonts:
       - asset: fonts/MyCustomFont.ttf
       - style: italic

Then assign the font to your Text widget:

@override
Widget build(BuildContext context) {
  return Scaffold(
    appBar: AppBar(
      title: const Text('Sample App'),
    ),
    body: const Center(
      child: Text(
        'This is a custom font text',
        style: TextStyle(fontFamily: 'MyCustomFont'),
      ),
    ),
  );
}

Along with fonts, you can customize other styling elements on a Text widget. The style parameter of a Text widget takes a TextStyle object, where you can customize many parameters, such as:

• color
• decoration
• decorationColor
• decorationStyle
• fontFamily
• fontSize
• fontStyle
• fontWeight
• hashCode
• height
• inherit
• letterSpacing
• textBaseline
• wordSpacing

For more information on using Forms, see Retrieve the value of a text field, from the Flutter cookbook.

In Flutter, you can easily show a "hint" or a placeholder text for your input by adding an InputDecoration object to the decoration constructor parameter for the Text Widget.

Center(
  child: TextField(
    decoration: InputDecoration(hintText: 'This is a hint'),
  ),
)

Just as you would with a "hint", pass an InputDecoration object to the decoration constructor for the Text widget.

However, you don't want to start off by showing an error. Instead, when the user has entered invalid data, update the state, and pass a new InputDecoration object.

import 'package:flutter/material.dart';

void main() {
  runApp(const SampleApp());
}

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});
  // This widget is the root of your application.
  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
      ),
      home: const SampleAppPage(),
    );
  }
}

class SampleAppPage extends StatefulWidget {
  const SampleAppPage({super.key});

  @override
  State<SampleAppPage> createState() => _SampleAppPageState();
}

class _SampleAppPageState extends State<SampleAppPage> {
  String? _errorText;

  @override
  Widget build(BuildContext context) {
    return Scaffold(
      appBar: AppBar(
        title: const Text('Sample App'),
      ),
      body: Center(
        child: TextField(
          onSubmitted: (text) {
            setState(() {
              if (!isEmail(text)) {
                _errorText = 'Error: This is not an email';
              } else {
                _errorText = null;
              }
            });
          },
          decoration: InputDecoration(
            hintText: 'This is a hint',
            errorText: _getErrorText(),
          ),
        ),
      ),
    );
  }

  String? _getErrorText() {
    return _errorText;
  }

  bool isEmail(String em) {
    String emailRegexp =
        r'^(([^<>()[\]\\.,;:\s@\"]+(\.[^<>()[\]\\.,;:\s@\"]+)*)|'
        r'(\".+\"))@((\[[0-9]{1,3}\.[0-9]{1,3}\.[0-9]{1,3}\.[0-9]{1,3}\])|'
        r'(([a-zA-Z\-0-9]+\.)+[a-zA-Z]{2,}))$';

    RegExp regExp = RegExp(emailRegexp);

    return regExp.hasMatch(em);
  }
}

Use the geolocator community plugin.

The image_picker plugin is popular for accessing the camera.

To Log in with Facebook, use the flutter_facebook_login community plugin.

Most Firebase functions are covered by first party plugins. These plugins are first-party integrations, maintained by the Flutter team:

• google_mobile_ads for Google Mobile Ads for Flutter
• firebase_analytics for Firebase Analytics
• firebase_auth for Firebase Auth
• firebase_database for Firebase RTDB
• firebase_storage for Firebase Cloud Storage
• firebase_messaging for Firebase Messaging (FCM)
• flutter_firebase_ui for quick Firebase Auth integrations (Facebook, Google, Twitter and email)
• cloud_firestore for Firebase Cloud Firestore

You can also find some third-party Firebase plugins on pub.dev that cover areas not directly covered by the first-party plugins.

If there is platform-specific functionality that Flutter or its community Plugins are missing, you can build your own following the developing packages and plugins page.

Flutter's plugin architecture, in a nutshell, is much like using an Event bus in Android: you fire off a message and let the receiver process and emit a result back to you. In this case, the receiver is code running on the native side on Android or iOS.

If you use the NDK in your current Android application and want your Flutter application to take advantage of your native libraries then it's possible by building a custom plugin.

Your custom plugin first talks to your Android app, where you call your native functions over JNI. Once a response is ready, send a message back to Flutter and render the result.

Calling native code directly from Flutter is currently not supported.

Out of the box, Flutter comes with a beautiful implementation of Material Design, which takes care of a lot of styling and theming needs that you would typically do. Unlike Android where you declare themes in XML and then assign it to your application using AndroidManifest.xml, in Flutter you declare themes in the top level widget.

To take full advantage of Material Components in your app, you can declare a top level widget MaterialApp as the entry point to your application. MaterialApp is a convenience widget that wraps a number of widgets that are commonly required for applications implementing Material Design. It builds upon a WidgetsApp by adding Material specific functionality.

You can also use a WidgetsApp as your app widget, which provides some of the same functionality, but is not as rich as MaterialApp.

To customize the colors and styles of any child components, pass a ThemeData object to the MaterialApp widget. For example, in the code below, the color scheme from seed is set to deepPurple and text selection color is red.

import 'package:flutter/material.dart';

class SampleApp extends StatelessWidget {
  const SampleApp({super.key});

  @override
  Widget build(BuildContext context) {
    return MaterialApp(
      title: 'Sample App',
      theme: ThemeData(
        colorScheme: ColorScheme.fromSeed(seedColor: Colors.deepPurple),
        textSelectionTheme:
            const TextSelectionThemeData(selectionColor: Colors.red),
      ),
      home: const SampleAppPage(),
    );
  }
}

In Android, you can store a small collection of key-value pairs using the SharedPreferences API.

In Flutter, access this functionality using the Shared_Preferences plugin. This plugin wraps the functionality of both Shared Preferences and NSUserDefaults (the iOS equivalent).

import 'dart:async';
import 'package:flutter/material.dart';

import 'package:shared_preferences/shared_preferences.dart';

void main() {
  runApp(
    const MaterialApp(
      home: Scaffold(
        body: Center(
          child: ElevatedButton(
            onPressed: _incrementCounter,
            child: Text('Increment Counter'),
          ),
        ),
      ),
    ),
  );
}

Future<void> _incrementCounter() async {
  SharedPreferences prefs = await SharedPreferences.getInstance();
  int counter = (prefs.getInt('counter') ?? 0) + 1;
  await prefs.setInt('counter', counter);
}

In Android, you use SQLite to store structured data that you can query using SQL.

In Flutter, for macOS, Android, or iOS, access this functionality using the SQFlite plugin.

Use the DevTools suite for debugging Flutter or Dart apps.

DevTools includes support for profiling, examining the heap, inspecting the widget tree, logging diagnostics, debugging, observing executed lines of code, debugging memory leaks and memory fragmentation. For more information, check out the DevTools documentation.

In Android, you use Firebase Cloud Messaging to set up push notifications for your app.

In Flutter, access this functionality using the Firebase Messaging plugin. For more information on using the Firebase Cloud Messaging API, see the firebase_messaging plugin documentation.