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React has a powerful composition model, and we recommend using composition instead of inheritance to reuse code between components.
In this section, we will consider a few problems where developers new to React often reach for inheritance, and show how we can solve them with composition.
Some components don’t know their children ahead of time. This is especially common for components like
Sidebar
or
Dialog
that represent generic “boxes”.
We recommend that such components use the special
children
prop to pass children elements directly into their output:
function FancyBorder(props) {
return (
<div className={'FancyBorder FancyBorder-' + props.color}>
{props.children} </div>
);
}
This lets other components pass arbitrary children to them by nesting the JSX:
function WelcomeDialog() {
return (
<FancyBorder color="blue">
<h1 className="Dialog-title"> Welcome </h1> <p className="Dialog-message"> Thank you for visiting our spacecraft! </p> </FancyBorder>
);
}
Try it on CodePen
Anything inside the
<FancyBorder>
JSX tag gets passed into the
FancyBorder
component as a
children
prop. Since
FancyBorder
renders
{props.children}
inside a
<div>
, the passed elements appear in the final output.
While this is less common, sometimes you might need multiple “holes” in a component. In such cases you may come up with your own convention instead of using
children
:
function SplitPane(props) {
return (
<div className="SplitPane">
<div className="SplitPane-left">
{props.left} </div>
<div className="SplitPane-right">
{props.right} </div>
</div>
);
}
function App() {
return (
<SplitPane
left={
<Contacts /> }
right={
<Chat /> } />
);
}
Try it on CodePen
React elements like
<Contacts />
and
<Chat />
are just objects, so you can pass them as props like any other data. This approach may remind you of “slots” in other libraries but there are no limitations on what you can pass as props in React.
Sometimes we think about components as being “special cases” of other components. For example, we might say that a
WelcomeDialog
is a special case of
Dialog
.
In React, this is also achieved by composition, where a more “specific” component renders a more “generic” one and configures it with props:
function Dialog(props) {
return (
<FancyBorder color="blue">
<h1 className="Dialog-title">
{props.title} </h1>
<p className="Dialog-message">
{props.message} </p>
</FancyBorder>
);
}
function WelcomeDialog() {
return (
<Dialog title="Welcome" message="Thank you for visiting our spacecraft!" /> );
}
Try it on CodePen
Composition works equally well for components defined as classes:
function Dialog(props) {
return (
<FancyBorder color="blue">
<h1 className="Dialog-title">
{props.title}
</h1>
<p className="Dialog-message">
{props.message}
</p>
{props.children} </FancyBorder>
);
}
class SignUpDialog extends React.Component {
constructor(props) {
super(props);
this.handleChange = this.handleChange.bind(this);
this.handleSignUp = this.handleSignUp.bind(this);
this.state = {login: ''};
}
render() {
return (
<Dialog title="Mars Exploration Program"
message="How should we refer to you?">
<input value={this.state.login} onChange={this.handleChange} /> <button onClick={this.handleSignUp}> Sign Me Up! </button> </Dialog>
);
}
handleChange(e) {
this.setState({login: e.target.value});
}
handleSignUp() {
alert(`Welcome aboard, ${this.state.login}!`);
}
}
Try it on CodePen
At Facebook, we use React in thousands of components, and we haven’t found any use cases where we would recommend creating component inheritance hierarchies.
Props and composition give you all the flexibility you need to customize a component’s look and behavior in an explicit and safe way. Remember that components may accept arbitrary props, including primitive values, React elements, or functions.
If you want to reuse non-UI functionality between components, we suggest extracting it into a separate JavaScript module. The components may import it and use that function, object, or class, without extending it.
React is, in our opinion, the premier way to build big, fast Web apps with JavaScript. It has scaled very well for us at Facebook and Instagram.
One of the many great parts of React is how it makes you think about apps as you build them. In this document, we’ll walk you through the thought process of building a searchable product data table using React.
Imagine that we already have a JSON API and a mock from our designer. The mock looks like this:
Our JSON API returns some data that looks like this:
[
{category: "Sporting Goods", price: "$49.99", stocked: true, name: "Football"},
{category: "Sporting Goods", price: "$9.99", stocked: true, name: "Baseball"},
{category: "Sporting Goods", price: "$29.99", stocked: false, name: "Basketball"},
{category: "Electronics", price: "$99.99", stocked: true, name: "iPod Touch"},
{category: "Electronics", price: "$399.99", stocked: false, name: "iPhone 5"},
{category: "Electronics", price: "$199.99", stocked: true, name: "Nexus 7"}
];
The first thing you’ll want to do is to draw boxes around every component (and subcomponent) in the mock and give them all names. If you’re working with a designer, they may have already done this, so go talk to them! Their Photoshop layer names may end up being the names of your React components!
But how do you know what should be its own component? Use the same techniques for deciding if you should create a new function or object. One such technique is the single responsibility principle, that is, a component should ideally only do one thing. If it ends up growing, it should be decomposed into smaller subcomponents.
Since you’re often displaying a JSON data model to a user, you’ll find that if your model was built correctly, your UI (and therefore your component structure) will map nicely. That’s because UI and data models tend to adhere to the same information architecture . Separate your UI into components, where each component matches one piece of your data model.
You’ll see here that we have five components in our app. We’ve italicized the data each component represents. The numbers in the image correspond to the numbers below.
FilterableProductTable
(orange):
contains the entirety of the example
SearchBar
(blue):
receives all
user input
ProductTable
(green):
displays and filters the
data collection
based on
user input
ProductCategoryRow
(turquoise):
displays a heading for each
category
ProductRow
(red):
displays a row for each
product
If you look at
ProductTable
, you’ll see that the table header (containing the “Name” and “Price” labels) isn’t its own component. This is a matter of preference, and there’s an argument to be made either way. For this example, we left it as part of
ProductTable
because it is part of rendering the
data collection
which is
ProductTable
’s responsibility. However, if this header grows to be complex (e.g., if we were to add affordances for sorting), it would certainly make sense to make this its own
ProductTableHeader
component.
Now that we’ve identified the components in our mock, let’s arrange them into a hierarchy. Components that appear within another component in the mock should appear as a child in the hierarchy:
FilterableProductTable
SearchBar
ProductTable
ProductCategoryRow
ProductRow
See the Pen Thinking In React: Step 2 on CodePen.
Now that you have your component hierarchy, it’s time to implement your app. The easiest way is to build a version that takes your data model and renders the UI but has no interactivity. It’s best to decouple these processes because building a static version requires a lot of typing and no thinking, and adding interactivity requires a lot of thinking and not a lot of typing. We’ll see why.
To build a static version of your app that renders your data model, you’ll want to build components that reuse other components and pass data using props . props are a way of passing data from parent to child. If you’re familiar with the concept of state , don’t use state at all to build this static version. State is reserved only for interactivity, that is, data that changes over time. Since this is a static version of the app, you don’t need it.
You can build top-down or bottom-up. That is, you can either start with building the components higher up in the hierarchy (i.e. starting with
FilterableProductTable
) or with the ones lower in it (
ProductRow
). In simpler examples, it’s usually easier to go top-down, and on larger projects, it’s easier to go bottom-up and write tests as you build.
At the end of this step, you’ll have a library of reusable components that render your data model. The components will only have
render()
methods since this is a static version of your app. The component at the top of the hierarchy (
FilterableProductTable
) will take your data model as a prop. If you make a change to your underlying data model and call
root.render()
again, the UI will be updated. You can see how your UI is updated and where to make changes. React’s
one-way data flow
(also called
one-way binding
) keeps everything modular and fast.
Refer to the React docs if you need help executing this step.
There are two types of “model” data in React: props and state. It’s important to understand the distinction between the two; skim the official React docs if you aren’t sure what the difference is. See also FAQ: What is the difference between state and props?
To make your UI interactive, you need to be able to trigger changes to your underlying data model. React achieves this with state .
To build your app correctly, you first need to think of the minimal set of mutable state that your app needs. The key here is DRY: Don’t Repeat Yourself . Figure out the absolute minimal representation of the state your application needs and compute everything else you need on-demand. For example, if you’re building a TODO list, keep an array of the TODO items around; don’t keep a separate state variable for the count. Instead, when you want to render the TODO count, take the length of the TODO items array.
Think of all the pieces of data in our example application. We have:
Let’s go through each one and figure out which one is state. Ask three questions about each piece of data:
The original list of products is passed in as props, so that’s not state. The search text and the checkbox seem to be state since they change over time and can’t be computed from anything. And finally, the filtered list of products isn’t state because it can be computed by combining the original list of products with the search text and value of the checkbox.
So finally, our state is:
See the Pen Thinking In React: Step 4 on CodePen.
OK, so we’ve identified what the minimal set of app state is. Next, we need to identify which component mutates, or owns , this state.
Remember: React is all about one-way data flow down the component hierarchy. It may not be immediately clear which component should own what state. This is often the most challenging part for newcomers to understand, so follow these steps to figure it out:
For each piece of state in your application:
Let’s run through this strategy for our application:
ProductTable
needs to filter the product list based on state and
SearchBar
needs to display the search text and checked state.
FilterableProductTable
.
FilterableProductTable
Cool, so we’ve decided that our state lives in
FilterableProductTable
. First, add an instance property
this.state = {filterText: '', inStockOnly: false}
to
FilterableProductTable
’s
constructor
to reflect the initial state of your application. Then, pass
filterText
and
inStockOnly
to
ProductTable
and
SearchBar
as a prop. Finally, use these props to filter the rows in
ProductTable
and set the values of the form fields in
SearchBar
.
You can start seeing how your application will behave: set
filterText
to
"ball"
and refresh your app. You’ll see that the data table is updated correctly.
See the Pen Thinking In React: Step 5 on CodePen.
So far, we’ve built an app that renders correctly as a function of props and state flowing down the hierarchy. Now it’s time to support data flowing the other way: the form components deep in the hierarchy need to update the state in
FilterableProductTable
.
React makes this data flow explicit to help you understand how your program works, but it does require a little more typing than traditional two-way data binding.
If you try to type or check the box in the previous version of the example (step 4), you’ll see that React ignores your input. This is intentional, as we’ve set the
value
prop of the
input
to always be equal to the
state
passed in from
FilterableProductTable
.
Let’s think about what we want to happen. We want to make sure that whenever the user changes the form, we update the state to reflect the user input. Since components should only update their own state,
FilterableProductTable
will pass callbacks to
SearchBar
that will fire whenever the state should be updated. We can use the
onChange
event on the inputs to be notified of it. The callbacks passed by
FilterableProductTable
will call
setState()
, and the app will be updated.
Hopefully, this gives you an idea of how to think about building components and applications with React. While it may be a little more typing than you’re used to, remember that code is read far more often than it’s written, and it’s less difficult to read this modular, explicit code. As you start to build large libraries of components, you’ll appreciate this explicitness and modularity, and with code reuse, your lines of code will start to shrink. :)
Web accessibility (also referred to as a11y ) is the design and creation of websites that can be used by everyone. Accessibility support is necessary to allow assistive technology to interpret web pages.
React fully supports building accessible websites, often by using standard HTML techniques.
The Web Content Accessibility Guidelines provides guidelines for creating accessible web sites.
The following WCAG checklists provide an overview:
The Web Accessibility Initiative - Accessible Rich Internet Applications document contains techniques for building fully accessible JavaScript widgets.
Note that all
aria-*
HTML attributes are fully supported in JSX. Whereas most DOM properties and attributes in React are camelCased, these attributes should be hyphen-cased (also known as kebab-case, lisp-case, etc) as they are in plain HTML:
<input
type="text"
aria-label={labelText} aria-required="true" onChange={onchangeHandler}
value={inputValue}
name="name"
/>
Semantic HTML is the foundation of accessibility in a web application. Using the various HTML elements to reinforce the meaning of information
in our websites will often give us accessibility for free.
Sometimes we break HTML semantics when we add
<div>
elements to our JSX to make our React code work, especially when working with lists (
<ol>
,
<ul>
and
<dl>
) and the HTML
<table>
.
In these cases we should rather use React Fragments to group together multiple elements.
For example,
import React, { Fragment } from 'react';
function ListItem({ item }) {
return (
<Fragment> <dt>{item.term}</dt>
<dd>{item.description}</dd>
</Fragment> );
}
function Glossary(props) {
return (
<dl>
{props.items.map(item => (
<ListItem item={item} key={item.id} />
))}
</dl>
);
}
You can map a collection of items to an array of fragments as you would any other type of element as well:
function Glossary(props) {
return (
<dl>
{props.items.map(item => (
// Fragments should also have a `key` prop when mapping collections
<Fragment key={item.id}> <dt>{item.term}</dt>
<dd>{item.description}</dd>
</Fragment> ))}
</dl>
);
}
When you don’t need any props on the Fragment tag you can use the short syntax, if your tooling supports it:
function ListItem({ item }) {
return (
<> <dt>{item.term}</dt>
<dd>{item.description}</dd>
</> );
}
For more info, see the Fragments documentation.
Every HTML form control, such as
<input>
and
<textarea>
, needs to be labeled accessibly. We need to provide descriptive labels that are also exposed to screen readers.
The following resources show us how to do this:
Although these standard HTML practices can be directly used in React, note that the
for
attribute is written as
htmlFor
in JSX:
<label htmlFor="namedInput">Name:</label><input id="namedInput" type="text" name="name"/>
Error situations need to be understood by all users. The following link shows us how to expose error texts to screen readers as well:
Ensure that your web application can be fully operated with the keyboard only:
Keyboard focus refers to the current element in the DOM that is selected to accept input from the keyboard. We see it everywhere as a focus outline similar to that shown in the following image:
Only ever use CSS that removes this outline, for example by setting
outline: 0
, if you are replacing it with another focus outline implementation.
Provide a mechanism to allow users to skip past navigation sections in your application as this assists and speeds up keyboard navigation.
Skiplinks or Skip Navigation Links are hidden navigation links that only become visible when keyboard users interact with the page. They are very easy to implement with internal page anchors and some styling:
Also use landmark elements and roles, such as
<main>
and
<aside>
, to demarcate page regions as assistive technology allow the user to quickly navigate to these sections.
Read more about the use of these elements to enhance accessibility here:
Our React applications continuously modify the HTML DOM during runtime, sometimes leading to keyboard focus being lost or set to an unexpected element. In order to repair this, we need to programmatically nudge the keyboard focus in the right direction. For example, by resetting keyboard focus to a button that opened a modal window after that modal window is closed.
MDN Web Docs takes a look at this and describes how we can build keyboard-navigable JavaScript widgets.
To set focus in React, we can use Refs to DOM elements.
Using this, we first create a ref to an element in the JSX of a component class:
class CustomTextInput extends React.Component {
constructor(props) {
super(props);
// Create a ref to store the textInput DOM element this.textInput = React.createRef(); }
render() {
// Use the `ref` callback to store a reference to the text input DOM // element in an instance field (for example, this.textInput). return (
<input
type="text"
ref={this.textInput} />
);
}
}
Then we can focus it elsewhere in our component when needed:
focus() {
// Explicitly focus the text input using the raw DOM API
// Note: we're accessing "current" to get the DOM node
this.textInput.current.focus();
}
Sometimes a parent component needs to set focus to an element in a child component. We can do this by exposing DOM refs to parent components through a special prop on the child component that forwards the parent’s ref to the child’s DOM node.
function CustomTextInput(props) {
return (
<div>
<input ref={props.inputRef} /> </div>
);
}
class Parent extends React.Component {
constructor(props) {
super(props);
this.inputElement = React.createRef(); }
render() {
return (
<CustomTextInput inputRef={this.inputElement} /> );
}
}
// Now you can set focus when required.
this.inputElement.current.focus();
When using a HOC to extend components, it is recommended to forward the ref to the wrapped component using the
forwardRef
function of React. If a third party HOC does not implement ref forwarding, the above pattern can still be used as a fallback.
A great focus management example is the react-aria-modal. This is a relatively rare example of a fully accessible modal window. Not only does it set initial focus on
the cancel button (preventing the keyboard user from accidentally activating the success action) and trap keyboard focus inside the modal, it also resets focus back to the element that initially triggered the modal.
Note:
While this is a very important accessibility feature, it is also a technique that should be used judiciously. Use it to repair the keyboard focus flow when it is disturbed, not to try and anticipate how
users want to use applications.
Ensure that all functionality exposed through a mouse or pointer event can also be accessed using the keyboard alone. Depending only on the pointer device will lead to many cases where keyboard users cannot use your application.
To illustrate this, let’s look at a prolific example of broken accessibility caused by click events. This is the outside click pattern, where a user can disable an opened popover by clicking outside the element.
This is typically implemented by attaching a
click
event to the
window
object that closes the popover:
class OuterClickExample extends React.Component {
constructor(props) {
super(props);
this.state = { isOpen: false };
this.toggleContainer = React.createRef();
this.onClickHandler = this.onClickHandler.bind(this);
this.onClickOutsideHandler = this.onClickOutsideHandler.bind(this);
}
componentDidMount() { window.addEventListener('click', this.onClickOutsideHandler); }
componentWillUnmount() {
window.removeEventListener('click', this.onClickOutsideHandler);
}
onClickHandler() {
this.setState(currentState => ({
isOpen: !currentState.isOpen
}));
}
onClickOutsideHandler(event) { if (this.state.isOpen && !this.toggleContainer.current.contains(event.target)) { this.setState({ isOpen: false }); } }
render() {
return (
<div ref={this.toggleContainer}>
<button onClick={this.onClickHandler}>Select an option</button>
{this.state.isOpen && (
<ul>
<li>Option 1</li>
<li>Option 2</li>
<li>Option 3</li>
</ul>
)}
</div>
);
}
}
This may work fine for users with pointer devices, such as a mouse, but operating this with the keyboard alone leads to broken functionality when tabbing to the next element as the
window
object never receives a
click
event. This can lead to obscured functionality which blocks users from using your application.
The same functionality can be achieved by using appropriate event handlers instead, such as
onBlur
and
onFocus
:
class BlurExample extends React.Component {
constructor(props) {
super(props);
this.state = { isOpen: false };
this.timeOutId = null;
this.onClickHandler = this.onClickHandler.bind(this);
this.onBlurHandler = this.onBlurHandler.bind(this);
this.onFocusHandler = this.onFocusHandler.bind(this);
}
onClickHandler() {
this.setState(currentState => ({
isOpen: !currentState.isOpen
}));
}
// We close the popover on the next tick by using setTimeout. // This is necessary because we need to first check if // another child of the element has received focus as // the blur event fires prior to the new focus event. onBlurHandler() { this.timeOutId = setTimeout(() => { this.setState({ isOpen: false }); }); }
// If a child receives focus, do not close the popover. onFocusHandler() { clearTimeout(this.timeOutId); }
render() {
// React assists us by bubbling the blur and // focus events to the parent. return (
<div onBlur={this.onBlurHandler} onFocus={this.onFocusHandler}> <button onClick={this.onClickHandler}
aria-haspopup="true"
aria-expanded={this.state.isOpen}>
Select an option
</button>
{this.state.isOpen && (
<ul>
<li>Option 1</li>
<li>Option 2</li>
<li>Option 3</li>
</ul>
)}
</div>
);
}
}
This code exposes the functionality to both pointer device and keyboard users. Also note the added
aria-*
props to support screen-reader users. For simplicity’s sake the keyboard events to enable
arrow key
interaction of the popover options have not been implemented.
This is one example of many cases where depending on only pointer and mouse events will break functionality for keyboard users. Always testing with the keyboard will immediately highlight the problem areas which can then be fixed by using keyboard aware event handlers.
A more complex user experience should not mean a less accessible one. Whereas accessibility is most easily achieved by coding as close to HTML as possible, even the most complex widget can be coded accessibly.
Here we require knowledge of ARIA Roles as well as ARIA States and Properties.
These are toolboxes filled with HTML attributes that are fully supported in JSX and enable us to construct fully accessible, highly functional React components.
Each type of widget has a specific design pattern and is expected to function in a certain way by users and user agents alike:
Indicate the human language of page texts as screen reader software uses this to select the correct voice settings:
Set the document
<title>
to correctly describe the current page content as this ensures that the user remains aware of the current page context:
We can set this in React using the React Document Title Component.
Ensure that all readable text on your website has sufficient color contrast to remain maximally readable by users with low vision:
It can be tedious to manually calculate the proper color combinations for all cases in your website so instead, you can calculate an entire accessible color palette with Colorable.
Both the aXe and WAVE tools mentioned below also include color contrast tests and will report on contrast errors.
If you want to extend your contrast testing abilities you can use these tools:
There are a number of tools we can use to assist in the creation of accessible web applications.
By far the easiest and also one of the most important checks is to test if your entire website can be reached and used with the keyboard alone. Do this by:
Tab
and
Shift+Tab
to browse.
Enter
to activate elements.
We can check some accessibility features directly in our JSX code. Often intellisense checks are already provided in JSX aware IDE’s for the ARIA roles, states and properties. We also have access to the following tool:
The eslint-plugin-jsx-a11y plugin for ESLint provides AST linting feedback regarding accessibility issues in your JSX. Many IDE’s allow you to integrate these findings directly into code analysis and source code windows.
Create React App has this plugin with a subset of rules activated. If you want to enable even more accessibility rules, you can create an
.eslintrc
file in the root of your project with this content:
{
"extends": ["react-app", "plugin:jsx-a11y/recommended"],
"plugins": ["jsx-a11y"]
}
A number of tools exist that can run accessibility audits on web pages in your browser. Please use them in combination with other accessibility checks mentioned here as they can only
test the technical accessibility of your HTML.
Deque Systems offers aXe-core for automated and end-to-end accessibility tests of your applications. This module includes integrations for Selenium.
The Accessibility Engine or aXe, is an accessibility inspector browser extension built on
aXe-core
.
You can also use the @axe-core/react module to report these accessibility findings directly to the console while developing and debugging.
The Web Accessibility Evaluation Tool is another accessibility browser extension.
The Accessibility Tree is a subset of the DOM tree that contains accessible objects for every DOM element that should be exposed
to assistive technology, such as screen readers.
In some browsers we can easily view the accessibility information for each element in the accessibility tree:
Testing with a screen reader should form part of your accessibility tests.
Please note that browser / screen reader combinations matter. It is recommended that you test your application in the browser best suited to your screen reader of choice.
NonVisual Desktop Access or NVDA is an open source Windows screen reader that is widely used.
Refer to the following guides on how to best use NVDA:
VoiceOver is an integrated screen reader on Apple devices.
Refer to the following guides on how to activate and use VoiceOver:
Job Access With Speech or JAWS, is a prolifically used screen reader on Windows.
Refer to the following guides on how to best use JAWS:
ChromeVox is an integrated screen reader on Chromebooks and is available as an extension for Google Chrome.
Refer to the following guides on how best to use ChromeVox:
Most React apps will have their files “bundled” using tools like Webpack, Rollup or Browserify. Bundling is the process of following imported files and merging them into a single file: a “bundle”. This bundle can then be included on a webpage to load an entire app at once.
App:
// app.js
import { add } from './math.js';
console.log(add(16, 26)); // 42
// math.js
export function add(a, b) {
return a + b;
}
Bundle:
function add(a, b) {
return a + b;
}
console.log(add(16, 26)); // 42
Note:
Your bundles will end up looking a lot different than this.
If you’re using Create React App, Next.js, Gatsby, or a similar tool, you will have a Webpack setup out of the box to bundle your app.
If you aren’t, you’ll need to set up bundling yourself. For example, see the Installation and Getting Started guides on the Webpack docs.
Bundling is great, but as your app grows, your bundle will grow too. Especially if you are including large third-party libraries. You need to keep an eye on the code you are including in your bundle so that you don’t accidentally make it so large that your app takes a long time to load.
To avoid winding up with a large bundle, it’s good to get ahead of the problem and start “splitting” your bundle. Code-Splitting is a feature
supported by bundlers like Webpack, Rollup and Browserify (via factor-bundle) which can create multiple bundles that can be dynamically loaded at runtime.
Code-splitting your app can help you “lazy-load” just the things that are currently needed by the user, which can dramatically improve the performance of your app. While you haven’t reduced the overall amount of code in your app, you’ve avoided loading code that the user may never need, and reduced the amount of code needed during the initial load.
import()
The best way to introduce code-splitting into your app is through the dynamic
import()
syntax.
Before:
import { add } from './math';
console.log(add(16, 26));
After:
import("./math").then(math => {
console.log(math.add(16, 26));
});
When Webpack comes across this syntax, it automatically starts code-splitting your app. If you’re using Create React App, this is already configured for you and you can start using it immediately. It’s also supported out of the box in Next.js.
If you’re setting up Webpack yourself, you’ll probably want to read Webpack’s guide on code splitting. Your Webpack config should look vaguely like this.
When using Babel, you’ll need to make sure that Babel can parse the dynamic import syntax but is not transforming it. For that you will need @babel/plugin-syntax-dynamic-import.
React.lazy
The
React.lazy
function lets you render a dynamic import as a regular component.
Before:
import OtherComponent from './OtherComponent';
After:
const OtherComponent = React.lazy(() => import('./OtherComponent'));
This will automatically load the bundle containing the
OtherComponent
when this component is first rendered.
React.lazy
takes a function that must call a dynamic
import()
. This must return a
Promise
which resolves to a module with a
default
export containing a React component.
The lazy component should then be rendered inside a
Suspense
component, which allows us to show some fallback content (such as a loading indicator) while we’re waiting for the lazy component to load.
import React, { Suspense } from 'react';
const OtherComponent = React.lazy(() => import('./OtherComponent'));
function MyComponent() {
return (
<div>
<Suspense fallback={<div>Loading...</div>}>
<OtherComponent />
</Suspense>
</div>
);
}
The
fallback
prop accepts any React elements that you want to render while waiting for the component to load. You can place the
Suspense
component anywhere above the lazy component. You can even wrap multiple lazy components with a single
Suspense
component.
import React, { Suspense } from 'react';
const OtherComponent = React.lazy(() => import('./OtherComponent'));
const AnotherComponent = React.lazy(() => import('./AnotherComponent'));
function MyComponent() {
return (
<div>
<Suspense fallback={<div>Loading...</div>}>
<section>
<OtherComponent />
<AnotherComponent />
</section>
</Suspense>
</div>
);
}
Any component may suspend as a result of rendering, even components that were already shown to the user. In order for screen content to always be consistent, if an already shown component suspends, React has to hide its tree up to the closest
<Suspense>
boundary. However, from the user’s perspective, this can be disorienting.
Consider this tab switcher:
import React, { Suspense } from 'react';
import Tabs from './Tabs';
import Glimmer from './Glimmer';
const Comments = React.lazy(() => import('./Comments'));
const Photos = React.lazy(() => import('./Photos'));
function MyComponent() {
const [tab, setTab] = React.useState('photos');
function handleTabSelect(tab) {
setTab(tab);
};
return (
<div>
<Tabs onTabSelect={handleTabSelect} />
<Suspense fallback={<Glimmer />}>
{tab === 'photos' ? <Photos /> : <Comments />}
</Suspense>
</div>
);
}
In this example, if tab gets changed from
'photos'
to
'comments'
, but
Comments
suspends, the user will see a glimmer. This makes sense because the user no longer wants to see
Photos
, the
Comments
component is not ready to render anything, and React needs to keep the user experience consistent, so it has no choice but to show the
Glimmer
above.
However, sometimes this user experience is not desirable. In particular, it is sometimes better to show the “old” UI while the new UI is being prepared. You can use the new
startTransition
API to make React do this:
function handleTabSelect(tab) {
startTransition(() => {
setTab(tab);
});
}
Here, you tell React that setting tab to
'comments'
is not an urgent update, but is a transition that may take some time. React will then keep the old UI in place and interactive, and will switch to showing
<Comments />
when it is ready. See Transitions for more info.
If the other module fails to load (for example, due to network failure), it will trigger an error. You can handle these errors to show a nice user experience and manage recovery with Error Boundaries. Once you’ve created your Error Boundary, you can use it anywhere above your lazy components to display an error state when there’s a network error.
import React, { Suspense } from 'react';
import MyErrorBoundary from './MyErrorBoundary';
const OtherComponent = React.lazy(() => import('./OtherComponent'));
const AnotherComponent = React.lazy(() => import('./AnotherComponent'));
const MyComponent = () => (
<div>
<MyErrorBoundary>
<Suspense fallback={<div>Loading...</div>}>
<section>
<OtherComponent />
<AnotherComponent />
</section>
</Suspense>
</MyErrorBoundary>
</div>
);
Deciding where in your app to introduce code splitting can be a bit tricky. You want to make sure you choose places that will split bundles evenly, but won’t disrupt the user experience.
A good place to start is with routes. Most people on the web are used to page transitions taking some amount of time to load. You also tend to be re-rendering the entire page at once so your users are unlikely to be interacting with other elements on the page at the same time.
Here’s an example of how to setup route-based code splitting into your app using libraries like React Router with
React.lazy
.
import React, { Suspense, lazy } from 'react';
import { BrowserRouter as Router, Routes, Route } from 'react-router-dom';
const Home = lazy(() => import('./routes/Home'));
const About = lazy(() => import('./routes/About'));
const App = () => (
<Router>
<Suspense fallback={<div>Loading...</div>}>
<Routes>
<Route path="/" element={<Home />} />
<Route path="/about" element={<About />} />
</Routes>
</Suspense>
</Router>
);
React.lazy
currently only supports default exports. If the module you want to import uses named exports, you can create an intermediate module that reexports it as the default. This ensures that tree shaking keeps working and that you don’t pull in unused components.
// ManyComponents.js
export const MyComponent = /* ... */;
export const MyUnusedComponent = /* ... */;
// MyComponent.js
export { MyComponent as default } from "./ManyComponents.js";
// MyApp.js
import React, { lazy } from 'react';
const MyComponent = lazy(() => import("./MyComponent.js"));
Context provides a way to pass data through the component tree without having to pass props down manually at every level.
In a typical React application, data is passed top-down (parent to child) via props, but such usage can be cumbersome for certain types of props (e.g. locale preference, UI theme) that are required by many components within an application. Context provides a way to share values like these between components without having to explicitly pass a prop through every level of the tree.
API
Examples
Context is designed to share data that can be considered “global” for a tree of React components, such as the current authenticated user, theme, or preferred language. For example, in the code below we manually thread through a “theme” prop in order to style the Button component:
class App extends React.Component {
render() {
return <Toolbar theme="dark" />;
}
}
function Toolbar(props) {
// The Toolbar component must take an extra "theme" prop // and pass it to the ThemedButton. This can become painful // if every single button in the app needs to know the theme // because it would have to be passed through all components. return (
<div>
<ThemedButton theme={props.theme} /> </div>
);
}
class ThemedButton extends React.Component {
render() {
return <Button theme={this.props.theme} />;
}
}
Using context, we can avoid passing props through intermediate elements:
// Context lets us pass a value deep into the component tree// without explicitly threading it through every component.// Create a context for the current theme (with "light" as the default).const ThemeContext = React.createContext('light');
class App extends React.Component {
render() {
// Use a Provider to pass the current theme to the tree below. // Any component can read it, no matter how deep it is. // In this example, we're passing "dark" as the current value. return (
<ThemeContext.Provider value="dark"> <Toolbar />
</ThemeContext.Provider>
);
}
}
// A component in the middle doesn't have to// pass the theme down explicitly anymore.function Toolbar() {
return (
<div>
<ThemedButton />
</div>
);
}
class ThemedButton extends React.Component {
// Assign a contextType to read the current theme context. // React will find the closest theme Provider above and use its value. // In this example, the current theme is "dark". static contextType = ThemeContext;
render() {
return <Button theme={this.context} />; }
}
Context is primarily used when some data needs to be accessible by many components at different nesting levels. Apply it sparingly because it makes component reuse more difficult.
If you only want to avoid passing some props through many levels, component composition is often a simpler solution than context.
For example, consider a
Page
component that passes a
user
and
avatarSize
prop several levels down so that deeply nested
Link
and
Avatar
components can read it:
<Page user={user} avatarSize={avatarSize} />
// ... which renders ...
<PageLayout user={user} avatarSize={avatarSize} />
// ... which renders ...
<NavigationBar user={user} avatarSize={avatarSize} />
// ... which renders ...
<Link href={user.permalink}>
<Avatar user={user} size={avatarSize} />
</Link>
It might feel redundant to pass down the
user
and
avatarSize
props through many levels if in the end only the
Avatar
component really needs it. It’s also annoying that whenever the
Avatar
component needs more props from the top, you have to add them at all the intermediate levels too.
One way to solve this issue
without context
is to pass down the
Avatar
component itself so that the intermediate components don’t need to know about the
user
or
avatarSize
props:
function Page(props) {
const user = props.user;
const userLink = (
<Link href={user.permalink}>
<Avatar user={user} size={props.avatarSize} />
</Link>
);
return <PageLayout userLink={userLink} />;
}
// Now, we have:
<Page user={user} avatarSize={avatarSize} />
// ... which renders ...
<PageLayout userLink={...} />
// ... which renders ...
<NavigationBar userLink={...} />
// ... which renders ...
{props.userLink}
With this change, only the top-most Page component needs to know about the
Link
and
Avatar
components’ use of
user
and
avatarSize
.
This inversion of control can make your code cleaner in many cases by reducing the amount of props you need to pass through your application and giving more control to the root components. Such inversion, however, isn’t the right choice in every case; moving more complexity higher in the tree makes those higher-level components more complicated and forces the lower-level components to be more flexible than you may want.
You’re not limited to a single child for a component. You may pass multiple children, or even have multiple separate “slots” for children, as documented here:
function Page(props) {
const user = props.user;
const content = <Feed user={user} />;
const topBar = (
<NavigationBar>
<Link href={user.permalink}>
<Avatar user={user} size={props.avatarSize} />
</Link>
</NavigationBar>
);
return (
<PageLayout
topBar={topBar}
content={content}
/>
);
}
This pattern is sufficient for many cases when you need to decouple a child from its immediate parents. You can take it even further with render props if the child needs to communicate with the parent before rendering.
However, sometimes the same data needs to be accessible by many components in the tree, and at different nesting levels. Context lets you “broadcast” such data, and changes to it, to all components below. Common examples where using context might be simpler than the alternatives include managing the current locale, theme, or a data cache.
React.createContext
const MyContext = React.createContext(defaultValue);
Creates a Context object. When React renders a component that subscribes to this Context object it will read the current context value from the closest matching
Provider
above it in the tree.
The
defaultValue
argument is
only
used when a component does not have a matching Provider above it in the tree. This default value can be helpful for testing components in isolation without wrapping them. Note: passing
undefined
as a Provider value does not cause consuming components to use
defaultValue
.
Context.Provider
<MyContext.Provider value={/* some value */}>
Every Context object comes with a Provider React component that allows consuming components to subscribe to context changes.
The Provider component accepts a
value
prop to be passed to consuming components that are descendants of this Provider. One Provider can be connected to many consumers. Providers can be nested to override values deeper within the tree.
All consumers that are descendants of a Provider will re-render whenever the Provider’s
value
prop changes. The propagation from Provider to its descendant consumers (including
.contextType
and
useContext
) is not subject to the
shouldComponentUpdate
method, so the consumer is updated even when an ancestor component skips an update.
Changes are determined by comparing the new and old values using the same algorithm as
Object.is
.
Note
The way changes are determined can cause some issues when passing objects as
value
: see Caveats.
Class.contextType
class MyClass extends React.Component {
componentDidMount() {
let value = this.context;
/* perform a side-effect at mount using the value of MyContext */
}
componentDidUpdate() {
let value = this.context;
/* ... */
}
componentWillUnmount() {
let value = this.context;
/* ... */
}
render() {
let value = this.context;
/* render something based on the value of MyContext */
}
}
MyClass.contextType = MyContext;
The
contextType
property on a class can be assigned a Context object created by
React.createContext()
. Using this property lets you consume the nearest current value of that Context type using
this.context
. You can reference this in any of the lifecycle methods including the render function.
Note:
You can only subscribe to a single context using this API. If you need to read more than one see Consuming Multiple Contexts.
If you are using the experimental public class fields syntax, you can use a static class field to initialize your
contextType
.
class MyClass extends React.Component {
static contextType = MyContext;
render() {
let value = this.context;
/* render something based on the value */
}
}
Context.Consumer
<MyContext.Consumer>
{value => /* render something based on the context value */}
</MyContext.Consumer>
A React component that subscribes to context changes. Using this component lets you subscribe to a context within a function component.
Requires a function as a child. The function receives the current context value and returns a React node. The
value
argument passed to the function will be equal to the
value
prop of the closest Provider for this context above in the tree. If there is no Provider for this context above, the
value
argument will be equal to the
defaultValue
that was passed to
createContext()
.
Note
For more information about the ‘function as a child’ pattern, see render props.
Context.displayName
Context object accepts a
displayName
string property. React DevTools uses this string to determine what to display for the context.
For example, the following component will appear as MyDisplayName in the DevTools:
const MyContext = React.createContext(/* some value */);
MyContext.displayName = 'MyDisplayName';
<MyContext.Provider> // "MyDisplayName.Provider" in DevTools
<MyContext.Consumer> // "MyDisplayName.Consumer" in DevTools
A more complex example with dynamic values for the theme:
theme-context.js
export const themes = {
light: {
foreground: '#000000',
background: '#eeeeee',
},
dark: {
foreground: '#ffffff',
background: '#222222',
},
};
export const ThemeContext = React.createContext( themes.dark // default value);
themed-button.js
import {ThemeContext} from './theme-context';
class ThemedButton extends React.Component {
render() {
let props = this.props;
let theme = this.context; return (
<button
{...props}
style={{backgroundColor: theme.background}}
/>
);
}
}
ThemedButton.contextType = ThemeContext;
export default ThemedButton;
app.js
import {ThemeContext, themes} from './theme-context';
import ThemedButton from './themed-button';
// An intermediate component that uses the ThemedButton
function Toolbar(props) {
return (
<ThemedButton onClick={props.changeTheme}>
Change Theme
</ThemedButton>
);
}
class App extends React.Component {
constructor(props) {
super(props);
this.state = {
theme: themes.light,
};
this.toggleTheme = () => {
this.setState(state => ({
theme:
state.theme === themes.dark
? themes.light
: themes.dark,
}));
};
}
render() {
// The ThemedButton button inside the ThemeProvider // uses the theme from state while the one outside uses // the default dark theme return (
<Page>
<ThemeContext.Provider value={this.state.theme}> <Toolbar changeTheme={this.toggleTheme} /> </ThemeContext.Provider> <Section>
<ThemedButton /> </Section>
</Page>
);
}
}
const root = ReactDOM.createRoot(
document.getElementById('root')
);
root.render(<App />);
It is often necessary to update the context from a component that is nested somewhere deeply in the component tree. In this case you can pass a function down through the context to allow consumers to update the context:
theme-context.js
// Make sure the shape of the default value passed to
// createContext matches the shape that the consumers expect!
export const ThemeContext = React.createContext({
theme: themes.dark, toggleTheme: () => {},});
theme-toggler-button.js
import {ThemeContext} from './theme-context';
function ThemeTogglerButton() {
// The Theme Toggler Button receives not only the theme // but also a toggleTheme function from the context return (
<ThemeContext.Consumer>
{({theme, toggleTheme}) => ( <button
onClick={toggleTheme}
style={{backgroundColor: theme.background}}>
Toggle Theme
</button>
)}
</ThemeContext.Consumer>
);
}
export default ThemeTogglerButton;
app.js
import {ThemeContext, themes} from './theme-context';
import ThemeTogglerButton from './theme-toggler-button';
class App extends React.Component {
constructor(props) {
super(props);
this.toggleTheme = () => {
this.setState(state => ({
theme:
state.theme === themes.dark
? themes.light
: themes.dark,
}));
};
// State also contains the updater function so it will // be passed down into the context provider this.state = {
theme: themes.light,
toggleTheme: this.toggleTheme, };
}
render() {
// The entire state is passed to the provider return (
<ThemeContext.Provider value={this.state}> <Content />
</ThemeContext.Provider>
);
}
}
function Content() {
return (
<div>
<ThemeTogglerButton />
</div>
);
}
const root = ReactDOM.createRoot(
document.getElementById('root')
);
root.render(<App />);
To keep context re-rendering fast, React needs to make each context consumer a separate node in the tree.
// Theme context, default to light theme
const ThemeContext = React.createContext('light');
// Signed-in user context
const UserContext = React.createContext({
name: 'Guest',
});
class App extends React.Component {
render() {
const {signedInUser, theme} = this.props;
// App component that provides initial context values
return (
<ThemeContext.Provider value={theme}> <UserContext.Provider value={signedInUser}> <Layout />
</UserContext.Provider> </ThemeContext.Provider> );
}
}
function Layout() {
return (
<div>
<Sidebar />
<Content />
</div>
);
}
// A component may consume multiple contexts
function Content() {
return (
<ThemeContext.Consumer> {theme => ( <UserContext.Consumer> {user => ( <ProfilePage user={user} theme={theme} /> )} </UserContext.Consumer> )} </ThemeContext.Consumer> );
}
If two or more context values are often used together, you might want to consider creating your own render prop component that provides both.
Because context uses reference identity to determine when to re-render, there are some gotchas that could trigger unintentional renders in consumers when a provider’s parent re-renders. For example, the code below will re-render all consumers every time the Provider re-renders because a new object is always created for
value
:
class App extends React.Component {
render() {
return (
<MyContext.Provider value={{something: 'something'}}> <Toolbar />
</MyContext.Provider>
);
}
}
To get around this, lift the value into the parent’s state:
class App extends React.Component {
constructor(props) {
super(props);
this.state = {
value: {something: 'something'}, };
}
render() {
return (
<MyContext.Provider value={this.state.value}> <Toolbar />
</MyContext.Provider>
);
}
}
Note
React previously shipped with an experimental context API. The old API will be supported in all 16.x releases, but applications using it should migrate to the new version. The legacy API will be removed in a future major React version. Read the legacy context docs here.
In the past, JavaScript errors inside components used to corrupt React’s internal state and cause it to emit cryptic errors on next renders. These errors were always caused by an earlier error in the application code, but React did not provide a way to handle them gracefully in components, and could not recover from them.
A JavaScript error in a part of the UI shouldn’t break the whole app. To solve this problem for React users, React 16 introduces a new concept of an “error boundary”.
Error boundaries are React components that catch JavaScript errors anywhere in their child component tree, log those errors, and display a fallback UI instead of the component tree that crashed. Error boundaries catch errors during rendering, in lifecycle methods, and in constructors of the whole tree below them.
Note
Error boundaries do not catch errors for:
- Event handlers (learn more)
- Asynchronous code (e.g.
setTimeout
orrequestAnimationFrame
callbacks)
- Server side rendering
- Errors thrown in the error boundary itself (rather than its children)
A class component becomes an error boundary if it defines either (or both) of the lifecycle methods
static getDerivedStateFromError()
or
componentDidCatch()
. Use
static getDerivedStateFromError()
to render a fallback UI after an error has been thrown. Use
componentDidCatch()
to log error information.
class ErrorBoundary extends React.Component {
constructor(props) {
super(props);
this.state = { hasError: false };
}
static getDerivedStateFromError(error) { // Update state so the next render will show the fallback UI. return { hasError: true }; }
componentDidCatch(error, errorInfo) { // You can also log the error to an error reporting service logErrorToMyService(error, errorInfo); }
render() {
if (this.state.hasError) { // You can render any custom fallback UI return <h1>Something went wrong.</h1>; }
return this.props.children;
}
}
Then you can use it as a regular component:
<ErrorBoundary>
<MyWidget />
</ErrorBoundary>
Error boundaries work like a JavaScript
catch {}
block, but for components. Only class components can be error boundaries. In practice, most of the time you’ll want to declare an error boundary component once and use it throughout your application.
Note that
error boundaries only catch errors in the components below them in the tree
. An error boundary can’t catch an error within itself. If an error boundary fails trying to render the error message, the error will propagate to the closest error boundary above it. This, too, is similar to how the
catch {}
block works in JavaScript.
Check out this example of declaring and using an error boundary.
The granularity of error boundaries is up to you. You may wrap top-level route components to display a “Something went wrong” message to the user, just like how server-side frameworks often handle crashes. You may also wrap individual widgets in an error boundary to protect them from crashing the rest of the application.
This change has an important implication. As of React 16, errors that were not caught by any error boundary will result in unmounting of the whole React component tree.
We debated this decision, but in our experience it is worse to leave corrupted UI in place than to completely remove it. For example, in a product like Messenger leaving the broken UI visible could lead to somebody sending a message to the wrong person. Similarly, it is worse for a payments app to display a wrong amount than to render nothing.
This change means that as you migrate to React 16, you will likely uncover existing crashes in your application that have been unnoticed before. Adding error boundaries lets you provide better user experience when something goes wrong.
For example, Facebook Messenger wraps content of the sidebar, the info panel, the conversation log, and the message input into separate error boundaries. If some component in one of these UI areas crashes, the rest of them remain interactive.
We also encourage you to use JS error reporting services (or build your own) so that you can learn about unhandled exceptions as they happen in production, and fix them.
React 16 prints all errors that occurred during rendering to the console in development, even if the application accidentally swallows them. In addition to the error message and the JavaScript stack, it also provides component stack traces. Now you can see where exactly in the component tree the failure has happened:
You can also see the filenames and line numbers in the component stack trace. This works by default in Create React App projects:
If you don’t use Create React App, you can add this plugin manually to your Babel configuration. Note that it’s intended only for development and must be disabled in production .
Note
Component names displayed in the stack traces depend on the
Function.name
property. If you support older browsers and devices which may not yet provide this natively (e.g. IE 11), consider including aFunction.name
polyfill in your bundled application, such asfunction.name-polyfill
. Alternatively, you may explicitly set thedisplayName
property on all your components.
try
/
catch
is great but it only works for imperative code:
try {
showButton();
} catch (error) {
// ...
}
However, React components are declarative and specify what should be rendered:
<Button />
Error boundaries preserve the declarative nature of React, and behave as you would expect. For example, even if an error occurs in a
componentDidUpdate
method caused by a
setState
somewhere deep in the tree, it will still correctly propagate to the closest error boundary.
Error boundaries do not catch errors inside event handlers.
React doesn’t need error boundaries to recover from errors in event handlers. Unlike the render method and lifecycle methods, the event handlers don’t happen during rendering. So if they throw, React still knows what to display on the screen.
If you need to catch an error inside an event handler, use the regular JavaScript
try
/
catch
statement:
class MyComponent extends React.Component {
constructor(props) {
super(props);
this.state = { error: null };
this.handleClick = this.handleClick.bind(this);
}
handleClick() {
try { // Do something that could throw } catch (error) { this.setState({ error }); } }
render() {
if (this.state.error) { return <h1>Caught an error.</h1> } return <button onClick={this.handleClick}>Click Me</button> }
}
Note that the above example is demonstrating regular JavaScript behavior and doesn’t use error boundaries.
React 15 included a very limited support for error boundaries under a different method name:
unstable_handleError
. This method no longer works, and you will need to change it to
componentDidCatch
in your code starting from the first 16 beta release.
For this change, we’ve provided a codemod to automatically migrate your code.