Flutter for React Native developers
- Introduction to Dart for JavaScript Developers
- The basics
- Project structure and resources
- Flutter widgets
- Views
- Layouts
- Styling
- State management
- Props
- Local storage
- Routing
- Gesture detection and touch event handling
- Making HTTP network requests
- Form input
- Platform-specific code
- Debugging
- Animation
- React Native and Flutter widget equivalent components
This document is for React Native (RN) developers looking to apply their existing RN knowledge to build mobile apps with Flutter. If you understand the fundamentals of the RN framework then you can use this document as a way to get started learning Flutter development.
This document can be used as a cookbook by jumping around and finding questions that are most relevant to your needs.
Introduction to Dart for JavaScript Developers
Like React Native, Flutter uses reactive-style views. However, while RN transpiles to native widgets, Flutter compiles all the way to native code. Flutter controls each pixel on the screen, which avoids performance problems caused by the need for a JavaScript bridge.
Dart is an easy language to learn and offers the following features:
- Provides an open-source, scalable programming language for building web, server, and mobile apps.
- Provides an object-oriented, single inheritance language that uses a C-style syntax that is AOT-compiled into native.
- Transcompiles optionally into JavaScript.
- Supports interfaces and abstract classes.
A few examples of the differences between JavaScript and Dart are described below.
Entry point
JavaScript doesn’t have a pre-defined entry function—you define the entry point.
// JavaScript
function startHere() {
// Can be used as entry point
}
In Dart, every app must have a top-level main()
function that serves as the
entry point to the app.
/// Dart
void main() {}
Try it out in DartPad.
Printing to the console
To print to the console in Dart, use print()
.
// JavaScript
console.log('Hello world!');
/// Dart
print('Hello world!');
Try it out in DartPad.
Variables
Dart is type safe—it uses a combination of static type checking and runtime checks to ensure that a variable’s value always matches the variable’s static type. Although types are mandatory, some type annotations are optional because Dart performs type inference.
Creating and assigning variables
In JavaScript, variables cannot be typed.
In Dart, variables must either be explicitly typed or the type system must infer the proper type automatically.
// JavaScript
var name = 'JavaScript';
/// Dart
/// Both variables are acceptable.
String name = 'dart'; // Explicitly typed as a [String].
var otherName = 'Dart'; // Inferred [String] type.
Try it out in DartPad.
For more information, see Dart’s Type System.
Default value
In JavaScript, uninitialized variables are undefined
.
In Dart, uninitialized variables have an initial value of null
.
Because numbers are objects in Dart, even uninitialized variables with
numeric types have the value null
.
// JavaScript
var name; // == undefined
// Dart
var name; // == null; raises a linter warning
int? x; // == null
Try it out in DartPad.
For more information, see the documentation on variables.
Checking for null or zero
In JavaScript, values of 1 or any non-null objects
are treated as true
when using the ==
comparison operator.
// JavaScript
var myNull = null;
if (!myNull) {
console.log('null is treated as false');
}
var zero = 0;
if (!zero) {
console.log('0 is treated as false');
}
In Dart, only the boolean value true
is treated as true.
/// Dart
var myNull;
var zero = 0;
if (zero == 0) {
print('use "== 0" to check zero');
}
Try it out in DartPad.
Functions
Dart and JavaScript functions are generally similar. The primary difference is the declaration.
// JavaScript
function fn() {
return true;
}
/// Dart
/// You can explicitly define the return type.
bool fn() {
return true;
}
Try it out in DartPad.
For more information, see the documentation on functions.
Asynchronous programming
Futures
Like JavaScript, Dart supports single-threaded execution. In JavaScript, the Promise object represents the eventual completion (or failure) of an asynchronous operation and its resulting value.
Dart uses Future
objects to handle this.
// JavaScript
class Example {
_getIPAddress() {
const url = 'https://httpbin.org/ip';
return fetch(url)
.then(response => response.json())
.then(responseJson => {
const ip = responseJson.origin;
return ip;
});
}
}
function main() {
const example = new Example();
example
._getIPAddress()
.then(ip => console.log(ip))
.catch(error => console.error(error));
}
main();
/// Dart
import 'dart:convert';
import 'package:http/http.dart' as http;
class Example {
Future<String> _getIPAddress() {
final url = Uri.https('httpbin.org', '/ip');
return http.get(url).then((response) {
String ip = jsonDecode(response.body)['origin'];
return ip;
});
}
}
void main() {
final example = Example();
example
._getIPAddress()
.then((ip) => print(ip))
.catchError((error) => print(error));
}
For more information, see the documentation on
Future
objects.
async
and await
The async
function declaration defines an asynchronous function.
In JavaScript, the async
function returns a Promise
.
The await
operator is used to wait for a Promise
.
// JavaScript
class Example {
async function _getIPAddress() {
const url = 'https://httpbin.org/ip';
const response = await fetch(url);
const json = await response.json();
const data = json.origin;
return data;
}
}
async function main() {
const example = new Example();
try {
const ip = await example._getIPAddress();
console.log(ip);
} catch (error) {
console.error(error);
}
}
main();
In Dart, an async
function returns a Future
,
and the body of the function is scheduled for execution later.
The await
operator is used to wait for a Future
.
// Dart
import 'dart:convert';
import 'package:http/http.dart' as http;
class Example {
Future<String> _getIPAddress() async {
final url = Uri.https('httpbin.org', '/ip');
final response = await http.get(url);
String ip = jsonDecode(response.body)['origin'];
return ip;
}
}
/// An async function returns a `Future`.
/// It can also return `void`, unless you use
/// the `avoid_void_async` lint. In that case,
/// return `Future<void>`.
void main() async {
final example = Example();
try {
final ip = await example._getIPAddress();
print(ip);
} catch (error) {
print(error);
}
}
For more information, see the documentation for async and await.
The basics
How do I create a Flutter app?
To create an app using React Native,
you would run create-react-native-app
from the command line.
$ create-react-native-app <projectname>
To create an app in Flutter, do one of the following:
- Use an IDE with the Flutter and Dart plugins installed.
- Use the
flutter create
command from the command line. Make sure that the Flutter SDK is in your PATH.
$ flutter create <projectname>
For more information, see Getting started, which walks you through creating a button-click counter app. Creating a Flutter project builds all the files that you need to run a sample app on both Android and iOS devices.
How do I run my app?
In React Native, you would run npm run
or yarn run
from the project
directory.
You can run Flutter apps in a couple of ways:
- Use the “run” option in an IDE with the Flutter and Dart plugins.
- Use
flutter run
from the project’s root directory.
Your app runs on a connected device, the iOS simulator, or the Android emulator.
For more information, see the Flutter Getting started documentation.
How do I import widgets?
In React Native, you need to import each required component.
// React Native
import React from 'react';
import { StyleSheet, Text, View } from 'react-native';
In Flutter, to use widgets from the Material Design library,
import the material.dart
package. To use iOS style widgets,
import the Cupertino library. To use a more basic widget set,
import the Widgets library.
Or, you can write your own widget library and import that.
import 'package:flutter/cupertino.dart';
import 'package:flutter/material.dart';
import 'package:flutter/widgets.dart';
import 'package:my_widgets/my_widgets.dart';
Whichever widget package you import, Dart pulls in only the widgets that are used in your app.
For more information, see the Flutter Widget Catalog.
What is the equivalent of the React Native “Hello world!” app in Flutter?
In React Native, the HelloWorldApp
class extends React.Component
and
implements the render method by returning a view component.
// React Native
import React from 'react';
import { StyleSheet, Text, View } from 'react-native';
export default class App extends React.Component {
render() {
return (
<View style={styles.container}>
<Text>Hello world!</Text>
</View>
);
}
}
const styles = StyleSheet.create({
container: {
flex: 1,
backgroundColor: '#fff',
alignItems: 'center',
justifyContent: 'center'
}
});
In Flutter, you can create an identical “Hello world!” app using the
Center
and Text
widgets from the core widget library.
The Center
widget becomes the root of the widget tree and has one child,
the Text
widget.
/// Flutter
import 'package:flutter/material.dart';
void main() {
runApp(
const Center(
child: Text(
'Hello, world!',
textDirection: TextDirection.ltr,
),
),
);
}
The following images show the Android and iOS UI for the basic Flutter “Hello world!” app.
Now that you’ve seen the most basic Flutter app, the next section shows how to take advantage of Flutter’s rich widget libraries to create a modern, polished app.
How do I use widgets and nest them to form a widget tree?
In Flutter, almost everything is a widget.
Widgets are the basic building blocks of an app’s user interface. You compose widgets into a hierarchy, called a widget tree. Each widget nests inside a parent widget and inherits properties from its parent. Even the application object itself is a widget. There is no separate “application” object. Instead, the root widget serves this role.
A widget can define:
- A structural element—like a button or menu
- A stylistic element—like a font or color scheme
- An aspect of layout—like padding or alignment
The following example shows the “Hello world!” app using widgets from the
Material library. In this example, the widget tree is nested inside the
MaterialApp
root widget.
/// Flutter
import 'package:flutter/material.dart';
void main() => runApp(const MyApp());
class MyApp extends StatelessWidget {
const MyApp({super.key});
@override
Widget build(BuildContext context) {
return MaterialApp(
title: 'Welcome to Flutter',
home: Scaffold(
appBar: AppBar(
title: const Text('Welcome to Flutter'),
),
body: const Center(
child: Text('Hello world'),
),
),
);
}
}
The following images show “Hello world!” built from Material Design widgets. You get more functionality for free than in the basic “Hello world!” app.
When writing an app, you’ll use two types of widgets:
StatelessWidget
or StatefulWidget
.
A StatelessWidget
is just what it sounds like—a
widget with no state. A StatelessWidget
is created once,
and never changes its appearance.
A StatefulWidget
dynamically changes state based on data
received, or user input.
The important difference between stateless and stateful
widgets is that StatefulWidget
s have a State
object
that stores state data and carries it over
across tree rebuilds, so it’s not lost.
In simple or basic apps it’s easy to nest widgets, but as the code base gets larger and the app becomes complex, you should break deeply nested widgets into functions that return the widget or smaller classes. Creating separate functions and widgets allows you to reuse the components within the app.
How do I create reusable components?
In React Native, you would define a class to create a
reusable component and then use props
methods to set
or return properties and values of the selected elements.
In the example below, the CustomCard
class is defined
and then used inside a parent class.
// React Native
class CustomCard extends React.Component {
render() {
return (
<View>
<Text> Card {this.props.index} </Text>
<Button
title="Press"
onPress={() => this.props.onPress(this.props.index)}
/>
</View>
);
}
}
// Usage
<CustomCard onPress={this.onPress} index={item.key} />
In Flutter, define a class to create a custom widget and then reuse the
widget. You can also define and call a function that returns a
reusable widget as shown in the build
function in the following example.
/// Flutter
class CustomCard extends StatelessWidget {
const CustomCard({
super.key,
required this.index,
required this.onPress,
});
final int index;
final void Function() onPress;
@override
Widget build(BuildContext context) {
return Card(
child: Column(
children: <Widget>[
Text('Card $index'),
TextButton(
onPressed: onPress,
child: const Text('Press'),
),
],
));
}
}
class UseCard extends StatelessWidget {
const UseCard({super.key, required this.index});
final int index;
@override
Widget build(BuildContext context) {
/// Usage
return CustomCard(
index: index,
onPress: () {
print('Card $index');
},
);
}
}
In the previous example, the constructor for the CustomCard
class uses Dart’s curly brace syntax { }
to indicate named parameters.
To require these fields, either remove the curly braces from
the constructor, or add required
to the constructor.
The following screenshots show an example of the reusable
CustomCard
class.
Project structure and resources
Where do I start writing the code?
Start with the lib/main.dart
file.
It’s autogenerated when you create a Flutter app.
// Dart
void main() {
print('Hello, this is the main function.');
}
In Flutter, the entry point file is
{project_name}/lib/main.dart
and execution
starts from the main
function.
How are files structured in a Flutter app?
When you create a new Flutter project, it builds the following directory structure. You can customize it later, but this is where you start.
┬
└ project_name
┬
├ android - Contains Android-specific files.
├ build - Stores iOS and Android build files.
├ ios - Contains iOS-specific files.
├ lib - Contains externally accessible Dart source files.
┬
└ src - Contains additional source files.
└ main.dart - The Flutter entry point and the start of a new app.
This is generated automatically when you create a Flutter
project.
It's where you start writing your Dart code.
├ test - Contains automated test files.
└ pubspec.yaml - Contains the metadata for the Flutter app.
This is equivalent to the package.json file in React Native.
Where do I put my resources and assets and how do I use them?
A Flutter resource or asset is a file that is bundled and deployed with your app and is accessible at runtime. Flutter apps can include the following asset types:
- Static data such as JSON files
- Configuration files
- Icons and images (JPEG, PNG, GIF, Animated GIF, WebP, Animated WebP, BMP, and WBMP)
Flutter uses the pubspec.yaml
file,
located at the root of your project, to
identify assets required by an app.
flutter:
assets:
- assets/my_icon.png
- assets/background.png
The assets
subsection specifies files that should be included with the app.
Each asset is identified by an explicit path
relative to the pubspec.yaml
file, where the asset file is located.
The order in which the assets are declared does not matter.
The actual directory used (assets
in this case) does not matter.
However, while assets can be placed in any app directory, it’s a
best practice to place them in the assets
directory.
During a build, Flutter places assets into a special archive
called the asset bundle, which apps read from at runtime.
When an asset’s path is specified in the assets’ section of pubspec.yaml
,
the build process looks for any files
with the same name in adjacent subdirectories.
These files are also included in the asset bundle
along with the specified asset. Flutter uses asset variants
when choosing resolution-appropriate images for your app.
In React Native, you would add a static image by placing the image file in a source code directory and referencing it.
<Image source={require('./my-icon.png')} />
In Flutter, add a static image to your app
using the Image.asset
constructor in a widget’s build method.
Image.asset('assets/background.png');
For more information, see Adding Assets and Images in Flutter.
How do I load images over a network?
In React Native, you would specify the uri
in the
source
prop of the Image
component and also provide the
size if needed.
In Flutter, use the Image.network
constructor to include
an image from a URL.
Image.network('https://docs.flutter.dev/assets/images/docs/owl.jpg');
How do I install packages and package plugins?
Flutter supports using shared packages contributed by other developers to the Flutter and Dart ecosystems. This allows you to quickly build your app without having to develop everything from scratch. Packages that contain platform-specific code are known as package plugins.
In React Native, you would use yarn add {package-name}
or
npm install --save {package-name}
to install packages
from the command line.
In Flutter, install a package using the following instructions:
- Add the package name and version to the
pubspec.yaml
dependencies section. The example below shows how to add thegoogle_sign_in
Dart package to thepubspec.yaml
file. Check your spaces when working in the YAML file because white space matters!
dependencies:
flutter:
sdk: flutter
google_sign_in: ^3.0.3
- Install the package from the command line by using
flutter pub get
. If using an IDE, it often runsflutter pub get
for you, or it might prompt you to do so. - Import the package into your app code as shown below:
import 'package:flutter/material.dart';
For more information, see Using Packages and Developing Packages & Plugins.
You can find many packages shared by Flutter developers in the Flutter packages section of pub.dev.
Flutter widgets
In Flutter, you build your UI out of widgets that describe what their view should look like given their current configuration and state.
Widgets are often composed of many small,
single-purpose widgets that are nested to produce powerful effects.
For example, the Container
widget consists of
several widgets responsible for layout, painting, positioning, and sizing.
Specifically, the Container
widget includes the LimitedBox
,
ConstrainedBox
, Align
, Padding
, DecoratedBox
, and Transform
widgets.
Rather than subclassing Container
to produce a customized effect, you can
compose these and other simple widgets in new and unique ways.
The Center
widget is another example of how you can control the layout.
To center a widget, wrap it in a Center
widget and then use layout
widgets for alignment, row, columns, and grids.
These layout widgets do not have a visual representation of their own.
Instead, their sole purpose is to control some aspect of another
widget’s layout. To understand why a widget renders in a
certain way, it’s often helpful to inspect the neighboring widgets.
For more information, see the Flutter Technical Overview.
For more information about the core widgets from the Widgets
package,
see Flutter Basic Widgets,
the Flutter Widget Catalog,
or the Flutter Widget Index.
Views
View
container?
What is the equivalent of the In React Native, View
is a container that supports layout with Flexbox
,
style, touch handling, and accessibility controls.
In Flutter, you can use the core layout widgets in the Widgets
library, such as Container
, Column
,
Row
, and Center
.
For more information, see the Layout Widgets catalog.
FlatList
or SectionList
?
What is the equivalent of A List
is a scrollable list of components arranged vertically.
In React Native, FlatList
or SectionList
are used to render simple or
sectioned lists.
// React Native
<FlatList
data={[ ... ]}
renderItem={({ item }) => <Text>{item.key}</Text>}
/>
ListView
is Flutter’s most commonly used scrolling widget.
The default constructor takes an explicit list of children.
ListView
is most appropriate for a small number of widgets.
For a large or infinite list, use ListView.builder
,
which builds its children on demand and only builds
those children that are visible.
var data = [
'Hello',
'World',
];
return ListView.builder(
itemCount: data.length,
itemBuilder: (context, index) {
return Text(data[index]);
},
);
To learn how to implement an infinite scrolling list, see the official
infinite_list
sample.
How do I use a Canvas to draw or paint?
In React Native, canvas components aren’t present
so third party libraries like react-native-canvas
are used.
// React Native
handleCanvas = canvas => {
const ctx = canvas.getContext('2d');
ctx.fillStyle = 'skyblue';
ctx.beginPath();
ctx.arc(75, 75, 50, 0, 2 * Math.PI);
ctx.fillRect(150, 100, 300, 300);
ctx.stroke();
};
render() {
return (
<View>
<Canvas ref={this.handleCanvas} />
</View>
);
}
In Flutter, you can use the CustomPaint
and CustomPainter
classes to draw to the canvas.
The following example shows how to draw during the paint phase using the
CustomPaint
widget. It implements the abstract class, CustomPainter
,
and passes it to CustomPaint
’s painter property.
CustomPaint
subclasses must implement the paint()
and shouldRepaint()
methods.
class MyCanvasPainter extends CustomPainter {
const MyCanvasPainter();
@override
void paint(Canvas canvas, Size size) {
final Paint paint = Paint()..color = Colors.amber;
canvas.drawCircle(const Offset(100.0, 200.0), 40.0, paint);
final Paint paintRect = Paint()..color = Colors.lightBlue;
final Rect rect = Rect.fromPoints(
const Offset(150.0, 300.0),
const Offset(300.0, 400.0),
);
canvas.drawRect(rect, paintRect);
}
@override
bool shouldRepaint(MyCanvasPainter oldDelegate) => false;
}
class MyCanvasWidget extends StatelessWidget {
const MyCanvasWidget({super.key});
@override
Widget build(BuildContext context) {
return const Scaffold(
body: CustomPaint(painter: MyCanvasPainter()),
);
}
}
Layouts
How do I use widgets to define layout properties?
In React Native, most of the layout can be done with the props
that are passed to a specific component.
For example, you could use the style
prop on the View
component
in order to specify the flexbox properties.
To arrange your components in a column, you would specify a prop such as:
flexDirection: 'column'
.
// React Native
<View
style={{
flex: 1,
flexDirection: 'column',
justifyContent: 'space-between',
alignItems: 'center'
}}
>
In Flutter, the layout is primarily defined by widgets specifically designed to provide layout, combined with control widgets and their style properties.
For example, the Column
and Row
widgets
take an array of children and align them
vertically and horizontally respectively.
A Container
widget takes a combination of
layout and styling properties, and a
Center
widget centers its child widgets.
@override
Widget build(BuildContext context) {
return Center(
child: Column(
children: <Widget>[
Container(
color: Colors.red,
width: 100.0,
height: 100.0,
),
Container(
color: Colors.blue,
width: 100.0,
height: 100.0,
),
Container(
color: Colors.green,
width: 100.0,
height: 100.0,
),
],
),
);
Flutter provides a variety of layout widgets in its core widget library.
For example, Padding
, Align
, and Stack
.
For a complete list, see Layout Widgets.
How do I layer widgets?
In React Native, components can be layered using absolute
positioning.
Flutter uses the Stack
widget to arrange children widgets in layers.
The widgets can entirely or partially overlap the base widget.
The Stack
widget positions its children relative to the edges of its box.
This class is useful if you simply want to overlap several children widgets.
@override
Widget build(BuildContext context) {
return Stack(
alignment: const Alignment(0.6, 0.6),
children: <Widget>[
const CircleAvatar(
backgroundImage: NetworkImage(
'https://avatars3.githubusercontent.com/u/14101776?v=4',
),
),
Container(
color: Colors.black45,
child: const Text('Flutter'),
),
],
);
The previous example uses Stack
to overlay a Container
(that displays its Text
on a translucent black background)
on top of a CircleAvatar
.
The Stack offsets the text using the alignment property
and Alignment
coordinates.
For more information, see the Stack
class documentation.
Styling
How do I style my components?
In React Native, inline styling and stylesheets.create
are used to style components.
// React Native
<View style={styles.container}>
<Text style={{ fontSize: 32, color: 'cyan', fontWeight: '600' }}>
This is a sample text
</Text>
</View>
const styles = StyleSheet.create({
container: {
flex: 1,
backgroundColor: '#fff',
alignItems: 'center',
justifyContent: 'center'
}
});
In Flutter, a Text
widget can take a TextStyle
class
for its style property. If you want to use the same text
style in multiple places, you can create a
TextStyle
class and use it for multiple Text
widgets.
const TextStyle textStyle = TextStyle(
color: Colors.cyan,
fontSize: 32.0,
fontWeight: FontWeight.w600,
);
return const Center(
child: Column(
children: <Widget>[
Text('Sample text', style: textStyle),
Padding(
padding: EdgeInsets.all(20.0),
child: Icon(
Icons.lightbulb_outline,
size: 48.0,
color: Colors.redAccent,
),
),
],
),
);
Icons
and Colors
?
How do I use React Native doesn’t include support for icons so third party libraries are used.
In Flutter, importing the Material library also pulls in the rich set of Material icons and colors.
return const Icon(Icons.lightbulb_outline, color: Colors.redAccent);
When using the Icons
class,
make sure to set uses-material-design: true
in
the project’s pubspec.yaml
file.
This ensures that the MaterialIcons
font,
which displays the icons, is included in your app.
In general, if you intend to use the Material library,
you should include this line.
name: my_awesome_application
flutter:
uses-material-design: true
Flutter’s Cupertino (iOS-style) package provides high
fidelity widgets for the current iOS design language.
To use the CupertinoIcons
font,
add a dependency for cupertino_icons
in your project’s
pubspec.yaml
file.
name: my_awesome_application
dependencies:
cupertino_icons: ^0.1.0
To globally customize the colors and styles of components,
use ThemeData
to specify default colors
for various aspects of the theme.
Set the theme property in MaterialApp
to the ThemeData
object.
The Colors
class provides colors
from the Material Design color palette.
The following example sets the primary swatch to blue
and the text selection to red
.
class SampleApp extends StatelessWidget {
const SampleApp({super.key});
@override
Widget build(BuildContext context) {
return MaterialApp(
title: 'Sample App',
theme: ThemeData(
primarySwatch: Colors.blue,
textSelectionTheme:
const TextSelectionThemeData(selectionColor: Colors.red)),
home: const SampleAppPage(),
);
}
}
How do I add style themes?
In React Native, common themes are defined for components in stylesheets and then used in components.
In Flutter, create uniform styling for almost everything
by defining the styling in the ThemeData
class and passing it to the theme property in the
MaterialApp
widget.
@override
Widget build(BuildContext context) {
return MaterialApp(
theme: ThemeData(
primaryColor: Colors.cyan,
brightness: Brightness.dark,
),
home: const StylingPage(),
);
}
A Theme
can be applied even without using the MaterialApp
widget.
The Theme
widget takes a ThemeData
in its data
parameter
and applies the ThemeData
to all of its children widgets.
@override
Widget build(BuildContext context) {
return Theme(
data: ThemeData(
primaryColor: Colors.cyan,
brightness: brightness,
),
child: Scaffold(
backgroundColor: Theme.of(context).primaryColor,
//...
),
);
}
State management
State is information that can be read synchronously
when a widget is built or information
that might change during the lifetime of a widget.
To manage app state in Flutter,
use a StatefulWidget
paired with a State object.
For more information on ways to approach managing state in Flutter, see State management.
The StatelessWidget
A StatelessWidget
in Flutter is a widget
that doesn’t require a state change—
it has no internal state to manage.
Stateless widgets 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 itself and the
BuildContext
in which the widget is inflated.
AboutDialog
, CircleAvatar
, and Text
are examples
of stateless widgets that subclass StatelessWidget
.
import 'package:flutter/material.dart';
void main() => runApp(
const MyStatelessWidget(
text: 'StatelessWidget Example to show immutable data',
),
);
class MyStatelessWidget extends StatelessWidget {
const MyStatelessWidget({
super.key,
required this.text,
});
final String text;
@override
Widget build(BuildContext context) {
return Center(
child: Text(
text,
textDirection: TextDirection.ltr,
),
);
}
}
The previous example uses the constructor of the MyStatelessWidget
class to pass the text
, which is marked as final
.
This class extends StatelessWidget
—it contains immutable data.
The build
method of a stateless widget is typically called
in only three situations:
- When the widget is inserted into a tree
- When the widget’s parent changes its configuration
- When an
InheritedWidget
it depends on, changes
The StatefulWidget
A StatefulWidget
is a widget that changes state.
Use the setState
method to manage the
state changes for a StatefulWidget
.
A call to setState()
tells the Flutter
framework that something has changed in a state,
which causes an app to rerun the build()
method
so that the app can reflect the change.
State is information that can be read synchronously when a widget
is built and might change during the lifetime of the widget.
It’s the responsibility of the widget implementer to ensure that
the state object is promptly notified when the state changes.
Use StatefulWidget
when a widget can change dynamically.
For example, the state of the widget changes by typing into a form,
or moving a slider.
Or, it can change over time—perhaps a data feed updates the UI.
Checkbox
, Radio
, Slider
, InkWell
,
Form
, and TextField
are examples of stateful widgets that subclass
StatefulWidget
.
The following example declares a StatefulWidget
that requires a createState()
method.
This method creates the state object that manages the widget’s state,
_MyStatefulWidgetState
.
class MyStatefulWidget extends StatefulWidget {
const MyStatefulWidget({
super.key,
required this.title,
});
final String title;
@override
State<MyStatefulWidget> createState() => _MyStatefulWidgetState();
}
The following state class, _MyStatefulWidgetState
,
implements the build()
method for the widget.
When the state changes, for example, when the user toggles
the button, setState()
is called with the new toggle value.
This causes the framework to rebuild this widget in the UI.
class _MyStatefulWidgetState extends State<MyStatefulWidget> {
bool showText = true;
bool toggleState = true;
Timer? t2;
void toggleBlinkState() {
setState(() {
toggleState = !toggleState;
});
if (!toggleState) {
t2 = Timer.periodic(const Duration(milliseconds: 1000), (t) {
toggleShowText();
});
} else {
t2?.cancel();
}
}
void toggleShowText() {
setState(() {
showText = !showText;
});
}
@override
Widget build(BuildContext context) {
return Scaffold(
body: Center(
child: Column(
children: <Widget>[
if (showText)
const Text(
'This execution will be done before you can blink.',
),
Padding(
padding: const EdgeInsets.only(top: 70.0),
child: ElevatedButton(
onPressed: toggleBlinkState,
child: toggleState
? const Text('Blink')
: const Text('Stop Blinking'),
),
),
],
),
),
);
}
}
What are the StatefulWidget and StatelessWidget best practices?
Here are a few things to consider when designing your widget.
- Determine whether a widget should be
a
StatefulWidget
or aStatelessWidget
.
In Flutter, widgets are either Stateful or Stateless—depending on whether they depend on a state change.
- If a widget changes—the user interacts with it or a data feed interrupts the UI, then it’s Stateful.
- If a widget is final or immutable, then it’s Stateless.
- Determine which object manages the widget’s state (for a
StatefulWidget
).
In Flutter, there are three primary ways to manage state:
- The widget manages its own state
- The parent widget manages the widget’s state
- A mix-and-match approach
When deciding which approach to use, consider the following principles:
- If the state in question is user data, for example the checked or unchecked mode of a checkbox, or the position of a slider, then the state is best managed by the parent widget.
- If the state in question is aesthetic, for example an animation, then the widget itself best manages the state.
- When in doubt, let the parent widget manage the child widget’s state.
- Subclass StatefulWidget and State.
The MyStatefulWidget
class manages its own state—it extends
StatefulWidget
, it overrides the createState()
method to create the State
object,
and the framework calls createState()
to build the widget.
In this example, createState()
creates an instance of
_MyStatefulWidgetState
, which
is implemented in the next best practice.
class MyStatefulWidget extends StatefulWidget {
const MyStatefulWidget({
super.key,
required this.title,
});
final String title;
@override
State<MyStatefulWidget> createState() => _MyStatefulWidgetState();
}
class _MyStatefulWidgetState extends State<MyStatefulWidget> {
@override
Widget build(BuildContext context) {
//...
}
}
- Add the StatefulWidget into the widget tree.
Add your custom StatefulWidget
to the widget tree
in the app’s build method.
class MyStatelessWidget extends StatelessWidget {
// This widget is the root of your application.
const MyStatelessWidget({super.key});
@override
Widget build(BuildContext context) {
return const MaterialApp(
title: 'Flutter Demo',
home: MyStatefulWidget(title: 'State Change Demo'),
);
}
}
Props
In React Native, most components can be customized when they are
created with different parameters or properties, called props
.
These parameters can be used in a child component using this.props
.
// React Native
class CustomCard extends React.Component {
render() {
return (
<View>
<Text> Card {this.props.index} </Text>
<Button
title='Press'
onPress={() => this.props.onPress(this.props.index)}
/>
</View>
);
}
}
class App extends React.Component {
onPress = index => {
console.log('Card ', index);
};
render() {
return (
<View>
<FlatList
data={[ ... ]}
renderItem={({ item }) => (
<CustomCard onPress={this.onPress} index={item.key} />
)}
/>
</View>
);
}
}
In Flutter, you assign a local variable or function marked
final
with the property received in the parameterized constructor.
/// Flutter
class CustomCard extends StatelessWidget {
const CustomCard({
super.key,
required this.index,
required this.onPress,
});
final int index;
final void Function() onPress;
@override
Widget build(BuildContext context) {
return Card(
child: Column(
children: <Widget>[
Text('Card $index'),
TextButton(
onPressed: onPress,
child: const Text('Press'),
),
],
));
}
}
class UseCard extends StatelessWidget {
const UseCard({super.key, required this.index});
final int index;
@override
Widget build(BuildContext context) {
/// Usage
return CustomCard(
index: index,
onPress: () {
print('Card $index');
},
);
}
}
Local storage
If you don’t need to store a lot of data, and it doesn’t require
structure, you can use shared_preferences
which allows you to
read and write persistent key-value pairs of primitive data
types: booleans, floats, ints, longs, and strings.
How do I store persistent key-value pairs that are global to the app?
In React Native, you use the setItem
and getItem
functions
of the AsyncStorage
component to store and retrieve data
that is persistent and global to the app.
// React Native
await AsyncStorage.setItem( 'counterkey', json.stringify(++this.state.counter));
AsyncStorage.getItem('counterkey').then(value => {
if (value != null) {
this.setState({ counter: value });
}
});
In Flutter, use the shared_preferences
plugin to
store and retrieve key-value data that is persistent and global
to the app. The shared_preferences
plugin wraps
NSUserDefaults
on iOS and SharedPreferences
on Android,
providing a persistent store for simple data.
To use the plugin,
add shared_preferences
as a dependency in the pubspec.yaml
file then import the package in your Dart file.
dependencies:
flutter:
sdk: flutter
shared_preferences: ^2.0.13
import 'package:shared_preferences/shared_preferences.dart';
To implement persistent data, use the setter methods
provided by the SharedPreferences
class.
Setter methods are available for various primitive
types, such as setInt
, setBool
, and setString
.
To read data, use the appropriate getter method provided
by the SharedPreferences
class. For each
setter there is a corresponding getter method,
for example, getInt
, getBool
, and getString
.
Future<void> updateCounter() async {
final prefs = await SharedPreferences.getInstance();
int? counter = prefs.getInt('counter');
if (counter is int) {
await prefs.setInt('counter', ++counter);
}
setState(() {
_counter = counter;
});
}
Routing
Most apps contain several screens for displaying different types of information. For example, you might have a product screen that displays images where users could tap on a product image to get more information about the product on a new screen.
In Android, new screens are new Activities. In iOS, new screens are new ViewControllers. In Flutter, screens are just Widgets! And to navigate to new screens in Flutter, use the Navigator widget.
How do I navigate between screens?
In React Native, there are three main navigators: StackNavigator, TabNavigator, and DrawerNavigator. Each provides a way to configure and define the screens.
// React Native
const MyApp = TabNavigator(
{ Home: { screen: HomeScreen }, Notifications: { screen: tabNavScreen } },
{ tabBarOptions: { activeTintColor: '#e91e63' } }
);
const SimpleApp = StackNavigator({
Home: { screen: MyApp },
stackScreen: { screen: StackScreen }
});
export default (MyApp1 = DrawerNavigator({
Home: {
screen: SimpleApp
},
Screen2: {
screen: drawerScreen
}
}));
In Flutter, there are two main widgets used to navigate between screens:
A Navigator
is defined as a widget that manages a set of child
widgets with a stack discipline. The navigator manages a stack
of Route
objects and provides methods for managing the stack,
like Navigator.push
and Navigator.pop
.
A list of routes might be specified in the MaterialApp
widget,
or they might be built on the fly, for example, in hero animations.
The following example specifies named routes in the MaterialApp
widget.
class NavigationApp extends StatelessWidget {
// This widget is the root of your application.
const NavigationApp({super.key});
@override
Widget build(BuildContext context) {
return MaterialApp(
//...
routes: <String, WidgetBuilder>{
'/a': (context) => const UsualNavScreen(),
'/b': (context) => const DrawerNavScreen(),
},
//...
);
}
}
To navigate to a named route, the Navigator.of()
method is used to specify the BuildContext
(a handle to the location of a widget in the widget tree).
The name of the route is passed to the pushNamed
function to
navigate to the specified route.
Navigator.of(context).pushNamed('/a');
You can also use the push method of Navigator
which
adds the given Route
to the history of the
navigator that most tightly encloses the given BuildContext
,
and transitions to it. In the following example,
the MaterialPageRoute
widget is a modal route that
replaces the entire screen with a platform-adaptive
transition. It takes a WidgetBuilder
as a required parameter.
Navigator.push(
context,
MaterialPageRoute(
builder: (context) => const UsualNavScreen(),
),
);
How do I use tab navigation and drawer navigation?
In Material Design apps, there are two primary options for Flutter navigation: tabs and drawers. When there is insufficient space to support tabs, drawers provide a good alternative.
Tab navigation
In React Native, createBottomTabNavigator
and TabNavigation
are used to
show tabs and for tab navigation.
// React Native
import { createBottomTabNavigator } from 'react-navigation';
const MyApp = TabNavigator(
{ Home: { screen: HomeScreen }, Notifications: { screen: tabNavScreen } },
{ tabBarOptions: { activeTintColor: '#e91e63' } }
);
Flutter provides several specialized widgets for drawer and tab navigation:
TabController
- Coordinates the tab selection between a
TabBar
and aTabBarView
. TabBar
- Displays a horizontal row of tabs.
Tab
- Creates a material design TabBar tab.
TabBarView
- Displays the widget that corresponds to the currently selected tab.
class _MyAppState extends State<MyApp> with SingleTickerProviderStateMixin {
late TabController controller = TabController(length: 2, vsync: this);
@override
Widget build(BuildContext context) {
return TabBar(
controller: controller,
tabs: const <Tab>[
Tab(icon: Icon(Icons.person)),
Tab(icon: Icon(Icons.email)),
],
);
}
}
A TabController
is required to coordinate the tab selection
between a TabBar
and a TabBarView
.
The TabController
constructor length
argument is the total
number of tabs. A TickerProvider
is required to trigger
the notification whenever a frame triggers a state change.
The TickerProvider
is vsync
. Pass the
vsync: this
argument to the TabController
constructor
whenever you create a new TabController
.
The TickerProvider
is an interface implemented
by classes that can vend Ticker
objects.
Tickers can be used by any object that must be notified whenever a
frame triggers, but they’re most commonly used indirectly via an
AnimationController
. AnimationController
s
need a TickerProvider
to obtain their Ticker
.
If you are creating an AnimationController from a State,
then you can use the TickerProviderStateMixin
or SingleTickerProviderStateMixin
classes to obtain a suitable TickerProvider
.
The Scaffold
widget wraps a new TabBar
widget and
creates two tabs. The TabBarView
widget
is passed as the body
parameter of the Scaffold
widget.
All screens corresponding to the TabBar
widget’s tabs are
children to the TabBarView
widget along with the same TabController
.
class _NavigationHomePageState extends State<NavigationHomePage>
with SingleTickerProviderStateMixin {
late TabController controller = TabController(length: 2, vsync: this);
@override
Widget build(BuildContext context) {
return Scaffold(
bottomNavigationBar: Material(
color: Colors.blue,
child: TabBar(
tabs: const <Tab>[
Tab(
icon: Icon(Icons.person),
),
Tab(
icon: Icon(Icons.email),
),
],
controller: controller,
),
),
body: TabBarView(
controller: controller,
children: const <Widget>[HomeScreen(), TabScreen()],
));
}
}
Drawer navigation
In React Native, import the needed react-navigation packages and then use
createDrawerNavigator
and DrawerNavigation
.
// React Native
export default (MyApp1 = DrawerNavigator({
Home: {
screen: SimpleApp
},
Screen2: {
screen: drawerScreen
}
}));
In Flutter, we can use the Drawer
widget in combination with a
Scaffold
to create a layout with a Material Design drawer.
To add a Drawer
to an app, wrap it in a Scaffold
widget.
The Scaffold
widget provides a consistent
visual structure to apps that follow the
Material Design guidelines. It also supports
special Material Design components,
such as Drawers
, AppBars
, and SnackBars
.
The Drawer
widget is a Material Design panel that slides
in horizontally from the edge of a Scaffold
to show navigation
links in an application. You can
provide a ElevatedButton
, a Text
widget,
or a list of items to display as the child to the Drawer
widget.
In the following example, the ListTile
widget provides the navigation on tap.
@override
Widget build(BuildContext context) {
return Drawer(
elevation: 20.0,
child: ListTile(
leading: const Icon(Icons.change_history),
title: const Text('Screen2'),
onTap: () {
Navigator.of(context).pushNamed('/b');
},
),
);
}
The Scaffold
widget also includes an AppBar
widget that automatically
displays an appropriate IconButton to show the Drawer
when a Drawer is
available in the Scaffold
. The Scaffold
automatically handles the
edge-swipe gesture to show the Drawer
.
@override
Widget build(BuildContext context) {
return Scaffold(
drawer: Drawer(
elevation: 20.0,
child: ListTile(
leading: const Icon(Icons.change_history),
title: const Text('Screen2'),
onTap: () {
Navigator.of(context).pushNamed('/b');
},
),
),
appBar: AppBar(title: const Text('Home')),
body: Container(),
);
}
Gesture detection and touch event handling
To listen for and respond to gestures, Flutter supports taps, drags, and scaling. The gesture system in Flutter has two separate layers. The first layer includes raw pointer events, which describe the location and movement of pointers, (such as touches, mice, and styli movements), across the screen. The second layer includes gestures, which describe semantic actions that consist of one or more pointer movements.
How do I add a click or press listeners to a widget?
In React Native, listeners are added to components
using PanResponder
or the Touchable
components.
// React Native
<TouchableOpacity
onPress={() => {
console.log('Press');
}}
onLongPress={() => {
console.log('Long Press');
}}
>
<Text>Tap or Long Press</Text>
</TouchableOpacity>
For more complex gestures and combining several touches into
a single gesture, PanResponder
is used.
// React Native
class App extends Component {
componentWillMount() {
this._panResponder = PanResponder.create({
onMoveShouldSetPanResponder: (event, gestureState) =>
!!getDirection(gestureState),
onPanResponderMove: (event, gestureState) => true,
onPanResponderRelease: (event, gestureState) => {
const drag = getDirection(gestureState);
},
onPanResponderTerminationRequest: (event, gestureState) => true
});
}
render() {
return (
<View style={styles.container} {...this._panResponder.panHandlers}>
<View style={styles.center}>
<Text>Swipe Horizontally or Vertically</Text>
</View>
</View>
);
}
}
In Flutter, to add a click (or press) listener to a widget,
use a button or a touchable widget that has an onPress: field
.
Or, add gesture detection to any widget by wrapping it
in a GestureDetector
.
@override
Widget build(BuildContext context) {
return GestureDetector(
child: Scaffold(
appBar: AppBar(title: const Text('Gestures')),
body: const Center(
child: Column(
mainAxisAlignment: MainAxisAlignment.center,
children: <Widget>[
Text('Tap, Long Press, Swipe Horizontally or Vertically'),
],
)),
),
onTap: () {
print('Tapped');
},
onLongPress: () {
print('Long Pressed');
},
onVerticalDragEnd: (value) {
print('Swiped Vertically');
},
onHorizontalDragEnd: (value) {
print('Swiped Horizontally');
},
);
}
For more information, including a list of
Flutter GestureDetector
callbacks,
see the GestureDetector class.
Making HTTP network requests
Fetching data from the internet is common for most apps. And in Flutter,
the http
package provides the simplest way to fetch data from the internet.
How do I fetch data from API calls?
React Native provides the Fetch API for networking—you make a fetch request and then receive the response to get the data.
// React Native
_getIPAddress = () => {
fetch('https://httpbin.org/ip')
.then(response => response.json())
.then(responseJson => {
this.setState({ _ipAddress: responseJson.origin });
})
.catch(error => {
console.error(error);
});
};
Flutter uses the http
package. To install the http
package,
add it to the dependencies’ section of our pubspec.yaml.
dependencies:
flutter:
sdk: flutter
http: <latest_version>
Flutter uses the dart:io
core HTTP support client.
To create an HTTP Client, import dart:io
.
import 'dart:io';
The client supports the following HTTP operations: GET, POST, PUT, and DELETE.
final url = Uri.parse('https://httpbin.org/ip');
final httpClient = HttpClient();
Future<void> getIPAddress() async {
final request = await httpClient.getUrl(url);
final response = await request.close();
final responseBody = await response.transform(utf8.decoder).join();
final String ip = jsonDecode(responseBody)['origin'];
setState(() {
_ipAddress = ip;
});
}
Form input
Text fields allow users to type text into your app so they can be
used to build forms, messaging apps, search experiences, and more.
Flutter provides two core text field widgets:
TextField
and TextFormField
.
How do I use text field widgets?
In React Native, to enter text you use a TextInput
component to show a text
input box and then use the callback to store the value in a variable.
// React Native
<TextInput
placeholder="Enter your Password"
onChangeText={password => this.setState({ password })}
/>
<Button title="Submit" onPress={this.validate} />
In Flutter, use the TextEditingController
class to manage a TextField
widget.
Whenever the text field is modified,
the controller notifies its listeners.
Listeners read the text and selection properties to
learn what the user typed into the field.
You can access the text in TextField
by the text
property of the controller.
final TextEditingController _controller = TextEditingController();
@override
Widget build(BuildContext context) {
return Column(children: [
TextField(
controller: _controller,
decoration: const InputDecoration(
hintText: 'Type something',
labelText: 'Text Field',
),
),
ElevatedButton(
child: const Text('Submit'),
onPressed: () {
showDialog(
context: context,
builder: (context) {
return AlertDialog(
title: const Text('Alert'),
content: Text('You typed ${_controller.text}'),
);
});
},
),
]);
}
In this example, when a user clicks on the submit button an alert dialog
displays the current text entered in the text field.
This is achieved using an AlertDialog
widget that displays the alert message, and the text from
the TextField
is accessed by the text
property of the
TextEditingController
.
How do I use Form widgets?
In Flutter, use the Form
widget where
TextFormField
widgets along with the submit
button are passed as children.
The TextFormField
widget has a parameter called
onSaved
that takes a callback and executes
when the form is saved. A FormState
object is used to save, reset, or validate
each FormField
that is a descendant of this Form
.
To obtain the FormState
, you can use Form.of()
with a context whose ancestor is the Form
,
or pass a GlobalKey
to the Form
constructor and call
GlobalKey.currentState()
.
@override
Widget build(BuildContext context) {
return Form(
key: formKey,
child: Column(
children: <Widget>[
TextFormField(
validator: (value) {
if (value != null && value.contains('@')) {
return null;
}
return 'Not a valid email.';
},
onSaved: (val) {
_email = val;
},
decoration: const InputDecoration(
hintText: 'Enter your email',
labelText: 'Email',
),
),
ElevatedButton(
onPressed: _submit,
child: const Text('Login'),
),
],
),
);
}
The following example shows how Form.save()
and formKey
(which is a GlobalKey
), are used to save the form on submit.
void _submit() {
final form = formKey.currentState;
if (form != null && form.validate()) {
form.save();
showDialog(
context: context,
builder: (context) {
return AlertDialog(
title: const Text('Alert'),
content: Text('Email: $_email, password: $_password'));
},
);
}
}
Platform-specific code
When building a cross-platform app, you want to re-use as much code as possible across platforms. However, scenarios might arise where it makes sense for the code to be different depending on the OS. This requires a separate implementation by declaring a specific platform.
In React Native, the following implementation would be used:
// React Native
if (Platform.OS === 'ios') {
return 'iOS';
} else if (Platform.OS === 'android') {
return 'android';
} else {
return 'not recognised';
}
In Flutter, use the following implementation:
final platform = Theme.of(context).platform;
if (platform == TargetPlatform.iOS) {
return 'iOS';
}
if (platform == TargetPlatform.android) {
return 'android';
}
if (platform == TargetPlatform.fuchsia) {
return 'fuchsia';
}
return 'not recognized ';
Debugging
What tools can I use to debug my app in Flutter?
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, see the DevTools documentation.
If you’re using an IDE, you can debug your application using the IDE’s debugger.
How do I perform a hot reload?
Flutter’s Stateful Hot Reload feature helps you quickly and easily experiment, build UIs, add features, and fix bugs. Instead of recompiling your app every time you make a change, you can hot reload your app instantly. The app is updated to reflect your change, and the current state of the app is preserved.
In React Native, the shortcut is ⌘R for the iOS Simulator and tapping R twice on Android emulators.
In Flutter, If you are using IntelliJ IDE or Android Studio,
you can select Save All (⌘s/ctrl-s), or you can click the
Hot Reload button on the toolbar. If you
are running the app at the command line using flutter run
,
type r
in the Terminal window.
You can also perform a full restart by typing R
in the
Terminal window.
How do I access the in-app developer menu?
In React Native, the developer menu can be accessed by shaking your device: ⌘D for the iOS Simulator or ⌘M for Android emulator.
In Flutter, if you are using an IDE, you can use the IDE tools. If you start
your application using flutter run
you can also access the menu by typing h
in the terminal window, or type the following shortcuts:
Action | Terminal Shortcut | Debug functions and properties |
---|---|---|
Widget hierarchy of the app | w |
debugDumpApp() |
Rendering tree of the app | t |
debugDumpRenderTree() |
Layers | L |
debugDumpLayerTree() |
Accessibility |
S (traversal order) orU (inverse hit test order) |
debugDumpSemantics() |
To toggle the widget inspector | i |
WidgetsApp. showWidgetInspectorOverride |
To toggle the display of construction lines | p |
debugPaintSizeEnabled |
To simulate different operating systems | o |
defaultTargetPlatform |
To display the performance overlay | P |
WidgetsApp. showPerformanceOverlay |
To save a screenshot to flutter. png | s |
|
To quit | q |
Animation
Well-designed animation makes a UI feel intuitive, contributes to the look and feel of a polished app, and improves the user experience. Flutter’s animation support makes it easy to implement simple and complex animations. The Flutter SDK includes many Material Design widgets that include standard motion effects, and you can easily customize these effects to personalize your app.
In React Native, Animated APIs are used to create animations.
In Flutter, use the Animation
class and the AnimationController
class.
Animation
is an abstract class that understands its
current value and its state (completed or dismissed).
The AnimationController
class lets you
play an animation forward or in reverse,
or stop animation and set the animation
to a specific value to customize the motion.
How do I add a simple fade-in animation?
In the React Native example below, an animated component,
FadeInView
is created using the Animated API.
The initial opacity state, final state, and the
duration over which the transition occurs are defined.
The animation component is added inside the Animated
component,
the opacity state fadeAnim
is mapped
to the opacity of the Text
component that we want to animate,
and then, start()
is called to start the animation.
// React Native
class FadeInView extends React.Component {
state = {
fadeAnim: new Animated.Value(0) // Initial value for opacity: 0
};
componentDidMount() {
Animated.timing(this.state.fadeAnim, {
toValue: 1,
duration: 10000
}).start();
}
render() {
return (
<Animated.View style={{...this.props.style, opacity: this.state.fadeAnim }} >
{this.props.children}
</Animated.View>
);
}
}
...
<FadeInView>
<Text> Fading in </Text>
</FadeInView>
...
To create the same animation in Flutter, create an
AnimationController
object named controller
and specify the duration. By default, an AnimationController
linearly produces values that range from 0.0 to 1.0,
during a given duration. The animation controller generates a new value
whenever the device running your app is ready to display a new frame.
Typically, this rate is around 60 values per second.
When defining an AnimationController
,
you must pass in a vsync
object.
The presence of vsync
prevents offscreen
animations from consuming unnecessary resources.
You can use your stateful object as the vsync
by adding
TickerProviderStateMixin
to the class definition.
An AnimationController
needs a TickerProvider,
which is configured using the vsync
argument on the constructor.
A Tween
describes the interpolation between a
beginning and ending value or the mapping from an input
range to an output range. To use a Tween
object
with an animation, call the Tween
object’s animate()
method and pass it the Animation
object that you want to modify.
For this example, a FadeTransition
widget is used and the opacity
property is
mapped to the animation
object.
To start the animation, use controller.forward()
.
Other operations can also be performed using the
controller such as fling()
or repeat()
.
For this example, the FlutterLogo
widget is used inside the FadeTransition
widget.
import 'package:flutter/material.dart';
void main() {
runApp(const Center(child: LogoFade()));
}
class LogoFade extends StatefulWidget {
const LogoFade({super.key});
@override
State<LogoFade> createState() => _LogoFadeState();
}
class _LogoFadeState extends State<LogoFade>
with SingleTickerProviderStateMixin {
late Animation<double> animation;
late AnimationController controller;
@override
void initState() {
super.initState();
controller = AnimationController(
duration: const Duration(milliseconds: 3000),
vsync: this,
);
final CurvedAnimation curve = CurvedAnimation(
parent: controller,
curve: Curves.easeIn,
);
animation = Tween(begin: 0.0, end: 1.0).animate(curve);
controller.forward();
}
@override
void dispose() {
controller.dispose();
super.dispose();
}
@override
Widget build(BuildContext context) {
return FadeTransition(
opacity: animation,
child: const SizedBox(
height: 300.0,
width: 300.0,
child: FlutterLogo(),
),
);
}
}
How do I add swipe animation to cards?
In React Native, either the PanResponder
or
third-party libraries are used for swipe animation.
In Flutter, to add a swipe animation, use the
Dismissible
widget and nest the child widgets.
return Dismissible(
key: Key(widget.key.toString()),
onDismissed: (dismissDirection) {
cards.removeLast();
},
child: Container(
//...
),
);
React Native and Flutter widget equivalent components
The following table lists commonly-used React Native components mapped to the corresponding Flutter widget and common widget properties.
React Native Component | Flutter Widget | Description |
---|---|---|
Button |
ElevatedButton |
A basic raised button. |
onPressed [required] | The callback when the button is tapped or otherwise activated. | |
Child | The button’s label. | |
Button |
TextButton |
A basic flat button. |
onPressed [required] | The callback when the button is tapped or otherwise activated. | |
Child | The button’s label. | |
ScrollView |
ListView |
A scrollable list of widgets arranged linearly. |
children | ( <Widget> [ ]) List of child widgets to display. | |
controller | [ ScrollController ] An object that can be used to control a scrollable widget. |
|
itemExtent | [ double ] If non-null, forces the children to have the given extent in the scroll direction. | |
scroll Direction | [ Axis ] The axis along which the scroll view scrolls. |
|
FlatList |
ListView.builder |
The constructor for a linear array of widgets that are created on demand. |
itemBuilder [required] | [IndexedWidgetBuilder ] helps in building the children on demand. This callback is called only with indices greater than or equal to zero and less than the itemCount. |
|
itemCount | [ int ] improves the ability of the ListView to estimate the maximum scroll extent. |
|
Image |
Image |
A widget that displays an image. |
image [required] | The image to display. | |
Image. asset | Several constructors are provided for the various ways that an image can be specified. | |
width, height, color, alignment | The style and layout for the image. | |
fit | Inscribing the image into the space allocated during layout. | |
Modal |
ModalRoute |
A route that blocks interaction with previous routes. |
animation | The animation that drives the route’s transition and the previous route’s forward transition. | |
ActivityIndicator |
CircularProgressIndicator |
A widget that shows progress along a circle. |
strokeWidth | The width of the line used to draw the circle. | |
backgroundColor | The progress indicator’s background color. The current theme’s ThemeData.backgroundColor by default. |
|
ActivityIndicator |
LinearProgressIndicator |
A widget that shows progress along a line. |
value | The value of this progress indicator. | |
RefreshControl |
RefreshIndicator |
A widget that supports the Material “swipe to refresh” idiom. |
color | The progress indicator’s foreground color. | |
onRefresh | A function that’s called when a user drags the refresh indicator far enough to demonstrate that they want the app to refresh. | |
View |
Container |
A widget that surrounds a child widget. |
View |
Column |
A widget that displays its children in a vertical array. |
View |
Row |
A widget that displays its children in a horizontal array. |
View |
Center |
A widget that centers its child within itself. |
View |
Padding |
A widget that insets its child by the given padding. |
padding [required] | [ EdgeInsets ] The amount of space to inset the child. | |
TouchableOpacity |
GestureDetector |
A widget that detects gestures. |
onTap | A callback when a tap occurs. | |
onDoubleTap | A callback when a tap occurs at the same location twice in quick succession. | |
TextInput |
TextInput |
The interface to the system’s text input control. |
controller | [ TextEditingController ] used to access and modify text. |
|
Text |
Text |
The Text widget that displays a string of text with a single style. |
data | [ String ] The text to display. | |
textDirection | [ TextAlign ] The direction in which the text flows. |
|
Switch |
Switch |
A material design switch. |
value [required] | [ boolean ] Whether this switch is on or off. | |
onChanged [required] | [ callback ] Called when the user toggles the switch on or off. | |
Slider |
Slider |
Used to select from a range of values. |
value [required] | [ double ] The current value of the slider. | |
onChanged [required] | Called when the user selects a new value for the slider. |