Higher-Order Components In React
Higher-Order Components In React
Shedrack Akintayo
Higher-order components (HOCs) in React were inspired by higher-order functions in JavaScript. A HOC is an advanced technique for reusing logic in React components. It is a pattern created out of React’s compositional nature.
HOCs basically incorporate the don’t-repeat-yourself (DRY) principle of programming, which you’ve most likely come across at some point in your career as a software developer. It is one of the best-known principles of software development, and observing it is very important when building an application or writing code in general.
In this tutorial, we will learn what a HOC is, its basic structure, some use cases, and finally an example.
Note: Basic knowledge of React and JavaScript will come in handy as you work through this tutorial.
Best Practices With React
React is a fantastic JavaScript library for building rich user interfaces. It provides a great component abstraction for organizing your interfaces into well-functioning code, and there’s just about anything you can use it for. Read more articles on React →
Higher-Order Functions In JavaScript
Before jumping into HOCs in React, let’s briefly discuss higher-order functions in JavaScript. Understanding them is critical to understanding our topic of focus.
Higher-order functions in JavaScript take some functions as arguments and return another function. They enable us to abstract over actions, not just values, They come in several forms, and they help us to write less code when operating on functions and even arrays.
The most interesting part of using higher-order functions is composition. We can write small functions that handle one piece of logic. Then, we can compose complex functions by using the different small functions we have created. This reduces bugs in our code base and makes our code much easier to read and understand.
JavaScript has some of these functions already built in. Some examples of higher-order functions are the following:
.forEach()
This iterates over every element in an array with the same code, but does not change or mutate the array, and it returns undefined..map()
This method transforms an array by applying a function to all of its elements, and then building a new array from the returned values..reduce()
This method executes a provided function for each value of the array (from left to right)..filter()
This checks every single element in an array to see whether it meets certain criteria as specified in thefilter
method, and then it returns a new array with the elements that match the criteria.
So many higher-order functions are built into JavaScript, and you can make your own custom ones.
An Example Of Custom Higher-Order Function
Suppose we are asked to write a function that formats integers as currencies, including some customization of specifying the currency symbol and adding a decimal separator for the currency amount. We can write a higher-other function that takes the currency symbol and also the decimal separator. This same function would then format the value passed to it with the currency symbol and decimal operators. We would name our higher-order function formatCurrency
.
const formatCurrency = function( currencySymbol, decimalSeparator ) { return function( value ) { const wholePart = Math.trunc( value / 100 ); let fractionalPart = value % 100; if ( fractionalPart < 10 ) { fractionalPart = '0' + fractionalPart; } return `$ {currencySymbol}$ {wholePart}$ {decimalSeparator}$ {fractionalPart}`; } }
formatCurrency
returns a function with a fixed currency symbol and decimal separator.
We then pass the formatter a value, and format this value with the function by extracting its whole part and the fractional part. The returned value of this function is constructed by a template literal, concatenating the currency symbol, the whole part, the decimal separator, and the fractional part.
Let’s use this higher-order function by assigning a value to it and seeing the result.
> getLabel = formatCurrency( '$ ', '.' ); > getLabel( 1999 ) "$ 19.99" //formatted value > getLabel( 2499 ) "$ 24.99" //formatted value
You might have noticed that we created a variable named getLabel
, then assigned our formatCurrency
higher-order function, and then passed the currency formatters to the function, which is the currency symbol and a decimal separator. To make use of the function, we call getLabel
, which is now a function, and we pass in the value that needs to be formatted. That’s all! We have created a custom higher order of our choice.
What Is A Higher-Order Component?
A higher-order component (HOC) is an advanced element for reusing logic in React components. Components take one or more components as arguments, and return a new upgraded component. Sounds familiar, right? They are similar to higher-order functions, which take some functions as an argument and produce a new function.
HOCs are commonly used to design components with certain shared behavior in a way that makes them connected differently than normal state-to-props pattern.
Facts About HOCs
- We don’t modify or mutate components. We create new ones.
- A HOC is used to compose components for code reuse.
- A HOC is a pure function. It has no side effects, returning only a new component.
Here are some examples of real-world HOCs you might have come across:
react-redux | connect(mapStateToProps, mapDispatchToProps)(UserPage) |
react-router | withRouter(UserPage) |
material-ui | withStyles(styles)(UserPage) |
Structure Of A Higher-Order Component
A HOC is structured like a higher-order function:
- It is a component.
- It takes another component as an argument.
- Then, it returns a new component.
- The component it returns can render the original component that was passed to it.
The snippet below shows how a HOC is structured in React:
import React from 'react'; // Take in a component as argument WrappedComponent const higherOrderComponent = (WrappedComponent) => { // And return another component class HOC extends React.Component { render() { return <WrappedComponent />; } } return HOC; };
We can see that higherOrderComponent
takes a component (WrappedComponent
) and returns another component inside of it. With this technique, whenever we need to reuse a particular component’s logic for something, we can create a HOC out of that component and use it wherever we like.
Use Cases
In my experience as a front-end engineer who has been writing React for a while now, here are some use cases for HOCs.
Show a loader while a component waits for data
Most of the time, when building a web application, we would need to use a loader of some sort that is displayed while a component is waiting for data to be passed to its props. We could easily use an in-component solution to render the loader, which would work, but it wouldn’t be the most elegant solution. Better would be to write a common HOC that can track those props; and while those props haven’t been injected or are in an empty state, it can show a loading state.
To explain this properly, let’s build a list of categories of public APIs, using its open API. We tend to handle list-loading, so that our clients don’t panic when the API we are getting data from takes so much time to respond.
Let’s generate a React app:
npx create-react-app repos-list
A basic list component can be written as follows:
//List.js import React from 'react'; const List = (props) => { const { repos } = props; if (!repos) return null; if (!repos.length) return <p>No repos, sorry</p>; return ( <ul> {repos.map((repo) => { return <li key={repo.id}>{repo.full_name}</li>; })} </ul> ); }; export default List;
The code above is a list component. Let’s break down the code into tiny bits so that we can understand what is happening.
const List = (props) => {};
Above, we initialize our functional component, named List
, and pass props to it.
const { repos } = props;
Then, we create a constant, named repos
, and pass it to our component props, so that it can be used to modify our component.
if (!repos) return null; if (!repos.length) return <p>No repos, sorry</p>;
Above, we are basically saying that, if after fetching has completed and the repos
prop is still empty, then it should return null
. We are also carrying out a conditional render here: If the length of the repos
prop is still empty, then it should render “No repos, sorry” in our browser.
return ( <ul> {repos.map((repo) => { return <li key={repo.id}>{repo.full_name}</li>; })} </ul> );
Here, we are basically mapping through the repos
array and returning a list of repos according to their full names, with a unique key for each entry.
Now, let’s write a HOC that handles loading, to make our users happy.
//withdLoading.js import React from 'react'; function WithLoading(Component) { return function WihLoadingComponent({ isLoading, ...props }) { if (!isLoading) return <Component {...props} />; return <p>Hold on, fetching data might take some time.</p>; }; } export default WithLoading;
This would display the text “Hold on, fetching data might take some time” when the app is still fetching data and the props are being injected into state. We make use of isLoading
to determine whether the component should be rendered.
Now, in your App.js
file, you could pass the loading
logic to WithLoading
, without worrying about it in your List
.
import React from 'react'; import List from './components/List.js'; import WithLoading from './components/withLoading.js'; const ListWithLoading = WithLoading(List); class App extends React.Component { state = { { }; componentDidMount() { this.setState({ loading: true }); fetch(`https://api.github.com/users/hacktivist123/repos`) .then((json) => json.json()) .then((repos) => { this.setState({ loading: false, repos: repos }); }); } render() { return ( <ListWithLoading isLoading={this.state.loading} repos={this.state.repos} /> ); } } export default App;
The code above is our entire app. Let’s break it down to see what is happening.
class App extends React.Component { state = { loading: false, repos: null, }; componentDidMount() { this.setState({ loading: true }); fetch(`https://api.github.com/users/hacktivist123/repos`) .then((json) => json.json()) .then((repos) => { this.setState({ loading: false, repos: repos }); }); }
All we are doing here is creating a class component named App()
, then initializing state with two properties, loading: false,
and repos: null,
. The initial state of loading
is false
, while the initial state of repos is also null
.
Then, when our component is mounting, we set the state of the loading
property to true
, and immediately make a fetch request to the API URL that holds the data we need to populate our List
component. Once the request is complete, we set the loading
state to false
and populate the repos
state with the data we have pulled from the API request.
const ListWithLoading = WithLoading(List);
Here, we create a new component named ListWithLoading
and pass the WithLoading
HOC that we created and also the List
component in it.
render() { return ( <ListWithLoading isLoading={this.state.loading} repos={this.state.repos} /> ); }
Above, we render the ListWithLoading
component, which has been supercharged by the WithLoading
HOC that we created and also the List
component in it. Also, we pass the loading
state’s value and the repos
state’s value as props to the component.
Because the page is still trying to pull data from the API, our HOC will render the following text in the browser.
When loading is done and the props are no longer in an empty state, the repos will be rendered to the screen.
Conditionally Render Components
Suppose we have a component that needs to be rendered only when a user is authenticated — it is a protected component. We can create a HOC named WithAuth()
to wrap that protected component, and then do a check in the HOC that will render only that particular component if the user has been authenticated.
A basic withAuth()
HOC, according to the example above, can be written as follows:
// withAuth.js import React from "react"; export function withAuth(Component) { return class AuthenticatedComponent extends React.Component { isAuthenticated() { return this.props.isAuthenticated; } /** * Render */ render() { const loginErrorMessage = ( <div> Please <a href="/login">login</a> in order to view this part of the application. </div> ); return ( <div> { this.isAuthenticated === true ? <Component {...this.props} /> : loginErrorMessage } </div> ); } }; } export default withAuth;
The code above is a HOC named withAuth
. It basically takes a component and returns a new component, named AuthenticatedComponent
, that checks whether the user is authenticated. If the user is not authenticated, it returns the loginErrorMessage
component; if the user is authenticated, it returns the wrapped component.
Note: this.props.isAuthenticated
has to be set from your application’s logic. (Or else use react-redux to retrieve it from the global state.)
To make use of our HOC in a protected component, we’d use it like so:
// MyProtectedComponent.js import React from "react"; import {withAuth} from "./withAuth.js"; export class MyProectedComponent extends React.Component { /** * Render */ render() { return ( <div> This is only viewable by authenticated users. </div> ); } } // Now wrap MyPrivateComponent with the requireAuthentication function export default withAuth(MyPrivateComponent);
Here, we create a component that is viewable only by users who are authenticated. We wrap that component in our withAuth
HOC to protect the component from users who are not authenticated.
Provide Components With Specific Styling
Continuing the use case above, based on whatever UI state you get from the HOC, you can render specific styles for specific UI states. For example, if the need arises in multiple places for styles like backgroundColor
, fontSize
and so on, they can be provided via a HOC by wrapping the component with one that just injects props with the specific className
.
Take a very simple component that renders “hello” and the name of a person. It takes a name
prop and some other prop that can affect the rendered JavaScript XML (JSX).
// A simple component const HelloComponent = ({ name, ...otherProps }) => ( <div {...otherProps}>Hello {name}!/div> );
Let’s create a HOC named withStyling
that adds some styling to the “hello” text.
const withStyling = (BaseComponent) => (props) => ( <BaseComponent {...props} style={{ fontWeight: 700, color: 'green' }} /> );
In order to make use of the HOC on our HelloComponent
, we wrap the HOC around the component. We create a pure component, named EnhancedHello
, and assign the HOC and our HelloComponent
, like so :
const EnhancedHello = withStyling(HelloComponent);
To make a change to our HelloComponent
, we render the EnhancedHello
component:
<EnhancedHello name='World' />
Now, the text in our HelloComponent
becomes this:
<div style={{fontWeight: 700, color: 'green' }}>Hello World</div>
Provide A Component With Any Prop You Want
This is a popular use case for HOCs. We can study our code base and note what reusable prop is needed across components. Then, we can have a wrapper HOC to provide those components with the reusable prop.
Let’s use the example above:
// A simple component const HelloComponent = ({ name, ...otherProps }) => ( <div {...otherProps}>Hello {name}!</div> );
Let’s create a HOC named withNameChange
that sets a name
prop on a base component to “New Name”.
const withNameChange = (BaseComponent) => (props) => ( <BaseComponent {...props} name='New Name' /> );
In order to use the HOC on our HelloComponent
, we wrap the HOC around the component, create a pure component named EnhancedHello2
, and assign the HOC and our HelloComponent
like so:
const EnhancedHello2 = withNameChange(HelloComponent);
To make a change to our HelloComponent
, we can render the EnhancedHello
component like so:
<EnhancedHello />
Now, the text in our HelloComponent
becomes this:
<div>Hello New World</div>
To change the name
prop, all we have to do is this:
<EnhancedHello name='Shedrack' />
The text in our HelloComponent
becomes this:
<div>Hello Shedrack</div>
Let’s Build A Higher-Order Component
In this section, we will build a HOC that takes a component that has a name
prop, and then we will make use of the name
prop in our HOC.
So, generate a new React app with create-react-app
, like so:
npx create-react-app my-app
After it is generated, replace the code in your index.js
file with the following snippet.
import React from 'react'; import { render } from 'react-dom'; const Hello = ({ name }) => <h1> Hello {name}! </h1>; function withName(WrappedComponent) { return class extends React.Component { render() { return <WrappedComponent name="Smashing Magazine" {...this.props} />; } }; } const NewComponent = withName(Hello); const App = () => <div> <NewComponent /> </div>; render(<App />, document.getElementById('root'));
Once you have replaced the code in your index.js
file, you should see the following on your screen:
Let’s go through the snippet bit by bit.
const Hello = ({ name }) => <h1> Hello {name}! </h1>;
Here, we create a functional component that has a prop called name
. In this functional component, we render the “Hello” and the value of the name
prop in an h1
tag.
function withName(WrappedComponent) { return class extends React.Component { render() { return <WrappedComponent name="Smashing Magazine" {...this.props} />; } }; }
Above, we create a higher-order functional component named withName()
. Then, we return an anonymous class component inside that renders the component wrapped in the HOC. And we assign a value to the prop of the wrapped component.
const NewComponent = withName(Hello);
Here, we create a new component named NewComponent
. We use the HOC that we created, and assign to it the functional component that we created at the start of the code base, named hello
.
const App = () => <div> <NewComponent /> </div>; render(<App />, document.getElementById('root'));
All we are doing above is creating another functional component, named App
. It renders the NewComponent
that we upgraded with our HOC in a div
. Then, we use the react-dom function render
to display the component in the browser.
That’s all we need to do! Our withName
function takes a component as an argument and returns a HOC. A few months from now, if we decide to change things around, we only have to edit our HOC.
Conclusion
I hope you’ve enjoyed working through this tutorial. You can read more about higher-order components in the references listed below. If you have any questions, leave them in the comments section below. I’ll be happy to answer every one.
Resources And References
- “Higher-Order Functions”, Eloquent JavaScript, Marijn Haverbeke
- “Introduction to Higher-Order Components (HOCs) in React”, Johnson Ogwuru
- “React Higher-Order Components”, Tyler McGinnis
- “Simple Explanation of Higher-Order Components (HOCs)”, Jakob Lind
- “A Quick Intro to React’s Higher-Order Components”, Patrick Moriarty, Alligator.io
- “Higher-Order Functions in JavaScript”, Zslot Nagy
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