Flow is a static type checker for your JavaScript code. It is developed at Facebook and is often used with React. It lets you annotate the variables, functions, and React components with a special type syntax, and catch mistakes early. You can read an introduction to Flow to learn its basics.
To use Flow, you need to:
Add Flow to your project as a dependency.
Ensure that Flow syntax is stripped from the compiled code.
Add type annotations and run Flow to check them.
We will explain these steps below in detail.
Adding Flow to a Project
First, navigate to your project directory in the terminal. You will need to run the following command:
If you use Yarn, run:
yarnadd --dev flow-bin
If you use npm, run:
npminstall --save-dev flow-bin
This command installs the latest version of Flow into your project.
Now, add
flow
to the
"scripts"
section of your
package.json
to be able to use this from the terminal:
This command will create a Flow configuration file that you will need to commit.
Stripping Flow Syntax from the Compiled Code
Flow extends the JavaScript language with a special syntax for type annotations. However, browsers aren’t aware of this syntax, so we need to make sure it doesn’t end up in the compiled JavaScript bundle that is sent to the browser.
The exact way to do this depends on the tools you use to compile JavaScript.
Create React App
If your project was set up using Create React App, congratulations! The Flow annotations are already being stripped by default so you don’t need to do anything else in this step.
Babel
Note:
These instructions are
not
for Create React App users. Even though Create React App uses Babel under the hood, it is already configured to understand Flow. Only follow this step if you
don’t
use Create React App.
If you manually configured Babel for your project, you will need to install a special preset for Flow.
If you use Yarn, run:
yarnadd --dev @babel/preset-flow
If you use npm, run:
npminstall --save-dev @babel/preset-flow
Then add the
flow
preset to your Babel configuration. For example, if you configure Babel through
.babelrc
file, it could look like this:
{ "presets":[ "@babel/preset-flow","react" ] }
This will let you use the Flow syntax in your code.
Note:
Flow does not require the
react
preset, but they are often used together. Flow itself understands JSX syntax out of the box.
Other Build Setups
If you don’t use either Create React App or Babel, you can use flow-remove-types to strip the type annotations.
Running Flow
If you followed the instructions above, you should be able to run Flow for the first time.
yarn flow
If you use npm, run:
npm run flow
You should see a message like:
No errors! ✨ Done in 0.17s.
Adding Flow Type Annotations
By default, Flow only checks the files that include this annotation:
// @flow
Typically it is placed at the top of a file. Try adding it to some files in your project and run
yarn flow
or
npm run flow
to see if Flow already found any issues.
There is also an option to force Flow to check
all
files regardless of the annotation. This can be too noisy for existing projects, but is reasonable for a new project if you want to fully type it with Flow.
Now you’re all set! We recommend to check out the following resources to learn more about Flow:
Flow Documentation: Type Annotations
Flow Documentation: Editors
Flow Documentation: React
Linting in Flow
TypeScript
TypeScript is a programming language developed by Microsoft. It is a typed superset of JavaScript, and includes its own compiler. Being a typed language, TypeScript can catch errors and bugs at build time, long before your app goes live. You can learn more about using TypeScript with React here.
To use TypeScript, you need to:
Add TypeScript as a dependency to your project
Configure the TypeScript compiler options
Use the right file extensions
Add definitions for libraries you use
Let’s go over these in detail.
Using TypeScript with Create React App
Create React App supports TypeScript out of the box.
To create a
new project
with TypeScript support, run:
npx create-react-app my-app --template typescript
You can also add it to an
existing Create React App project
, as documented here.
Note:
If you use Create React App, you can
skip the rest of this page
. It describes the manual setup which doesn’t apply to Create React App users.
Adding TypeScript to a Project
It all begins with running one command in your terminal.
If you use Yarn, run:
yarnadd --dev typescript
If you use npm, run:
npminstall --save-dev typescript
Congrats! You’ve installed the latest version of TypeScript into your project. Installing TypeScript gives us access to the
tsc
command. Before configuration, let’s add
tsc
to the “scripts” section in our
package.json
:
The compiler is of no help to us until we tell it what to do. In TypeScript, these rules are defined in a special file called
tsconfig.json
. To generate this file:
If you use Yarn, run:
yarn run tsc --init
If you use npm, run:
npx tsc --init
Looking at the now generated
tsconfig.json
, you can see that there are many options you can use to configure the compiler. For a detailed description of all the options, check here.
Of the many options, we’ll look at
rootDir
and
outDir
. In its true fashion, the compiler will take in typescript files and generate javascript files. However we don’t want to get confused with our source files and the generated output.
We’ll address this in two steps:
Firstly, let’s arrange our project structure like this. We’ll place all our source code in the
src
directory.
Great! Now when we run our build script the compiler will output the generated javascript to the
build
folder. The TypeScript React Starter provides a
tsconfig.json
with a good set of rules to get you started.
Generally, you don’t want to keep the generated javascript in your source control, so be sure to add the build folder to your
.gitignore
.
File extensions
In React, you most likely write your components in a
.js
file. In TypeScript we have 2 file extensions:
.ts
is the default file extension while
.tsx
is a special extension used for files which contain
JSX
.
Running TypeScript
If you followed the instructions above, you should be able to run TypeScript for the first time.
yarn build
If you use npm, run:
npm run build
If you see no output, it means that it completed successfully.
Type Definitions
To be able to show errors and hints from other packages, the compiler relies on declaration files. A declaration file provides all the type information about a library. This enables us to use javascript libraries like those on npm in our project.
There are two main ways to get declarations for a library:
Bundled
- The library bundles its own declaration file. This is great for us, since all we need to do is install the library, and we can use it right away. To check if a library has bundled types, look for an
index.d.ts
file in the project. Some libraries will have it specified in their
package.json
under the
typings
or
types
field.
DefinitelyTyped
- DefinitelyTyped is a huge repository of declarations for libraries that don’t bundle a declaration file. The declarations are crowd-sourced and managed by Microsoft and open source contributors. React for example doesn’t bundle its own declaration file. Instead we can get it from DefinitelyTyped. To do so enter this command in your terminal.
# yarn yarnadd --dev @types/react
# npm npm i --save-dev @types/react
Local Declarations
Sometimes the package that you want to use doesn’t bundle declarations nor is it available on DefinitelyTyped. In that case, we can have a local declaration file. To do this, create a
declarations.d.ts
file in the root of your source directory. A simple declaration could look like this:
You are now ready to code! We recommend to check out the following resources to learn more about TypeScript:
TypeScript Documentation: Everyday Types
TypeScript Documentation: Migrating from JavaScript
TypeScript Documentation: React and Webpack
ReScript
ReScript is a typed language that compiles to JavaScript. Some of its core features are guaranteed 100% type coverage, first-class JSX support and dedicated React bindings to allow integration in existing JS / TS React codebases.
You can find more infos on integrating ReScript in your existing JS / React codebase here.
Kotlin
Kotlin is a statically typed language developed by JetBrains. Its target platforms include the JVM, Android, LLVM, and JavaScript.
JetBrains develops and maintains several tools specifically for the React community: React bindings as well as Create React Kotlin App. The latter helps you start building React apps with Kotlin with no build configuration.
Other Languages
Note there are other statically typed languages that compile to JavaScript and are thus React compatible. For example, F#/Fable with elmish-react. Check out their respective sites for more information, and feel free to add more statically typed languages that work with React to this page!
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Strict Mode – React
Strict Mode
StrictMode
is a tool for highlighting potential problems in an application. Like
Fragment
,
StrictMode
does not render any visible UI. It activates additional checks and warnings for its descendants.
Note:
Strict mode checks are run in development mode only;
they do not impact the production build
.
You can enable strict mode for any part of your application. For example:
In the above example, strict mode checks will
not
be run against the
Header
and
Footer
components. However,
ComponentOne
and
ComponentTwo
, as well as all of their descendants, will have the checks.
Additional functionality will be added with future releases of React.
Identifying unsafe lifecycles
As explained in this blog post, certain legacy lifecycle methods are unsafe for use in async React applications. However, if your application uses third party libraries, it can be difficult to ensure that these lifecycles aren’t being used. Fortunately, strict mode can help with this!
When strict mode is enabled, React compiles a list of all class components using the unsafe lifecycles, and logs a warning message with information about these components, like so:
Addressing the issues identified by strict mode
now
will make it easier for you to take advantage of concurrent rendering in future releases of React.
Warning about legacy string ref API usage
Previously, React provided two ways for managing refs: the legacy string ref API and the callback API. Although the string ref API was the more convenient of the two, it had several downsides and so our official recommendation was to use the callback form instead.
React 16.3 added a third option that offers the convenience of a string ref without any of the downsides:
Since object refs were largely added as a replacement for string refs, strict mode now warns about usage of string refs.
Note:
Callback refs will continue to be supported in addition to the new
createRef
API.
You don’t need to replace callback refs in your components. They are slightly more flexible, so they will remain as an advanced feature.
Learn more about the new
createRef
API here.
Warning about deprecated findDOMNode usage
React used to support
findDOMNode
to search the tree for a DOM node given a class instance. Normally you don’t need this because you can attach a ref directly to a DOM node.
findDOMNode
can also be used on class components but this was breaking abstraction levels by allowing a parent to demand that certain children were rendered. It creates a refactoring hazard where you can’t change the implementation details of a component because a parent might be reaching into its DOM node.
findDOMNode
only returns the first child, but with the use of Fragments, it is possible for a component to render multiple DOM nodes.
findDOMNode
is a one time read API. It only gave you an answer when you asked for it. If a child component renders a different node, there is no way to handle this change. Therefore
findDOMNode
only worked if components always return a single DOM node that never changes.
You can instead make this explicit by passing a ref to your custom component and pass that along to the DOM using ref forwarding.
You can also add a wrapper DOM node in your component and attach a ref directly to it.
In CSS, the
display: contents
attribute can be used if you don’t want the node to be part of the layout.
Detecting unexpected side effects
Conceptually, React does work in two phases:
The
render
phase determines what changes need to be made to e.g. the DOM. During this phase, React calls
render
and then compares the result to the previous render.
The
commit
phase is when React applies any changes. (In the case of React DOM, this is when React inserts, updates, and removes DOM nodes.) React also calls lifecycles like
componentDidMount
and
componentDidUpdate
during this phase.
The commit phase is usually very fast, but rendering can be slow. For this reason, the upcoming concurrent mode (which is not enabled by default yet) breaks the rendering work into pieces, pausing and resuming the work to avoid blocking the browser. This means that React may invoke render phase lifecycles more than once before committing, or it may invoke them without committing at all (because of an error or a higher priority interruption).
Render phase lifecycles include the following class component methods:
Because the above methods might be called more than once, it’s important that they do not contain side-effects. Ignoring this rule can lead to a variety of problems, including memory leaks and invalid application state. Unfortunately, it can be difficult to detect these problems as they can often be non-deterministic.
Strict mode can’t automatically detect side effects for you, but it can help you spot them by making them a little more deterministic. This is done by intentionally double-invoking the following functions:
Class component
constructor
,
render
, and
shouldComponentUpdate
methods
Class component static
getDerivedStateFromProps
method
Function component bodies
State updater functions (the first argument to
setState
)
Functions passed to
useState
,
useMemo
, or
useReducer
Note:
This only applies to development mode.
Lifecycles will not be double-invoked in production mode.
At first glance, this code might not seem problematic. But if
SharedApplicationState.recordEvent
is not idempotent, then instantiating this component multiple times could lead to invalid application state. This sort of subtle bug might not manifest during development, or it might do so inconsistently and so be overlooked.
By intentionally double-invoking methods like the component constructor, strict mode makes patterns like this easier to spot.
Note:
In React 17, React automatically modifies the console methods like
console.log()
to silence the logs in the second call to lifecycle functions. However, it may cause undesired behavior in certain cases where a workaround can be used.
Starting from React 18, React does not suppress any logs. However, if you have React DevTools installed, the logs from the second call will appear slightly dimmed. React DevTools also offers a setting (off by default) to suppress them completely.
Detecting legacy context API
The legacy context API is error-prone, and will be removed in a future major version. It still works for all 16.x releases but will show this warning message in strict mode:
Read the new context API documentation to help migrate to the new version.
Ensuring reusable state
In the future, we’d like to add a feature that allows React to add and remove sections of the UI while preserving state. For example, when a user tabs away from a screen and back, React should be able to immediately show the previous screen. To do this, React will support remounting trees using the same component state used before unmounting.
This feature will give React better performance out-of-the-box, but requires components to be resilient to effects being mounted and destroyed multiple times. Most effects will work without any changes, but some effects do not properly clean up subscriptions in the destroy callback, or implicitly assume they are only mounted or destroyed once.
To help surface these issues, React 18 introduces a new development-only check to Strict Mode. This new check will automatically unmount and remount every component, whenever a component mounts for the first time, restoring the previous state on the second mount.
To demonstrate the development behavior you’ll see in Strict Mode with this feature, consider what happens when React mounts a new component. Without this change, when a component mounts, React creates the effects:
* React mounts the component. * Layout effects are created. * Effects are created.
With Strict Mode starting in React 18, whenever a component mounts in development, React will simulate immediately unmounting and remounting the component:
* React mounts the component. * Layout effects are created. * Effect effects are created. * React simulates effects being destroyed on a mounted component. * Layout effects are destroyed. * Effects are destroyed. * React simulates effects being re-created on a mounted component. * Layout effects are created * Effect setup code runs
On the second mount, React will restore the state from the first mount. This feature simulates user behavior such as a user tabbing away from a screen and back, ensuring that code will properly handle state restoration.
When the component unmounts, effects are destroyed as normal:
* React unmounts the component. * Layout effects are destroyed. * Effect effects are destroyed.
Unmounting and remounting includes:
componentDidMount
componentWillUnmount
useEffect
useLayoutEffect
useInsertionEffect
Note:
This only applies to development mode,
production behavior is unchanged
.
We provide a codemod script to automate the conversion.
As your app grows, you can catch a lot of bugs with typechecking. For some applications, you can use JavaScript extensions like Flow or TypeScript to typecheck your whole application. But even if you don’t use those, React has some built-in typechecking abilities. To run typechecking on the props for a component, you can assign the special
propTypes
property:
In this example, we are using a class component, but the same functionality could also be applied to function components, or components created by
React.memo
or
React.forwardRef
.
PropTypes
exports a range of validators that can be used to make sure the data you receive is valid. In this example, we’re using
PropTypes.string
. When an invalid value is provided for a prop, a warning will be shown in the JavaScript console. For performance reasons,
propTypes
is only checked in development mode.
PropTypes
Here is an example documenting the different validators provided:
import PropTypes from'prop-types';
MyComponent.propTypes ={ // You can declare that a prop is a specific JS type. By default, these // are all optional. optionalArray: PropTypes.array, optionalBool: PropTypes.bool, optionalFunc: PropTypes.func, optionalNumber: PropTypes.number, optionalObject: PropTypes.object, optionalString: PropTypes.string, optionalSymbol: PropTypes.symbol,
// Anything that can be rendered: numbers, strings, elements or an array // (or fragment) containing these types. optionalNode: PropTypes.node,
// A React element. optionalElement: PropTypes.element,
// A React element type (ie. MyComponent). optionalElementType: PropTypes.elementType,
// You can also declare that a prop is an instance of a class. This uses // JS's instanceof operator. optionalMessage: PropTypes.instanceOf(Message),
// You can ensure that your prop is limited to specific values by treating // it as an enum. optionalEnum: PropTypes.oneOf(['News','Photos']),
// An object that could be one of many types optionalUnion: PropTypes.oneOfType([ PropTypes.string, PropTypes.number, PropTypes.instanceOf(Message) ]),
// An array of a certain type optionalArrayOf: PropTypes.arrayOf(PropTypes.number),
// An object with property values of a certain type optionalObjectOf: PropTypes.objectOf(PropTypes.number),
// An object taking on a particular shape optionalObjectWithShape: PropTypes.shape({ color: PropTypes.string, fontSize: PropTypes.number }),
// An object with warnings on extra properties optionalObjectWithStrictShape: PropTypes.exact({ name: PropTypes.string, quantity: PropTypes.number }),
// You can chain any of the above with `isRequired` to make sure a warning // is shown if the prop isn't provided. requiredFunc: PropTypes.func.isRequired,
// A required value of any data type requiredAny: PropTypes.any.isRequired,
// You can also specify a custom validator. It should return an Error // object if the validation fails. Don't `console.warn` or throw, as this // won't work inside `oneOfType`. customProp:function(props, propName, componentName){ if(!/matchme/.test(props[propName])){ returnnewError( 'Invalid prop `'+ propName +'` supplied to'+ ' `'+ componentName +'`. Validation failed.' ); } },
// You can also supply a custom validator to `arrayOf` and `objectOf`. // It should return an Error object if the validation fails. The validator // will be called for each key in the array or object. The first two // arguments of the validator are the array or object itself, and the // current item's key. customArrayProp: PropTypes.arrayOf(function(propValue, key, componentName, location, propFullName){ if(!/matchme/.test(propValue[key])){ returnnewError( 'Invalid prop `'+ propFullName +'` supplied to'+ ' `'+ componentName +'`. Validation failed.' ); } }) };
Requiring Single Child
With
PropTypes.element
you can specify that only a single child can be passed to a component as children.
import PropTypes from'prop-types';
classMyComponentextendsReact.Component{ render(){ // This must be exactly one element or it will warn. const children =this.props.children; return( <div> {children} </div> ); } }
Since ES2022 you can also declare
defaultProps
as static property within a React component class. For more information, see the class public static fields. This modern syntax will require a compilation step to work within older browsers.
The
defaultProps
will be used to ensure that
this.props.name
will have a value if it was not specified by the parent component. The
propTypes
typechecking happens after
defaultProps
are resolved, so typechecking will also apply to the
defaultProps
.
Function Components
If you are using function components in your regular development, you may want to make some small changes to allow PropTypes to be properly applied.
Let’s say you have a component like this:
exportdefaultfunctionHelloWorldComponent({ name }){ return( <div>Hello, {name}</div> ) }
To add PropTypes, you may want to declare the component in a separate function before exporting, like this:
functionHelloWorldComponent({ name }){ return( <div>Hello, {name}</div> ) }
exportdefault HelloWorldComponent
Then, you can add PropTypes directly to the
HelloWorldComponent
:
import PropTypes from'prop-types'
functionHelloWorldComponent({ name }){ return( <div>Hello, {name}</div> ) }
Since an uncontrolled component keeps the source of truth in the DOM, it is sometimes easier to integrate React and non-React code when using uncontrolled components. It can also be slightly less code if you want to be quick and dirty. Otherwise, you should usually use controlled components.
If it’s still not clear which type of component you should use for a particular situation, you might find this article on controlled versus uncontrolled inputs to be helpful.
Default Values
In the React rendering lifecycle, the
value
attribute on form elements will override the value in the DOM. With an uncontrolled component, you often want React to specify the initial value, but leave subsequent updates uncontrolled. To handle this case, you can specify a
defaultValue
attribute instead of
value
. Changing the value of
defaultValue
attribute after a component has mounted will not cause any update of the value in the DOM.
Likewise,
<input type="checkbox">
and
<input type="radio">
support
defaultChecked
, and
<select>
and
<textarea>
supports
defaultValue
.
The file input Tag
In HTML, an
<input type="file">
lets the user choose one or more files from their device storage to be uploaded to a server or manipulated by JavaScript via the File API.
<inputtype="file"/>
In React, an
<input type="file" />
is always an uncontrolled component because its value can only be set by a user, and not programmatically.
You should use the File API to interact with the files. The following example shows how to create a ref to the DOM node to access file(s) in a submit handler:
Most people who use React don’t use Web Components, but you may want to, especially if you are using third-party UI components that are written using Web Components.
Web Components often expose an imperative API. For instance, a
video
Web Component might expose
play()
and
pause()
functions. To access the imperative APIs of a Web Component, you will need to use a ref to interact with the DOM node directly. If you are using third-party Web Components, the best solution is to write a React component that behaves as a wrapper for your Web Component.
Events emitted by a Web Component may not properly propagate through a React render tree.
You will need to manually attach event handlers to handle these events within your React components.
One common confusion is that Web Components use “class” instead of “className”.
This code
will not
work if you transform classes with Babel. See this issue for the discussion.
Include the custom-elements-es5-adapter before you load your web components to fix this issue.
React
is the entry point to the React library. If you load React from a
<script>
tag, these top-level APIs are available on the
React
global. If you use ES6 with npm, you can write
import React from 'react'
. If you use ES5 with npm, you can write
var React = require('react')
.
React components let you split the UI into independent, reusable pieces, and think about each piece in isolation. React components can be defined by subclassing
React.Component
or
React.PureComponent
.
React.Component
React.PureComponent
If you don’t use ES6 classes, you may use the
create-react-class
module instead. See Using React without ES6 for more information.
React components can also be defined as functions which can be wrapped:
React.memo
Creating React Elements
We recommend using JSX to describe what your UI should look like. Each JSX element is just syntactic sugar for calling
React.createElement()
. You will not typically invoke the following methods directly if you are using JSX.
createElement()
createFactory()
See Using React without JSX for more information.
Transforming Elements
React
provides several APIs for manipulating elements:
cloneElement()
isValidElement()
React.Children
Fragments
React
also provides a component for rendering multiple elements without a wrapper.
React.Fragment
Refs
React.createRef
React.forwardRef
Suspense
Suspense lets components “wait” for something before rendering. Today, Suspense only supports one use case: loading components dynamically with
React.lazy
. In the future, it will support other use cases like data fetching.
React.lazy
React.Suspense
Transitions
Transitions
are a new concurrent feature introduced in React 18. They allow you to mark updates as transitions, which tells React that they can be interrupted and avoid going back to Suspense fallbacks for already visible content.
React.startTransition
React.useTransition
Hooks
Hooks
are a new addition in React 16.8. They let you use state and other React features without writing a class. Hooks have a dedicated docs section and a separate API reference:
Basic Hooks
useState
useEffect
useContext
Additional Hooks
useReducer
useCallback
useMemo
useRef
useImperativeHandle
useLayoutEffect
useDebugValue
useDeferredValue
useTransition
useId
Library Hooks
useSyncExternalStore
useInsertionEffect
Reference
React.Component
React.Component
is the base class for React components when they are defined using ES6 classes:
See the React.Component API Reference for a list of methods and properties related to the base
React.Component
class.
React.PureComponent
React.PureComponent
is similar to
React.Component
. The difference between them is that
React.Component
doesn’t implement
shouldComponentUpdate()
, but
React.PureComponent
implements it with a shallow prop and state comparison.
If your React component’s
render()
function renders the same result given the same props and state, you can use
React.PureComponent
for a performance boost in some cases.
Note
React.PureComponent
’s
shouldComponentUpdate()
only shallowly compares the objects. If these contain complex data structures, it may produce false-negatives for deeper differences. Only extend
PureComponent
when you expect to have simple props and state, or use
forceUpdate()
when you know deep data structures have changed. Or, consider using immutable objects to facilitate fast comparisons of nested data.
Furthermore,
React.PureComponent
’s
shouldComponentUpdate()
skips prop updates for the whole component subtree. Make sure all the children components are also “pure”.
React.memo
const MyComponent = React.memo(functionMyComponent(props){ /* render using props */ });
React.memo
is a higher order component.
If your component renders the same result given the same props, you can wrap it in a call to
React.memo
for a performance boost in some cases by memoizing the result. This means that React will skip rendering the component, and reuse the last rendered result.
React.memo
only checks for prop changes. If your function component wrapped in
React.memo
has a
useState
,
useReducer
or
useContext
Hook in its implementation, it will still rerender when state or context change.
By default it will only shallowly compare complex objects in the props object. If you want control over the comparison, you can also provide a custom comparison function as the second argument.
functionMyComponent(props){ /* render using props */ } functionareEqual(prevProps, nextProps){ /* return true if passing nextProps to render would return the same result as passing prevProps to render, otherwise return false */ } exportdefault React.memo(MyComponent, areEqual);
This method only exists as a
performance optimization.
Do not rely on it to “prevent” a render, as this can lead to bugs.
Note
Unlike the
shouldComponentUpdate()
method on class components, the
areEqual
function returns
true
if the props are equal and
false
if the props are not equal. This is the inverse from
shouldComponentUpdate
.
Create and return a new React element of the given type. The type argument can be either a tag name string (such as
'div'
or
'span'
), a React component type (a class or a function), or a React fragment type.
Code written with JSX will be converted to use
React.createElement()
. You will not typically invoke
React.createElement()
directly if you are using JSX. See React Without JSX to learn more.
Clone and return a new React element using
element
as the starting point.
config
should contain all new props,
key
, or
ref
. The resulting element will have the original element’s props with the new props merged in shallowly. New children will replace existing children.
key
and
ref
from the original element will be preserved if no
key
and
ref
present in the
config
.
However, it also preserves
ref
s. This means that if you get a child with a
ref
on it, you won’t accidentally steal it from your ancestor. You will get the same
ref
attached to your new element. The new
ref
or
key
will replace old ones if present.
This API was introduced as a replacement of the deprecated
React.addons.cloneWithProps()
.
createFactory()
React.createFactory(type)
Return a function that produces React elements of a given type. Like
React.createElement()
, the type argument can be either a tag name string (such as
'div'
or
'span'
), a React component type (a class or a function), or a React fragment type.
This helper is considered legacy, and we encourage you to either use JSX or use
React.createElement()
directly instead.
You will not typically invoke
React.createFactory()
directly if you are using JSX. See React Without JSX to learn more.
isValidElement()
React.isValidElement(object)
Verifies the object is a React element. Returns
true
or
false
.
React.Children
React.Children
provides utilities for dealing with the
this.props.children
opaque data structure.
React.Children.map
React.Children.map(children,function[(thisArg)])
Invokes a function on every immediate child contained within
children
with
this
set to
thisArg
. If
children
is an array it will be traversed and the function will be called for each child in the array. If children is
null
or
undefined
, this method will return
null
or
undefined
rather than an array.
Note
If
children
is a
Fragment
it will be treated as a single child and not traversed.
Like
React.Children.map()
but does not return an array.
React.Children.count
React.Children.count(children)
Returns the total number of components in
children
, equal to the number of times that a callback passed to
map
or
forEach
would be invoked.
React.Children.only
React.Children.only(children)
Verifies that
children
has only one child (a React element) and returns it. Otherwise this method throws an error.
Note:
React.Children.only()
does not accept the return value of
React.Children.map()
because it is an array rather than a React element.
React.Children.toArray
React.Children.toArray(children)
Returns the
children
opaque data structure as a flat array with keys assigned to each child. Useful if you want to manipulate collections of children in your render methods, especially if you want to reorder or slice
this.props.children
before passing it down.
Note:
React.Children.toArray()
changes keys to preserve the semantics of nested arrays when flattening lists of children. That is,
toArray
prefixes each key in the returned array so that each element’s key is scoped to the input array containing it.
React.Fragment
The
React.Fragment
component lets you return multiple elements in a
render()
method without creating an additional DOM element:
render(){ return( <React.Fragment> Some text. <h2>A heading</h2> </React.Fragment> ); }
You can also use it with the shorthand
<></>
syntax. For more information, see React v16.2.0: Improved Support for Fragments.
React.createRef
React.createRef
creates a ref that can be attached to React elements via the ref attribute.
React.forwardRef
creates a React component that forwards the ref attribute it receives to another component below in the tree. This technique is not very common but is particularly useful in two scenarios:
Forwarding refs to DOM components
Forwarding refs in higher-order-components
React.forwardRef
accepts a rendering function as an argument. React will call this function with
props
and
ref
as two arguments. This function should return a React node.
// You can now get a ref directly to the DOM button: const ref = React.createRef(); <FancyButtonref={ref}>Click me!</FancyButton>;
In the above example, React passes a
ref
given to
<FancyButton ref={ref}>
element as a second argument to the rendering function inside the
React.forwardRef
call. This rendering function passes the
ref
to the
<button ref={ref}>
element.
As a result, after React attaches the ref,
ref.current
will point directly to the
<button>
DOM element instance.
For more information, see forwarding refs.
React.lazy
React.lazy()
lets you define a component that is loaded dynamically. This helps reduce the bundle size to delay loading components that aren’t used during the initial render.
You can learn how to use it from our code splitting documentation. You might also want to check out this article explaining how to use it in more detail.
// This component is loaded dynamically const SomeComponent = React.lazy(()=>import('./SomeComponent'));
Note that rendering
lazy
components requires that there’s a
<React.Suspense>
component higher in the rendering tree. This is how you specify a loading indicator.
React.Suspense
React.Suspense
lets you specify the loading indicator in case some components in the tree below it are not yet ready to render. In the future we plan to let
Suspense
handle more scenarios such as data fetching. You can read about this in our roadmap.
Today, lazy loading components is the
only
use case supported by
<React.Suspense>
:
// This component is loaded dynamically const OtherComponent = React.lazy(()=>import('./OtherComponent'));
It is documented in our code splitting guide. Note that
lazy
components can be deep inside the
Suspense
tree — it doesn’t have to wrap every one of them. The best practice is to place
<Suspense>
where you want to see a loading indicator, but to use
lazy()
wherever you want to do code splitting.
Note
For content that is already shown to the user, switching back to a loading indicator can be disorienting. It is sometimes better to show the “old” UI while the new UI is being prepared. To do this, you can use the new transition APIs
startTransition
and
useTransition
to mark updates as transitions and avoid unexpected fallbacks.
React.Suspense
in Server Side Rendering
During server side rendering Suspense Boundaries allow you to flush your application in smaller chunks by suspending.
When a component suspends we schedule a low priority task to render the closest Suspense boundary’s fallback. If the component unsuspends before we flush the fallback then we send down the actual content and throw away the fallback.
React.Suspense
during hydration
Suspense boundaries depend on their parent boundaries being hydrated before they can hydrate, but they can hydrate independently from sibling boundaries. Events on a boundary before it is hydrated will cause the boundary to hydrate at a higher priority than neighboring boundaries. Read more
React.startTransition
React.startTransition(callback)
React.startTransition
lets you mark updates inside the provided callback as transitions. This method is designed to be used when
React.useTransition
is not available.
Note:
Updates in a transition yield to more urgent updates such as clicks.
Updates in a transition will not show a fallback for re-suspended content, allowing the user to continue interacting while rendering the update.
React.startTransition
does not provide an
isPending
flag. To track the pending status of a transition see
React.useTransition
.