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React (aka React.js or ReactJS) is an open-source front-end JavaScript library that is used for building composable user interfaces, especially for single-page applications. It is used for handling view layer for web and mobile apps based on components in a declarative approach.
React was created by Jordan Walke, a software engineer working for Facebook. React was first deployed on Facebook's News Feed in 2011 and on Instagram in 2012.
The history of ReactJS started in 2010 with the creation of XHP. XHP is a PHP extension which improved the syntax of the language such that XML document fragments become valid PHP expressions and the primary purpose was used to create custom and reusable HTML elements.
The main principle of this extension was to make front-end code easier to understand and to help avoid cross-site scripting attacks. The project was successful to prevent the malicious content submitted by the scrubbing user.
But there was a different problem with XHP in which dynamic web applications require many roundtrips to the server, and XHP did not solve this problem. Also, the whole UI was re-rendered for small change in the application. Later, the initial prototype of React is created with the name FaxJ by Jordan inspired from XHP. Finally after sometime React has been introduced as a new library into JavaScript world.
Note: JSX comes from the idea of XHP
The major features of React are:
JSX stands for JavaScript XML and it is an XML-like syntax extension to ECMAScript. Basically it just provides the syntactic sugar for the React.createElement(type, props, ...children)
function, giving us expressiveness of JavaScript along with HTML like template syntax.
In the example below, the text inside <h1>
tag is returned as JavaScript function to the render function.
export default function App() {
return <h1 className="greeting">{"Hello, this is a JSX Code!"}</h1>;
}
If you don't use JSX syntax then the respective JavaScript code should be written as below,
import { createElement } from "react";
export default function App() {
return createElement(
"h1",
{ className: "greeting" },
"Hello, this is a JSX Code!"
);
}
```jsx harmony class App extends React.Component { render() { return
Note: JSX is stricter than HTML
An Element is a plain object describing what you want to appear on the screen in terms of the DOM nodes or other components. Elements can contain other Elements in their props. Creating a React element is cheap. Once an element is created, it cannot be mutated.
The JavaScript representation(Without JSX) of React Element would be as follows:
const element = React.createElement("div", { id: "login-btn" }, "Login");
and this element can be simiplified using JSX
<div id="login-btn">Login</div>
The above React.createElement()
function returns an object as below:
{
type: 'div',
props: {
children: 'Login',
id: 'login-btn'
}
}
Finally, this element renders to the DOM using ReactDOM.render()
.
Whereas a component can be declared in several different ways. It can be a class with a render()
method or it can be defined as a function. In either case, it takes props as an input, and returns a JSX tree as the output:
const Button = ({ handleLogin }) => (
<div id={"login-btn"} onClick={handleLogin}>
Login
</div>
);
Then JSX gets transpiled to a React.createElement()
function tree:
const Button = ({ handleLogin }) =>
React.createElement(
"div",
{ id: "login-btn", onClick: handleLogin },
"Login"
);
Components are the building blocks of creating User Interfaces(UI) in React. There are two possible ways to create a component.
Function Components: This is the simplest way to create a component. Those are pure JavaScript functions that accept props object as the one and only one parameter and return React elements to render the output:
function Greeting({ message }) {
return <h1>{`Hello, ${message}`}</h1>;
}
Class Components: You can also use ES6 class to define a component. The above function component can be written as a class component:
class Greeting extends React.Component {
render() {
return <h1>{`Hello, ${this.props.message}`}</h1>;
}
}
After the addition of Hooks(i.e. React 16.8 onwards) it is always recommended to use Function components over Class components in React. Because you could use state, lifecycle methods and other features that were only available in class component present in function component too.
But even there are two reasons to use Class components over Function components.
So the summary to this question is as follows:
Use Function Components:
Use Class Components:
Note: You can also use reusable react error boundary third-party component without writing any class. i.e, No need to use class components for Error boundaries.
The usage of Error boundaries from the above library is quite straight forward.
Note when using react-error-boundary: ErrorBoundary is a client component. You can only pass props to it that are serializable or use it in files that have a
"use client";
directive.
"use client";
import { ErrorBoundary } from "react-error-boundary";
<ErrorBoundary fallback={<div>Something went wrong</div>}>
<ExampleApplication />
</ErrorBoundary>;
Pure components are the components which render the same output for the same state and props. In function components, you can achieve these pure components through memoized React.memo()
API wrapping around the component. This API prevents unnecessary re-renders by comparing the previous props and new props using shallow comparison. So it will be helpful for performance optimizations.
But at the same time, it won't compare the previous state with the current state because function component itself prevents the unnecessary rendering by default when you set the same state again.
The syntactic representation of memoized components looks like below,
const MemoizedComponent = memo(SomeComponent, arePropsEqual?);
Below is the example of how child component(i.e., EmployeeProfile) prevents re-renders for the same props passed by parent component(i.e.,EmployeeRegForm).
import { memo, useState } from "react";
const EmployeeProfile = memo(function EmployeeProfile({ name, email }) {
return (
<>
<p>Name:{name}</p>
<p>Email: {email}</p>
</>
);
});
export default function EmployeeRegForm() {
const [name, setName] = useState("");
const [email, setEmail] = useState("");
return (
<>
<label>
Name:{" "}
<input value={name} onChange={(e) => setName(e.target.value)} />
</label>
<label>
Email:{" "}
<input value={email} onChange={(e) => setEmail(e.target.value)} />
</label>
<hr />
<EmployeeProfile name={name} />
</>
);
}
In the above code, the email prop has not been passed to child component. So there won't be any re-renders for email prop change.
In class components, the components extending React.PureComponent
instead of React.Component
become the pure components. When props or state changes, PureComponent will do a shallow comparison on both props and state by invoking shouldComponentUpdate()
lifecycle method.
Note: React.memo()
is a higher-order component.
State of a component is an object that holds some information that may change over the lifetime of the component. The important point is whenever the state object changes, the component re-renders. It is always recommended to make our state as simple as possible and minimize the number of stateful components.
Let's take an example of User component with message
state. Here, useState hook has been used to add state to the User component and it returns an array with current state and function to update it.
import { useState } from "react";
function User() {
const [message, setMessage] = useState("Welcome to React world");
return (
<div>
<h1>{message}</h1>
</div>
);
}
Whenever React calls your component or access useState
hook, it gives you a snapshot of the state for that particular render.
```jsx harmony import React from "react"; class User extends React.Component { constructor(props) { super(props); this.state = { message: "Welcome to React world", }; } render() { return (
State is similar to props, but it is private and fully controlled by the component ,i.e., it is not accessible to any other component till the owner component decides to pass it.
Props are inputs to components. They are single values or objects containing a set of values that are passed to components on creation similar to HTML-tag attributes. Here, the data is passed down from a parent component to a child component.
The primary purpose of props in React is to provide following component functionality:
this.props.reactProp
inside component's render()
method.For example, let us create an element with reactProp
property:
<Element reactProp={"1"} />
This reactProp
(or whatever you came up with) attribute name then becomes a property attached to React's native props object which originally already exists on all components created using React library.
props.reactProp;
For example, the usage of props in function component looks like below:
import React from "react";
import ReactDOM from "react-dom";
const ChildComponent = (props) => {
return (
<div>
<p>{props.name}</p>
<p>{props.age}</p>
<p>{props.gender}</p>
</div>
);
};
const ParentComponent = () => {
return (
<div>
<ChildComponent name="John" age="30" gender="male" />
<ChildComponent name="Mary" age="25" geneder="female" />
</div>
);
};
The properties from props object can be accessed directly using destructing feature from ES6 (ECMAScript 2015). It is also possible to fallback to default value when the prop value is not specified. The above child component can be simplified like below.
const ChildComponent = ({ name, age, gender = "male" }) => {
return (
<div>
<p>{name}</p>
<p>{age}</p>
<p>{gender}</p>
</div>
);
};
Note: The default value won't be used if you pass null
or 0
value. i.e, default value is only used if the prop value is missed or undefined
value has been passed.
{this.props.name}
{this.props.age}
{this.props.gender}
In React, both state
and props
are plain JavaScript objects and used to manage the data of a component, but they are used in different ways and have different characteristics.
The state
entity is managed by the component itself and can be updated using the setter(setState()
for class components) function. Unlike props, state can be modified by the component and is used to manage the internal state of the component. i.e, state acts as a component's memory. Moreover, changes in the state trigger a re-render of the component and its children. The components cannot become reusable with the usage of state alone.
On the otherhand, props
(short for "properties") are passed to a component by its parent component and are read-only
, meaning that they cannot be modified by the own component itself. i.e, props acts as arguments for a function. Also, props can be used to configure the behavior of a component and to pass data between components. The components become reusable with the usage of props.
Below are some of the main differences between HTML and React event handling,
In HTML, the event name usually represents in lowercase as a convention:
<button onclick="activateLasers()"></button>
Whereas in React it follows camelCase convention:
<button onClick={activateLasers}>
In HTML, you can return false
to prevent default behavior:
<a
href="#"
onclick='console.log("The link was clicked."); return false;'
/>
Whereas in React you must call preventDefault()
explicitly:
function handleClick(event) {
event.preventDefault();
console.log("The link was clicked.");
}
In HTML, you need to invoke the function by appending ()
Whereas in react you should not append ()
with the function name. (refer "activateLasers" function in the first point for example)
SyntheticEvent
is a cross-browser wrapper around the browser's native event. Its API is same as the browser's native event, including stopPropagation()
and preventDefault()
, except the events work identically across all browsers. The native events can be accessed directly from synthetic events using nativeEvent
attribute.
Let's take an example of BookStore title search component with the ability to get all native event properties
function BookStore() {
function handleTitleChange(e) {
console.log("The new title is:", e.target.value);
// 'e' represents synthetic event
const nativeEvent = e.nativeEvent;
console.log(nativeEvent);
e.stopPropagation();
e.preventDefault();
}
return <input name="title" onChange={handleTitleChange} />;
}
You can use either if statements or ternary expressions which are available from JS to conditionally render expressions. Apart from these approaches, you can also embed any expressions in JSX by wrapping them in curly braces and then followed by JS logical operator &&
.
<h1>Hello!</h1>;
{
messages.length > 0 && !isLogin ? (
<h2>You have {messages.length} unread messages.</h2>
) : (
<h2>You don't have unread messages.</h2>
);
}
A key
is a special attribute you should include when mapping over arrays to render data. Key prop helps React identify which items have changed, are added, or are removed.
Keys should be unique among its siblings. Most often we use ID from our data as key:
const todoItems = todos.map((todo) => <li key={todo.id}>{todo.text}</li>);
When you don't have stable IDs for rendered items, you may use the item index as a key as a last resort:
const todoItems = todos.map((todo, index) => (
<li key={index}>{todo.text}</li>
));
Note:
li
tag.key
prop is not present on list items.key={Math.random()}
. Because the keys will never match up between re-renders and DOM created everytime.The Virtual DOM (VDOM) is an in-memory representation of Real DOM. The representation of a UI is kept in memory and synced with the "real" DOM. It's a step that happens between the render function being called and the displaying of elements on the screen. This entire process is called reconciliation.
The Virtual DOM works in three simple steps.
Whenever any underlying data changes, the entire UI is re-rendered in Virtual DOM representation.
Then the difference between the previous DOM representation and the new one is calculated.
Once the calculations are done, the real DOM will be updated with only the things that have actually changed.
The Shadow DOM is a browser technology designed primarily for scoping variables and CSS in web components. The Virtual DOM is a concept implemented by libraries in JavaScript on top of browser APIs.
Fiber is the new reconciliation engine or reimplementation of core algorithm in React v16. The goal of React Fiber is to increase its suitability for areas like animation, layout, gestures, ability to pause, abort, or reuse work and assign priority to different types of updates; and new concurrency primitives.
The goal of React Fiber is to increase its suitability for areas like animation, layout, and gestures. Its headline feature is incremental rendering: the ability to split rendering work into chunks and spread it out over multiple frames.
from documentation
Its main goals are:
A component that controls the input elements within the forms on subsequent user input is called Controlled Component, i.e, every state mutation will have an associated handler function. That means, the displayed data is always in sync with the state of the component.
The controlled components will be implemented using the below steps,
For example, the name input field updates the user name using handleChange
event handler as below,
import React, { useState } from "react";
function UserProfile() {
const [username, setUsername] = useState("");
const handleChange = (e) => {
setUsername(e.target.value);
};
return (
<form>
<label>
Name:
<input type="text" value={username} onChange={handleChange} />
</label>
</form>
);
}
The Uncontrolled Components are the ones that store their own state internally, and you query the DOM using a ref to find its current value when you need it. This is a bit more like traditional HTML.
The uncontrolled components will be implemented using the below steps,
React.createRef()
in class based component.ref
in event handlers or componentDidMount
for class componentsIn the below UserProfile component, the username
input is accessed using ref.
import React, { useRef } from "react";
function UserProfile() {
const usernameRef = useRef(null);
const handleSubmit = (event) => {
event.preventDefault();
console.log("The submitted username is: " + usernameRef.current.value);
};
return (
<form onSubmit={handleSubmit}>
<label>
Username:
<input type="text" ref={usernameRef} />
</label>
<button type="submit">Submit</button>
</form>
);
}
In most cases, it's recommend to use controlled components to implement forms. In a controlled component, form data is handled by a React component. The alternative is uncontrolled components, where form data is handled by the DOM itself.
```jsx harmony class UserProfile extends React.Component { constructor(props) { super(props); this.handleSubmit = this.handleSubmit.bind(this); this.input = React.createRef(); } handleSubmit(event) { alert("A name was submitted: " + this.input.current.value); event.preventDefault(); } render() { return (
); } } ```JSX elements will be transpiled to React.createElement()
functions to create React elements which are going to be used for the object representation of UI. Whereas cloneElement
is used to clone an element and pass it new props.
When several components need to share the same changing data then it is recommended to lift the shared state up to their closest common ancestor. That means if two child components share the same data from its parent, then move the state to parent instead of maintaining local state in both of the child components.
A higher-order component (HOC) is a function that takes a component and returns a new component. Basically, it's a pattern that is derived from React's compositional nature.
We call them pure components because they can accept any dynamically provided child component but they won't modify or copy any behavior from their input components.
const EnhancedComponent = higherOrderComponent(WrappedComponent);
HOC can be used for many use cases:
Children is a prop that allows you to pass components as data to other components, just like any other prop you use. Component tree put between component's opening and closing tag will be passed to that component as children
prop.
A simple usage of children prop looks as below,
function MyDiv({ children }){
return (
<div>
{children}
</div>;
);
}
export default function Greeting() {
return (
<MyDiv>
<span>{"Hello"}</span>
<span>{"World"}</span>
</MyDiv>
);
}
```jsx harmony const MyDiv = React.createClass({ render: function () { return
Note: There are several methods available in the legacy React API to work with this prop. These include React.Children.map
, React.Children.forEach
, React.Children.count
, React.Children.only
, React.Children.toArray
.
The comments in React/JSX are similar to JavaScript Multiline comments but are wrapped in curly braces.
Single-line comments:
<div>
{/* Single-line comments(In vanilla JavaScript, the single-line comments are represented by double slash(//)) */}
{`Welcome ${user}, let's play React`}
</div>
Multi-line comments:
<div>
{/* Multi-line comments for more than
one line */}
{`Welcome ${user}, let's play React`}
</div>
Reconciliation
is the process through which React updates the Browser DOM and makes React work faster. React use a diffing algorithm
so that component updates are predictable and faster. React would first calculate the difference between the real DOM
and the copy of DOM (Virtual DOM)
when there's an update of components.
React stores a copy of Browser DOM which is called Virtual DOM
. When we make changes or add data, React creates a new Virtual DOM and compares it with the previous one. This comparison is done by Diffing Algorithm
.
Now React compares the Virtual DOM with Real DOM. It finds out the changed nodes and updates only the changed nodes in Real DOM leaving the rest nodes as it is. This process is called Reconciliation.
No, currently React.lazy
function supports default exports only. If you would like to import modules which are named exports, you can create an intermediate module that reexports it as the default. It also ensures that tree shaking keeps working and don’t pull unused components.
Let's take a component file which exports multiple named components,
// MoreComponents.js
export const SomeComponent = /* ... */;
export const UnusedComponent = /* ... */;
and reexport MoreComponents.js
components in an intermediate file IntermediateComponent.js
// IntermediateComponent.js
export { SomeComponent as default } from "./MoreComponents.js";
Now you can import the module using lazy function as below,
import React, { lazy } from "react";
const SomeComponent = lazy(() => import("./IntermediateComponent.js"));
className
over class
attribute?The attribute names written in JSX turned into keys of JavaScript objects and the JavaScript names cannot contain dashes or reserved words, it is recommended to use camelCase wherever applicable in JSX code. The attribute class
is a keyword in JavaScript, and JSX is an extension of JavaScript. That's the principle reason why React uses className
instead of class
. Pass a string as the className
prop.
render() {
return <span className="menu navigation-menu">{'Menu'}</span>
}
It's a common pattern or practice in React for a component to return multiple elements. Fragments let you group a list of children without adding extra nodes to the DOM.
You need to use either <Fragment>
or a shorter syntax having empty tag (<></>
).
Below is the example of how to use fragment inside Story component.
function Story({ title, description, date }) {
return (
<Fragment>
<h2>{title}</h2>
<p>{description}</p>
<p>{date}</p>
</Fragment>
);
}
It is also possible to render list of fragments inside a loop with the mandatory key attribute supplied.
function StoryBook() {
return stories.map((story) => (
<Fragment key={story.id}>
<h2>{story.title}</h2>
<p>{story.description}</p>
<p>{story.date}</p>
</Fragment>
));
}
Usually, you don't need to use <Fragment>
until there is a need of key attribute. The usage of shorter syntax looks like below.
function Story({ title, description, date }) {
return (
<>
<h2>{title}</h2>
<p>{description}</p>
<p>{date}</p>
</>
);
}
Below are the list of reasons to prefer fragments over container DOM elements,
Portal is a recommended way to render children into a DOM node that exists outside the DOM hierarchy of the parent component. When using CSS transform in a component, its descendant elements should not use fixed positioning, otherwise the layout will blow up.
ReactDOM.createPortal(child, container);
The first argument is any render-able React child, such as an element, string, or fragment. The second argument is a DOM element.
If the behaviour of a component is independent of its state then it can be a stateless component. You can use either a function or a class for creating stateless components. But unless you need to use a lifecycle hook in your components, you should go for function components. There are a lot of benefits if you decide to use function components here; they are easy to write, understand, and test, a little faster, and you can avoid the this
keyword altogether.
If the behaviour of a component is dependent on the state of the component then it can be termed as stateful component. These stateful components are either function components with hooks or class components.
Let's take an example of function stateful component which update the state based on click event,
import React, {useState} from 'react';
const App = (props) => {
const [count, setCount] = useState(0);
handleIncrement() {
setCount(count+1);
}
return (
<>
<button onClick={handleIncrement}>Increment</button>
<span>Counter: {count}</span>
</>
)
}
The equivalent class stateful component with a state that gets initialized in the `constructor`. ```jsx harmony class App extends Component { constructor(props) { super(props); this.state = { count: 0 }; } handleIncrement() { setState({ count: this.state.count + 1 }); } render() { <> Count: {count} >; } } ```
When the application is running in development mode, React will automatically check all props that we set on components to make sure they have correct type. If the type is incorrect, React will generate warning messages in the console. It's disabled in production mode due to performance impact. The mandatory props are defined with isRequired
.
The set of predefined prop types:
PropTypes.number
PropTypes.string
PropTypes.array
PropTypes.object
PropTypes.func
PropTypes.node
PropTypes.element
PropTypes.bool
PropTypes.symbol
PropTypes.any
We can define propTypes
for User
component as below:
import React from "react";
import PropTypes from "prop-types";
class User extends React.Component {
static propTypes = {
name: PropTypes.string.isRequired,
age: PropTypes.number.isRequired,
};
render() {
return (
<>
<h1>{`Welcome, ${this.props.name}`}</h1>
<h2>{`Age, ${this.props.age}`}</h2>
</>
);
}
}
Note: In React v15.5 PropTypes were moved from React.PropTypes
to prop-types
library.
The Equivalent Functional Component
import React from "react";
import PropTypes from "prop-types";
function User({ name, age }) {
return (
<>
<h1>{`Welcome, ${name}`}</h1>
<h2>{`Age, ${age}`}</h2>
</>
);
}
User.propTypes = {
name: PropTypes.string.isRequired,
age: PropTypes.number.isRequired,
};
Below are the list of main advantages of React,
Apart from the advantages, there are few limitations of React too,
Normally we use PropTypes library (React.PropTypes
moved to a prop-types
package since React v15.5) for type checking in the React applications. For large code bases, it is recommended to use static type checkers such as Flow or TypeScript, that perform type checking at compile time and provide auto-completion features.
react-dom
package?The react-dom
package provides DOM-specific methods that can be used at the top level of your app. Most of the components are not required to use this module. Some of the methods of this package are:
render()
hydrate()
unmountComponentAtNode()
findDOMNode()
createPortal()
The ReactDOMServer
object enables you to render components to static markup (typically used on node server). This object is mainly used for server-side rendering (SSR). The following methods can be used in both the server and browser environments:
renderToString()
renderToStaticMarkup()
For example, you generally run a Node-based web server like Express, Hapi, or Koa, and you call renderToString
to render your root component to a string, which you then send as response.
// using Express
import { renderToString } from "react-dom/server";
import MyPage from "./MyPage";
app.get("/", (req, res) => {
res.write(
"<!DOCTYPE html><html><head><title>My Page</title></head><body>"
);
res.write('<div id="content">');
res.write(renderToString(<MyPage />));
res.write("</div></body></html>");
res.end();
});
The dangerouslySetInnerHTML
attribute is React's replacement for using innerHTML
in the browser DOM. Just like innerHTML
, it is risky to use this attribute considering cross-site scripting (XSS) attacks. You just need to pass a __html
object as key and HTML text as value.
In this example MyComponent uses dangerouslySetInnerHTML
attribute for setting HTML markup:
function createMarkup() {
return { __html: "First · Second" };
}
function MyComponent() {
return <div dangerouslySetInnerHTML={createMarkup()} />;
}
The style
attribute accepts a JavaScript object with camelCased properties rather than a CSS string. This is consistent with the DOM style JavaScript property, is more efficient, and prevents XSS security holes.
const divStyle = {
color: "blue",
backgroundImage: "url(" + imgUrl + ")",
};
function HelloWorldComponent() {
return <div style={divStyle}>Hello World!</div>;
}
Style keys are camelCased in order to be consistent with accessing the properties on DOM nodes in JavaScript (e.g. node.style.backgroundImage
).
Handling events in React elements has some syntactic differences:
Keys should be stable, predictable, and unique so that React can keep track of elements.
In the below code snippet each element's key will be based on ordering, rather than tied to the data that is being represented. This limits the optimizations that React can do and creates confusing bugs in the application.
{
todos.map((todo, index) => <Todo {...todo} key={index} />);
}
If you use element data for unique key, assuming todo.id
is unique to this list and stable, React would be able to reorder elements without needing to reevaluate them as much.
{
todos.map((todo) => <Todo {...todo} key={todo.id} />);
}
Note: If you don't specify key
prop at all, React will use index as a key's value while iterating over an array of data.
In some cases you want to render different components depending on some state. JSX does not render false
or undefined
, so you can use conditional short-circuiting to render a given part of your component only if a certain condition is true.
const MyComponent = ({ name, address }) => (
<div>
<h2>{name}</h2>
{address && <p>{address}</p>}
</div>
);
If you need an if-else
condition then use ternary operator.
const MyComponent = ({ name, address }) => (
<div>
<h2>{name}</h2>
{address ? <p>{address}</p> : <p>{"Address is not available"}</p>}
</div>
);
When we spread props we run into the risk of adding unknown HTML attributes, which is a bad practice. Instead we can use prop destructuring with ...rest
operator, so it will add only required props.
For example,
const ComponentA = () => (
<ComponentB isDisplay={true} className={"componentStyle"} />
);
const ComponentB = ({ isDisplay, ...domProps }) => (
<div {...domProps}>{"ComponentB"}</div>
);
There are memoize libraries available which can be used on function components.
For example moize
library can memoize the component in another component.
import moize from "moize";
import Component from "./components/Component"; // this module exports a non-memoized component
const MemoizedFoo = moize.react(Component);
const Consumer = () => {
<div>
{"I will memoize the following entry:"}
<MemoizedFoo />
</div>;
};
Update: Since React v16.6.0, we have a React.memo
. It provides a higher order component which memoizes component unless the props change. To use it, simply wrap the component using React.memo before you use it.
const MemoComponent = React.memo(function MemoComponent(props) {
/* render using props */
});
OR;
export default React.memo(MyFunctionComponent);
React is already equipped to handle rendering on Node servers. A special version of the DOM renderer is available, which follows the same pattern as on the client side.
import ReactDOMServer from "react-dom/server";
import App from "./App";
ReactDOMServer.renderToString(<App />);
This method will output the regular HTML as a string, which can be then placed inside a page body as part of the server response. On the client side, React detects the pre-rendered content and seamlessly picks up where it left off.
You should use Webpack's DefinePlugin
method to set NODE_ENV
to production
, by which it strip out things like propType validation and extra warnings. Apart from this, if you minify the code, for example, Uglify's dead-code elimination to strip out development only code and comments, it will drastically reduce the size of your bundle.
Both render props and higher-order components render only a single child but in most of the cases Hooks are a simpler way to serve this by reducing nesting in your tree.
A switching component is a component that renders one of many components. We need to use object to map prop values to components.
For example, a switching component to display different pages based on page
prop:
import HomePage from "./HomePage";
import AboutPage from "./AboutPage";
import ServicesPage from "./ServicesPage";
import ContactPage from "./ContactPage";
const PAGES = {
home: HomePage,
about: AboutPage,
services: ServicesPage,
contact: ContactPage,
};
const Page = (props) => {
const Handler = PAGES[props.page] || ContactPage;
return <Handler {...props} />;
};
// The keys of the PAGES object can be used in the prop types to catch dev-time errors.
Page.propTypes = {
page: PropTypes.oneOf(Object.keys(PAGES)).isRequired,
};
Mixins are a way to totally separate components to have a common functionality. Mixins should not be used and can be replaced with higher-order components or decorators.
One of the most commonly used mixins is PureRenderMixin
. You might be using it in some components to prevent unnecessary re-renders when the props and state are shallowly equal to the previous props and state:
const PureRenderMixin = require("react-addons-pure-render-mixin");
const Button = React.createClass({
mixins: [PureRenderMixin],
// ...
});
Pointer Events provide a unified way of handling all input events. In the old days we had a mouse and respective event listeners to handle them but nowadays we have many devices which don't correlate to having a mouse, like phones with touch surface or pens. We need to remember that these events will only work in browsers that support the Pointer Events specification.
The following event types are now available in React DOM:
onPointerDown
onPointerMove
onPointerUp
onPointerCancel
onGotPointerCapture
onLostPointerCapture
onPointerEnter
onPointerLeave
onPointerOver
onPointerOut
If you are rendering your component using JSX, the name of that component has to begin with a capital letter otherwise React will throw an error as an unrecognized tag. This convention is because only HTML elements and SVG tags can begin with a lowercase letter.
function SomeComponent {
// Code goes here
}
You can define function component whose name starts with lowercase letter, but when it's imported it should have a capital letter. Here lowercase is fine:
function myComponent {
render() {
return <div />;
}
}
export default myComponent;
While when imported in another file it should start with capital letter:
import MyComponent from "./myComponent";
Yes. In the past, React used to ignore unknown DOM attributes. If you wrote JSX with an attribute that React doesn't recognize, React would just skip it.
For example, let's take a look at the below attribute:
<div mycustomattribute={"something"} />
Would render an empty div to the DOM with React v15:
<div />
In React v16 any unknown attributes will end up in the DOM:
<div mycustomattribute="something" />
This is useful for supplying browser-specific non-standard attributes, trying new DOM APIs, and integrating with opinionated third-party libraries.
You can simply use Array.prototype.map
with ES6 arrow function syntax.
For example, the items
array of objects is mapped into an array of components:
<tbody>
{items.map((item) => (
<SomeComponent key={item.id} name={item.name} />
))}
</tbody>
But you can't iterate using for
loop:
<tbody>
for (let i = 0; i < items.length; i++) {
<SomeComponent key={items[i].id} name={items[i].name} />
}
</tbody>
This is because JSX tags are transpiled into function calls, and you can't use statements inside expressions. This may change thanks to do
expressions which are stage 1 proposal.
React (or JSX) doesn't support variable interpolation inside an attribute value. The below representation won't work:
<img className="image" src="https://github.com/sudheerj/reactjs-interview-questions/raw/master/images/{this.props.image}" />
But you can put any JS expression inside curly braces as the entire attribute value. So the below expression works:
<img className="image" src={"images/" + this.props.image} />
Using template strings will also work:
<img className="image" src={`images/${this.props.image}`} />
If you want to pass an array of objects to a component with a particular shape then use React.PropTypes.shape()
as an argument to React.PropTypes.arrayOf()
.
ReactComponent.propTypes = {
arrayWithShape: React.PropTypes.arrayOf(
React.PropTypes.shape({
color: React.PropTypes.string.isRequired,
fontSize: React.PropTypes.number.isRequired,
})
).isRequired,
};
You shouldn't use curly braces inside quotes because it is going to be evaluated as a string.
<div className="btn-panel {this.props.visible ? 'show' : 'hidden'}">
Instead you need to move curly braces outside (don't forget to include spaces between class names):
<div className={'btn-panel ' + (this.props.visible ? 'show' : 'hidden')}>
Template strings will also work:
<div className={`btn-panel ${this.props.visible ? 'show' : 'hidden'}`}>
The react
package contains React.createElement()
, React.Component
, React.Children
, and other helpers related to elements and component classes. You can think of these as the isomorphic or universal helpers that you need to build components. The react-dom
package contains ReactDOM.render()
, and in react-dom/server
we have server-side rendering support with ReactDOMServer.renderToString()
and ReactDOMServer.renderToStaticMarkup()
.
The React team worked on extracting all DOM-related features into a separate library called ReactDOM. React v0.14 is the first release in which the libraries are split. By looking at some of the packages, react-native
, react-art
, react-canvas
, and react-three
, it has become clear that the beauty and essence of React has nothing to do with browsers or the DOM.
To build more environments that React can render to, React team planned to split the main React package into two: react
and react-dom
. This paves the way to writing components that can be shared between the web version of React and React Native.
If you try to render a <label>
element bound to a text input using the standard for
attribute, then it produces HTML missing that attribute and prints a warning to the console.
<label for={'user'}>{'User'}</label>
<input type={'text'} id={'user'} />
Since for
is a reserved keyword in JavaScript, use htmlFor
instead.
<label htmlFor={'user'}>{'User'}</label>
<input type={'text'} id={'user'} />
You can use spread operator in regular React:
<button style={{ ...styles.panel.button, ...styles.panel.submitButton }}>
{"Submit"}
</button>
If you're using React Native then you can use the array notation:
<button style={[styles.panel.button, styles.panel.submitButton]}>
{"Submit"}
</button>
You can use the useState
hook to manage the width and height state variables, and the useEffect
hook to add and remove the resize
event listener. The []
dependency array passed to useEffect ensures that the effect only runs once (on mount) and not on every re-render.
import React, { useState, useEffect } from "react";
function WindowDimensions() {
const [dimensions, setDimensions] = useState({
width: window.innerWidth,
height: window.innerHeight,
});
useEffect(() => {
function handleResize() {
setDimensions({
width: window.innerWidth,
height: window.innerHeight,
});
}
window.addEventListener("resize", handleResize);
return () => window.removeEventListener("resize", handleResize);
}, []);
return (
<span>
{dimensions.width} x {dimensions.height}
</span>
);
}
We can use <pre>
tag so that the formatting of the JSON.stringify()
is retained:
const data = { name: "John", age: 42 };
function User {
return <pre>{JSON.stringify(data, null, 2)}</pre>;
}
const container = createRoot(document.getElementById("container"));
container.render(<User />);
```jsx harmony const data = { name: "John", age: 42 }; class User extends React.Component { render() { return
{JSON.stringify(data, null, 2)}; } } React.render(
The React philosophy is that props should be immutable(read only) and top-down. This means that a parent can send any prop values to a child, but the child can't modify received props.
You need to use useEffect
hook to set focus on input field during page load time for functional component.
import React, { useEffect, useRef } from "react";
const App = () => {
const inputElRef = useRef(null);
useEffect(() => {
inputElRef.current.focus();
}, []);
return (
<div>
<input defaultValue={"Won't focus"} />
<input ref={inputElRef} defaultValue={"Will focus"} />
</div>
);
};
ReactDOM.render(<App />, document.getElementById("app"));
You can do it by creating _ref_ for `input` element and using it in `componentDidMount()`: ```jsx harmony class App extends React.Component { componentDidMount() { this.nameInput.focus(); } render() { return (
You can use React.version
to get the version.
const REACT_VERSION = React.version;
ReactDOM.render(
<div>{`React version: ${REACT_VERSION}`}</div>,
document.getElementById("app")
);
Add a listener on the history
object to record each page view:
history.listen(function (location) {
window.ga("set", "page", location.pathname + location.search);
window.ga("send", "pageview", location.pathname + location.search);
});
React does not apply vendor prefixes automatically. You need to add vendor prefixes manually.
<div
style={{
transform: "rotate(90deg)",
WebkitTransform: "rotate(90deg)", // note the capital 'W' here
msTransform: "rotate(90deg)", // 'ms' is the only lowercase vendor prefix
}}
/>
You should use default for exporting the components
import User from "user";
export default function MyProfile {
return <User type="customer">//...</User>;
}
```jsx harmony
import React from "react";
import User from "user";
export default class MyProfile extends React.Component {
render() {
return
With the export specifier, the MyProfile is going to be the member and exported to this module and the same can be imported without mentioning the name in other components.
The component names should start with an uppercase letter but there are few exceptions to this convention. The lowercase tag names with a dot (property accessors) are still considered as valid component names. For example, the below tag can be compiled to a valid component,
render() {
return (
<obj.component/> // `React.createElement(obj.component)`
)
}
If you want to use async
/await
in React, you will need Babel and transform-async-to-generator plugin. React Native ships with Babel and a set of transforms.
There are two common practices for React project file structure.
Grouping by features or routes:
One common way to structure projects is locate CSS, JS, and tests together, grouped by feature or route.
common/
├─ Avatar.js
├─ Avatar.css
├─ APIUtils.js
└─ APIUtils.test.js
feed/
├─ index.js
├─ Feed.js
├─ Feed.css
├─ FeedStory.js
├─ FeedStory.test.js
└─ FeedAPI.js
profile/
├─ index.js
├─ Profile.js
├─ ProfileHeader.js
├─ ProfileHeader.css
└─ ProfileAPI.js
Grouping by file type:
Another popular way to structure projects is to group similar files together.
api/
├─ APIUtils.js
├─ APIUtils.test.js
├─ ProfileAPI.js
└─ UserAPI.js
components/
├─ Avatar.js
├─ Avatar.css
├─ Feed.js
├─ Feed.css
├─ FeedStory.js
├─ FeedStory.test.js
├─ Profile.js
├─ ProfileHeader.js
└─ ProfileHeader.css
React Transition Group and React Motion are popular animation packages in React ecosystem.
It is recommended to avoid hard coding style values in components. Any values that are likely to be used across different UI components should be extracted into their own modules.
For example, these styles could be extracted into a separate component:
export const colors = {
white,
black,
blue,
};
export const space = [0, 8, 16, 32, 64];
And then imported individually in other components:
import { space, colors } from "./styles";
ESLint is a popular JavaScript linter. There are plugins available that analyse specific code styles. One of the most common for React is an npm package called eslint-plugin-react
. By default, it will check a number of best practices, with rules checking things from keys in iterators to a complete set of prop types.
Another popular plugin is eslint-plugin-jsx-a11y
, which will help fix common issues with accessibility. As JSX offers slightly different syntax to regular HTML, issues with alt
text and tabindex
, for example, will not be picked up by regular plugins.
React Router is a powerful routing library built on top of React that helps you add new screens and flows to your application incredibly quickly, all while keeping the URL in sync with what's being displayed on the page.
React Router is a wrapper around the history
library which handles interaction with the browser's window.history
with its browser and hash histories. It also provides memory history which is useful for environments that don't have global history, such as mobile app development (React Native) and unit testing with Node.
<Router>
components of React Router v6?React Router v6 provides below 4 <Router>
components:
<BrowserRouter>
:Uses the HTML5 history API for standard web apps.<HashRouter>
:Uses hash-based routing for static servers.<MemoryRouter>
:Uses in-memory routing for testing and non-browser environments.<StaticRouter>
:Provides static routing for server-side rendering (SSR).The above components will create browser, hash, memory and static history instances. React Router v6 makes the properties and methods of the history
instance associated with your router available through the context in the router
object.
push()
and replace()
methods of history
?A history instance has two methods for navigation purpose.
push()
replace()
If you think of the history as an array of visited locations, push()
will add a new location to the array and replace()
will replace the current location in the array with the new one.
There are three different ways to achieve programmatic routing/navigation within components.
Using the withRouter()
higher-order function:
The withRouter()
higher-order function will inject the history object as a prop of the component. This object provides push()
and replace()
methods to avoid the usage of context.
import { withRouter } from "react-router-dom"; // this also works with 'react-router-native'
const Button = withRouter(({ history }) => (
<button
type="button"
onClick={() => {
history.push("/new-location");
}}
>
{"Click Me!"}
</button>
));
Using <Route>
component and render props pattern:
The <Route>
component passes the same props as withRouter()
, so you will be able to access the history methods through the history prop.
import { Route } from "react-router-dom";
const Button = () => (
<Route
render={({ history }) => (
<button
type="button"
onClick={() => {
history.push("/new-location");
}}
>
{"Click Me!"}
</button>
)}
/>
);
Using context:
This option is not recommended and treated as unstable API.
const Button = (props, context) => (
<button
type="button"
onClick={() => {
context.history.push("/new-location");
}}
>
{"Click Me!"}
</button>
);
Button.contextTypes = {
history: React.PropTypes.shape({
push: React.PropTypes.func.isRequired,
}),
};
The ability to parse query strings was taken out of React Router v4 because there have been user requests over the years to support different implementation. So the decision has been given to users to choose the implementation they like. The recommended approach is to use query strings library.
const queryString = require("query-string");
const parsed = queryString.parse(props.location.search);
You can also use URLSearchParams
if you want something native:
const params = new URLSearchParams(props.location.search);
const foo = params.get("name");
You should use a polyfill for IE11.
You have to wrap your Route's in a <Switch>
block because <Switch>
is unique in that it renders a route exclusively.
At first you need to add Switch
to your imports:
import { Switch, Router, Route } from "react-router";
Then define the routes within <Switch>
block:
<Router>
<Switch>
<Route {/* ... */} />
<Route {/* ... */} />
</Switch>
</Router>
history.push
method in React Router v4?While navigating you can pass props to the history
object:
this.props.history.push({
pathname: "/template",
search: "?name=sudheer",
state: { detail: response.data },
});
The search
property is used to pass query params in push()
method.
A <Switch>
renders the first child <Route>
that matches. A <Route>
with no path always matches. So you just need to simply drop path attribute as below
<Switch>
<Route exact path="/" component={Home} />
<Route path="/user" component={User} />
<Route component={NotFound} />
</Switch>
Below are the list of steps to get history object on React Router v4,
Create a module that exports a history
object and import this module across the project.
For example, create history.js
file:
import { createBrowserHistory } from "history";
export default createBrowserHistory({
/* pass a configuration object here if needed */
});
You should use the <Router>
component instead of built-in routers. Import the above history.js
inside index.js
file:
import { Router } from "react-router-dom";
import history from "./history";
import App from "./App";
ReactDOM.render(
<Router history={history}>
<App />
</Router>,
holder
);
You can also use push method of history
object similar to built-in history object:
// some-other-file.js
import history from "./history";
history.push("/go-here");
The react-router
package provides <Redirect>
component in React Router. Rendering a <Redirect>
will navigate to a new location. Like server-side redirects, the new location will override the current location in the history stack.
import { Redirect } from "react-router";
export default function Login {
if (this.state.isLoggedIn === true) {
return <Redirect to="/your/redirect/page" />;
} else {
return <div>{"Login Please"}</div>;
}
}
```jsx
import React, { Component } from "react";
import { Redirect } from "react-router";
export default class LoginComponent extends Component {
render() {
if (this.state.isLoggedIn === true) {
return
The React Intl library makes internationalization in React straightforward, with off-the-shelf components and an API that can handle everything from formatting strings, dates, and numbers, to pluralization. React Intl is part of FormatJS which provides bindings to React via its components and API.
Below are the main features of React Intl,
The library provides two ways to format strings, numbers, and dates:
Using react components:
<FormattedMessage
id={"account"}
defaultMessage={"The amount is less than minimum balance."}
/>
Using an API:
const messages = defineMessages({
accountMessage: {
id: "account",
defaultMessage: "The amount is less than minimum balance.",
},
});
formatMessage(messages.accountMessage);
<FormattedMessage>
as placeholder using React Intl?The <Formatted... />
components from react-intl
return elements, not plain text, so they can't be used for placeholders, alt text, etc. In that case, you should use lower level API formatMessage()
. You can inject the intl
object into your component using injectIntl()
higher-order component and then format the message using formatMessage()
available on that object.
import React from "react";
import { injectIntl, intlShape } from "react-intl";
const MyComponent = ({ intl }) => {
const placeholder = intl.formatMessage({ id: "messageId" });
return <input placeholder={placeholder} />;
};
MyComponent.propTypes = {
intl: intlShape.isRequired,
};
export default injectIntl(MyComponent);
You can get the current locale in any component of your application using injectIntl()
:
import { injectIntl, intlShape } from "react-intl";
const MyComponent = ({ intl }) => (
<div>{`The current locale is ${intl.locale}`}</div>
);
MyComponent.propTypes = {
intl: intlShape.isRequired,
};
export default injectIntl(MyComponent);
The injectIntl()
higher-order component will give you access to the formatDate()
method via the props in your component. The method is used internally by instances of FormattedDate
and it returns the string representation of the formatted date.
import { injectIntl, intlShape } from "react-intl";
const stringDate = this.props.intl.formatDate(date, {
year: "numeric",
month: "numeric",
day: "numeric",
});
const MyComponent = ({ intl }) => (
<div>{`The formatted date is ${stringDate}`}</div>
);
MyComponent.propTypes = {
intl: intlShape.isRequired,
};
export default injectIntl(MyComponent);
Shallow rendering is useful for writing unit test cases in React. It lets you render a component one level deep and assert facts about what its render method returns, without worrying about the behavior of child components, which are not instantiated or rendered.
For example, if you have the following component:
function MyComponent() {
return (
<div>
<span className={"heading"}>{"Title"}</span>
<span className={"description"}>{"Description"}</span>
</div>
);
}
Then you can assert as follows:
import ShallowRenderer from "react-test-renderer/shallow";
// in your test
const renderer = new ShallowRenderer();
renderer.render(<MyComponent />);
const result = renderer.getRenderOutput();
expect(result.type).toBe("div");
expect(result.props.children).toEqual([
<span className={"heading"}>{"Title"}</span>,
<span className={"description"}>{"Description"}</span>,
]);
TestRenderer
package in React?This package provides a renderer that can be used to render components to pure JavaScript objects, without depending on the DOM or a native mobile environment. This package makes it easy to grab a snapshot of the platform view hierarchy (similar to a DOM tree) rendered by a ReactDOM or React Native without using a browser or jsdom
.
import TestRenderer from "react-test-renderer";
const Link = ({ page, children }) => <a href={page}>{children}</a>;
const testRenderer = TestRenderer.create(
<Link page={"https://www.facebook.com/"}>{"Facebook"}</Link>
);
console.log(testRenderer.toJSON());
// {
// type: 'a',
// props: { href: 'https://www.facebook.com/' },
// children: [ 'Facebook' ]
// }
ReactTestUtils are provided in the with-addons
package and allow you to perform actions against a simulated DOM for the purpose of unit testing.
Jest is a JavaScript unit testing framework created by Facebook based on Jasmine and provides automated mock creation and a jsdom
environment. It's often used for testing components.
There are couple of advantages compared to Jasmine:
jsdom
) so that your tests can be run on the command line.Let's write a test for a function that adds two numbers in sum.js
file:
const sum = (a, b) => a + b;
export default sum;
Create a file named sum.test.js
which contains actual test:
import sum from "./sum";
test("adds 1 + 2 to equal 3", () => {
expect(sum(1, 2)).toBe(3);
});
And then add the following section to your package.json
:
{
"scripts": {
"test": "jest"
}
}
Finally, run yarn test
or npm test
and Jest will print a result:
$ yarn test
PASS ./sum.test.js
✓ adds 1 + 2 to equal 3 (2ms)
Flux is an application design paradigm used as a replacement for the more traditional MVC pattern. It is not a framework or a library but a new kind of architecture that complements React and the concept of Unidirectional Data Flow. Facebook uses this pattern internally when working with React.
The workflow between dispatcher, stores and views components with distinct inputs and outputs as follows:
Redux is a predictable state container for JavaScript apps based on the Flux design pattern. Redux can be used together with React, or with any other view library. It is tiny (about 2kB) and has no dependencies.
Redux follows three fundamental principles:
Instead of saying downsides we can say that there are few compromises of using Redux over Flux. Those are as follows:
redux-immutable-state-invariant
, Immutable.js, or instructing your team to write non-mutating code.mapStateToProps()
and mapDispatchToProps()
?mapStateToProps()
is a utility which helps your component get updated state (which is updated by some other components):
const mapStateToProps = (state) => {
return {
todos: getVisibleTodos(state.todos, state.visibilityFilter),
};
};
mapDispatchToProps()
is a utility which will help your component to fire an action event (dispatching action which may cause change of application state):
const mapDispatchToProps = (dispatch) => {
return {
onTodoClick: (id) => {
dispatch(toggleTodo(id));
},
};
};
It is recommended to always use the “object shorthand” form for the mapDispatchToProps
.
Redux wraps it in another function that looks like (…args) => dispatch(onTodoClick(…args)), and pass that wrapper function as a prop to your component.
const mapDispatchToProps = {
onTodoClick,
};
Dispatching an action within a reducer is an anti-pattern. Your reducer should be without side effects, simply digesting the action payload and returning a new state object. Adding listeners and dispatching actions within the reducer can lead to chained actions and other side effects.
You just need to export the store from the module where it created with createStore()
. Also, it shouldn't pollute the global window object.
store = createStore(myReducer);
export default store;
These libraries are very different for very different purposes, but there are some vague similarities.
Redux is a tool for managing state throughout the application. It is usually used as an architecture for UIs. Think of it as an alternative to (half of) Angular. RxJS is a reactive programming library. It is usually used as a tool to accomplish asynchronous tasks in JavaScript. Think of it as an alternative to Promises. Redux uses the Reactive paradigm because the Store is reactive. The Store observes actions from a distance, and changes itself. RxJS also uses the Reactive paradigm, but instead of being an architecture, it gives you basic building blocks, Observables, to accomplish this pattern.
You need to write a root reducer in your application which delegate handling the action to the reducer generated by combineReducers()
.
For example, let us take rootReducer()
to return the initial state after USER_LOGOUT
action. As we know, reducers are supposed to return the initial state when they are called with undefined
as the first argument, no matter the action.
const appReducer = combineReducers({
/* your app's top-level reducers */
});
const rootReducer = (state, action) => {
if (action.type === "USER_LOGOUT") {
state = undefined;
}
return appReducer(state, action);
};
In case of using redux-persist
, you may also need to clean your storage. redux-persist
keeps a copy of your state in a storage engine. First, you need to import the appropriate storage engine and then, to parse the state before setting it to undefined and clean each storage state key.
const appReducer = combineReducers({
/* your app's top-level reducers */
});
const rootReducer = (state, action) => {
if (action.type === "USER_LOGOUT") {
Object.keys(state).forEach((key) => {
storage.removeItem(`persist:${key}`);
});
state = undefined;
}
return appReducer(state, action);
};
You can use Context in your application directly and is going to be great for passing down data to deeply nested components which what it was designed for.
Whereas Redux is much more powerful and provides a large number of features that the Context API doesn't provide. Also, React Redux uses context internally but it doesn't expose this fact in the public API.
Reducers always return the accumulation of the state (based on all previous and current actions). Therefore, they act as a reducer of state. Each time a Redux reducer is called, the state and action are passed as parameters. This state is then reduced (or accumulated) based on the action, and then the next state is returned. You could reduce a collection of actions and an initial state (of the store) on which to perform these actions to get the resulting final state.
You can use redux-thunk
middleware which allows you to define async actions.
Let's take an example of fetching specific account as an AJAX call using fetch API:
export function fetchAccount(id) {
return (dispatch) => {
dispatch(setLoadingAccountState()); // Show a loading spinner
fetch(`/account/${id}`, (response) => {
dispatch(doneFetchingAccount()); // Hide loading spinner
if (response.status === 200) {
dispatch(setAccount(response.json)); // Use a normal function to set the received state
} else {
dispatch(someError);
}
});
};
}
function setAccount(data) {
return { type: "SET_Account", data: data };
}
Keep your data in the Redux store, and the UI related state internally in the component.
The best way to access your store in a component is to use the connect()
function, that creates a new component that wraps around your existing one. This pattern is called Higher-Order Components, and is generally the preferred way of extending a component's functionality in React. This allows you to map state and action creators to your component, and have them passed in automatically as your store updates.
Let's take an example of <FilterLink>
component using connect:
import { connect } from "react-redux";
import { setVisibilityFilter } from "../actions";
import Link from "../components/Link";
const mapStateToProps = (state, ownProps) => ({
active: ownProps.filter === state.visibilityFilter,
});
const mapDispatchToProps = (dispatch, ownProps) => ({
onClick: () => dispatch(setVisibilityFilter(ownProps.filter)),
});
const FilterLink = connect(mapStateToProps, mapDispatchToProps)(Link);
export default FilterLink;
Due to it having quite a few performance optimizations and generally being less likely to cause bugs, the Redux developers almost always recommend using connect()
over accessing the store directly (using context API).
function MyComponent {
someMethod() {
doSomethingWith(this.context.store);
}
}
Component is a class or function component that describes the presentational part of your application.
Container is an informal term for a component that is connected to a Redux store. Containers subscribe to Redux state updates and dispatch actions, and they usually don't render DOM elements; they delegate rendering to presentational child components.
Constants allows you to easily find all usages of that specific functionality across the project when you use an IDE. It also prevents you from introducing silly bugs caused by typos – in which case, you will get a ReferenceError
immediately.
Normally we will save them in a single file (constants.js
or actionTypes.js
).
export const ADD_TODO = "ADD_TODO";
export const DELETE_TODO = "DELETE_TODO";
export const EDIT_TODO = "EDIT_TODO";
export const COMPLETE_TODO = "COMPLETE_TODO";
export const COMPLETE_ALL = "COMPLETE_ALL";
export const CLEAR_COMPLETED = "CLEAR_COMPLETED";
In Redux, you use them in two places:
During action creation:
Let's take actions.js
:
import { ADD_TODO } from "./actionTypes";
export function addTodo(text) {
return { type: ADD_TODO, text };
}
In reducers:
Let's create reducer.js
:
import { ADD_TODO } from "./actionTypes";
export default (state = [], action) => {
switch (action.type) {
case ADD_TODO:
return [
...state,
{
text: action.text,
completed: false,
},
];
default:
return state;
}
};
mapDispatchToProps()
?There are a few ways of binding action creators to dispatch()
in mapDispatchToProps()
.
Below are the possible options:
const mapDispatchToProps = (dispatch) => ({
action: () => dispatch(action()),
});
const mapDispatchToProps = (dispatch) => ({
action: bindActionCreators(action, dispatch),
});
const mapDispatchToProps = { action };
The third option is just a shorthand for the first one.
ownProps
parameter in mapStateToProps()
and mapDispatchToProps()
?If the ownProps
parameter is specified, React Redux will pass the props that were passed to the component into your connect functions. So, if you use a connected component:
import ConnectedComponent from "./containers/ConnectedComponent";
<ConnectedComponent user={"john"} />;
The ownProps
inside your mapStateToProps()
and mapDispatchToProps()
functions will be an object:
{
user: "john";
}
You can use this object to decide what to return from those functions.
Most of the applications has several top-level directories as below:
Store: Used for store initialization.
This structure works well for small and medium size apps.
redux-saga
is a library that aims to make side effects (asynchronous things like data fetching and impure things like accessing the browser cache) in React/Redux applications easier and better.
It is available in NPM:
$ npm install --save redux-saga
Saga is like a separate thread in your application, that's solely responsible for side effects. redux-saga
is a redux middleware, which means this thread can be started, paused and cancelled from the main application with normal Redux actions, it has access to the full Redux application state and it can dispatch Redux actions as well.
call()
and put()
in redux-saga?Both call()
and put()
are effect creator functions. call()
function is used to create effect description, which instructs middleware to call the promise. put()
function creates an effect, which instructs middleware to dispatch an action to the store.
Let's take example of how these effects work for fetching particular user data.
function* fetchUserSaga(action) {
// `call` function accepts rest arguments, which will be passed to `api.fetchUser` function.
// Instructing middleware to call promise, it resolved value will be assigned to `userData` variable
const userData = yield call(api.fetchUser, action.userId);
// Instructing middleware to dispatch corresponding action.
yield put({
type: "FETCH_USER_SUCCESS",
userData,
});
}
Redux Thunk middleware allows you to write action creators that return a function instead of an action. The thunk can be used to delay the dispatch of an action, or to dispatch only if a certain condition is met. The inner function receives the store methods dispatch()
and getState()
as parameters.
redux-saga
and redux-thunk
?Both Redux Thunk and Redux Saga take care of dealing with side effects. In most of the scenarios, Thunk uses Promises to deal with them, whereas Saga uses Generators. Thunk is simple to use and Promises are familiar to many developers, Sagas/Generators are more powerful but you will need to learn them. But both middleware can coexist, so you can start with Thunks and introduce Sagas when/if you need them.
Redux DevTools is a live-editing time travel environment for Redux with hot reloading, action replay, and customizable UI. If you don't want to bother with installing Redux DevTools and integrating it into your project, consider using Redux DevTools Extension for Chrome and Firefox.
Some of the main features of Redux DevTools are below,
persistState()
store enhancer, you can persist debug sessions across page reloads.Selectors are functions that take Redux state as an argument and return some data to pass to the component.
For example, to get user details from the state:
const getUserData = (state) => state.user.data;
These selectors have two main benefits,
Redux Form works with React and Redux to enable a form in React to use Redux to store all of its state. Redux Form can be used with raw HTML5 inputs, but it also works very well with common UI frameworks like Material UI, React Widgets and React Bootstrap.
Some of the main features of Redux Form are:
You can use applyMiddleware()
.
For example, you can add redux-thunk
and logger
passing them as arguments to applyMiddleware()
:
import { createStore, applyMiddleware } from "redux";
const createStoreWithMiddleware = applyMiddleware(
ReduxThunk,
logger
)(createStore);
You need to pass initial state as second argument to createStore:
const rootReducer = combineReducers({
todos: todos,
visibilityFilter: visibilityFilter,
});
const initialState = {
todos: [{ id: 123, name: "example", completed: false }],
};
const store = createStore(rootReducer, initialState);
Relay is similar to Redux in that they both use a single store. The main difference is that relay only manages state originated from the server, and all access to the state is used via GraphQL queries (for reading data) and mutations (for changing data). Relay caches the data for you and optimizes data fetching for you, by fetching only changed data and nothing more.
Actions are plain JavaScript objects or payloads of information that send data from your application to your store. They are the only source of information for the store. Actions must have a type property that indicates the type of action being performed.
For example, let's take an action which represents adding a new todo item:
{
type: ADD_TODO,
text: 'Add todo item'
}
React is a JavaScript library, supporting both front end web and being run on the server, for building user interfaces and web applications.
React Native is a mobile framework that compiles to native app components, allowing you to build native mobile applications (iOS, Android, and Windows) in JavaScript that allows you to use React to build your components, and implements React under the hood.
React Native can be tested only in mobile simulators like iOS and Android. You can run the app in your mobile using expo app (https://expo.io) Where it syncs using QR code, your mobile and computer should be in same wireless network.
You can use console.log
, console.warn
, etc. As of React Native v0.29 you can simply run the following to see logs in the console:
$ react-native log-ios
$ react-native log-android
Follow the below steps to debug React Native app:
Command + D
and a webpage should open up at http://localhost:8081/debugger-ui
.Command + Option + I
to open the Chrome Developer tools, or open it via View
-> Developer
-> Developer Tools
.Reselect is a selector library (for Redux) which uses memoization concept. It was originally written to compute derived data from Redux-like applications state, but it can't be tied to any architecture or library.
Reselect keeps a copy of the last inputs/outputs of the last call, and recomputes the result only if one of the inputs changes. If the same inputs are provided twice in a row, Reselect returns the cached output. It's memoization and cache are fully customizable.
Flow is a static type checker designed to find type errors in JavaScript. Flow types can express much more fine-grained distinctions than traditional type systems. For example, Flow helps you catch errors involving null
, unlike most type systems.
Flow is a static analysis tool (static checker) which uses a superset of the language, allowing you to add type annotations to all of your code and catch an entire class of bugs at compile time.
PropTypes is a basic type checker (runtime checker) which has been patched onto React. It can't check anything other than the types of the props being passed to a given component. If you want more flexible typechecking for your entire project Flow/TypeScript are appropriate choices.
The below steps followed to include Font Awesome in React:
Install font-awesome
:
$ npm install --save font-awesome
Import font-awesome
in your index.js
file:
import "font-awesome/css/font-awesome.min.css";
Add Font Awesome classes in className
:
function MyComponent {
return <div><i className={'fa fa-spinner'} /></div>
}
React Developer Tools let you inspect the component hierarchy, including component props and state. It exists both as a browser extension (for Chrome and Firefox), and as a standalone app (works with other environments including Safari, IE, and React Native).
The official extensions available for different browsers or environments.
If you opened a local HTML file in your browser (file://...
) then you must first open Chrome Extensions and check Allow access to file URLs
.
You need to follow below steps to use Polymer in React,
Create a Polymer element:
<link
rel="import"
href="https://github.com/sudheerj/reactjs-interview-questions/blob/master/./../bower_components/polymer/polymer.html"
/>;
Polymer({
is: "calendar-element",
ready: function () {
this.textContent = "I am a calendar";
},
});
Create the Polymer component HTML tag by importing it in a HTML document, e.g. import it in the index.html
of your React application:
<link
rel="import"
href="https://github.com/sudheerj/reactjs-interview-questions/blob/master/src/polymer-components/calendar-element.html"
/>
Use that element in the JSX file:
export default function MyComponent {
return <calendar-element />;
}
React has the following advantages over Vue.js:
Note: The above list of advantages are purely opinionated and it vary based on the professional experience. But they are helpful as base parameters.
Let's see the difference between React and Angular in a table format.
React | Angular |
---|---|
React is a library and has only the View layer | Angular is a framework and has complete MVC functionality |
React handles rendering on the server side | AngularJS renders only on the client side but Angular 2 and above renders on the server side |
React uses JSX that looks like HTML in JS which can be confusing | Angular follows the template approach for HTML, which makes code shorter and easy to understand |
React Native, which is a React type to build mobile applications are faster and more stable | Ionic, Angular's mobile native app is relatively less stable and slower |
In React, data flows only in one way and hence debugging is easy | In Angular, data flows both way i.e it has two-way data binding between children and parent and hence debugging is often difficult |
Note: The above list of differences are purely opinionated and it vary based on the professional experience. But they are helpful as base parameters.
When the page loads, React DevTools sets a global named __REACT_DEVTOOLS_GLOBAL_HOOK__
, then React communicates with that hook during initialization. If the website is not using React or if React fails to communicate with DevTools then it won't show up the tab.
styled-components
is a JavaScript library for styling React applications. It removes the mapping between styles and components, and lets you write actual CSS augmented with JavaScript.
Lets create <Title>
and <Wrapper>
components with specific styles for each.
import React from "react";
import styled from "styled-components";
// Create a <Title> component that renders an <h1> which is centered, red and sized at 1.5em
const Title = styled.h1`
font-size: 1.5em;
text-align: center;
color: palevioletred;
`;
// Create a <Wrapper> component that renders a <section> with some padding and a papayawhip background
const Wrapper = styled.section`
padding: 4em;
background: papayawhip;
`;
These two variables, Title
and Wrapper
, are now components that you can render just like any other react component.
<Wrapper>
<Title>{"Lets start first styled component!"}</Title>
</Wrapper>
Relay is a JavaScript framework for providing a data layer and client-server communication to web applications using the React view layer.
Let's see the main features of Reselect library,
Let's take calculations and different amounts of a shipment order with the simplified usage of Reselect:
import { createSelector } from "reselect";
const shopItemsSelector = (state) => state.shop.items;
const taxPercentSelector = (state) => state.shop.taxPercent;
const subtotalSelector = createSelector(shopItemsSelector, (items) =>
items.reduce((acc, item) => acc + item.value, 0)
);
const taxSelector = createSelector(
subtotalSelector,
taxPercentSelector,
(subtotal, taxPercent) => subtotal * (taxPercent / 100)
);
export const totalSelector = createSelector(
subtotalSelector,
taxSelector,
(subtotal, tax) => ({ total: subtotal + tax })
);
let exampleState = {
shop: {
taxPercent: 8,
items: [
{ name: "apple", value: 1.2 },
{ name: "orange", value: 0.95 },
],
},
};
console.log(subtotalSelector(exampleState)); // 2.15
console.log(taxSelector(exampleState)); // 0.172
console.log(totalSelector(exampleState)); // { total: 2.322 }
Redux can be used as a data store for any UI layer. The most common usage is with React and React Native, but there are bindings available for Angular, Angular 2, Vue, Mithril, and more. Redux simply provides a subscription mechanism which can be used by any other code.
Redux is originally written in ES6 and transpiled for production into ES5 with Webpack and Babel. You should be able to use it regardless of your JavaScript build process. Redux also offers a UMD build that can be used directly without any build process at all.
initialValues
get updated from state?You need to add enableReinitialize : true
setting.
const InitializeFromStateForm = reduxForm({
form: "initializeFromState",
enableReinitialize: true,
})(UserEdit);
If your initialValues
prop gets updated, your form will update too.
You can use oneOfType()
method of PropTypes
.
For example, the height property can be defined with either string
or number
type as below:
Component.propTypes = {
size: PropTypes.oneOfType([PropTypes.string, PropTypes.number]),
};
You can import SVG directly as component instead of loading it as a file. This feature is available with react-scripts@2.0.0
and higher.
import { ReactComponent as Logo } from "./logo.svg";
const App = () => (
<div>
{/* Logo is an actual react component */}
<Logo />
</div>
);
Note: Don't forget about the curly braces in the import.
The concept of render hijacking is the ability to control what a component will output from another component. It means that you decorate your component by wrapping it into a Higher-Order component. By wrapping, you can inject additional props or make other changes, which can cause changing logic of rendering. It does not actually enable hijacking, but by using HOC you make your component behave differently.
We can pass numbers
as props
to React component using curly braces {}
where as strings
in double quotes ""
or single quotes ''
import React from "react";
const ChildComponent = ({ name, age }) => {
return (
<>
My Name is {name} and Age is {age}
</>
);
};
const ParentComponent = () => {
return (
<>
<ChildComponent name="Chetan" age={30} />
</>
);
};
export default ParentComponent;
It is up to the developer's decision, i.e., it is developer's job to determine what kinds of state make up your application, and where each piece of state should live. Some users prefer to keep every single piece of data in Redux, to maintain a fully serializable and controlled version of their application at all times. Others prefer to keep non-critical or UI state, such as “is this dropdown currently open”, inside a component's internal state.
Below are the rules of thumb to determine what kind of data should be put into Redux
React creates a service worker for you without any configuration by default. The service worker is a web API that helps you cache your assets and other files so that when the user is offline or on a slow network, he/she can still see results on the screen, as such, it helps you build a better user experience, that's what you should know about service worker for now. It's all about adding offline capabilities to your site.
import React from "react";
import ReactDOM from "react-dom";
import App from "./App";
import registerServiceWorker from "./registerServiceWorker";
ReactDOM.render(<App />, document.getElementById("root"));
registerServiceWorker();
Class components can be restricted from re-rendering when their input props are the same using PureComponent or shouldComponentUpdate. Now you can do the same with function components by wrapping them in React.memo.
const MyComponent = React.memo(function MyComponent(props) {
/* only rerenders if props change */
});
The React.lazy
function lets you render a dynamic import as a regular component. It will automatically load the bundle containing the OtherComponent
when the component gets rendered. This must return a Promise which resolves to a module with a default export containing a React component.
const OtherComponent = React.lazy(() => import("./OtherComponent"));
function MyComponent() {
return (
<div>
<OtherComponent />
</div>
);
}
Note:
React.lazy
and Suspense
is not yet available for server-side rendering. If you want to do code-splitting in a server rendered app, we still recommend React Loadable.
You can compare the current value of the state with an existing state value and decide whether to rerender the page or not. If the values are the same then you need to return null to stop re-rendering otherwise return the latest state value.
For example, the user profile information is conditionally rendered as follows,
getUserProfile = (user) => {
const latestAddress = user.address;
this.setState((state) => {
if (state.address === latestAddress) {
return null;
} else {
return { title: latestAddress };
}
});
};
Arrays: Unlike older releases, you don't need to make sure render method return a single element in React16. You are able to return multiple sibling elements without a wrapping element by returning an array.
For example, let us take the below list of developers,
const ReactJSDevs = () => {
return [
<li key="1">John</li>,
<li key="2">Jackie</li>,
<li key="3">Jordan</li>,
];
};
You can also merge this array of items in another array component.
const JSDevs = () => {
return (
<ul>
<li>Brad</li>
<li>Brodge</li>
<ReactJSDevs />
<li>Brandon</li>
</ul>
);
};
Strings and Numbers: You can also return string and number type from the render method.
render() {
return 'Welcome to ReactJS questions';
}
// Number
render() {
return 2018;
}
Hooks is a special JavaScript function that allows you use state and other React features without writing a class. This pattern has been introduced as a new feature in React 16.8 and helped to isolate the stateful logic from the components.
Let's see an example of useState hook:
import { useState } from "react";
function Example() {
// Declare a new state variable, which we'll call "count"
const [count, setCount] = useState(0);
return (
<>
<p>You clicked {count} times</p>
<button onClick={() => setCount(count + 1)}>Click me</button>
</>
);
}
Note: Hooks can be used inside an existing function component without rewriting the component.
You need to follow two rules in order to use hooks,
React team released an ESLint plugin called eslint-plugin-react-hooks that enforces Hook's two rules. It is part of Hooks API. You can add this plugin to your project using the below command,
npm install eslint-plugin-react-hooks --save-dev
And apply the below config in your ESLint config file,
// Your ESLint configuration
{
"plugins": [
// ...
"react-hooks"
],
"rules": {
// ...
"react-hooks/rules-of-hooks": "error"
}
}
The recommended eslint-config-react-app
preset already includes the hooks rules of this plugin.
For example, the linter enforce proper naming convention for hooks. If you rename your custom hooks which as prefix "use" to something else then linter won't allow you to call built-in hooks such as useState, useEffect etc inside of your custom hook anymore.
Note: This plugin is intended to use in Create React App by default.
Below are the major differences between Flux and Redux
Flux | Redux |
---|---|
State is mutable | State is immutable |
The Store contains both state and change logic | The Store and change logic are separate |
There are multiple stores exist | There is only one store exist |
All the stores are disconnected and flat | Single store with hierarchical reducers |
It has a singleton dispatcher | There is no concept of dispatcher |
React components subscribe to the store | Container components uses connect function |
Below are the main benefits of React Router V4 module,
<BrowserRouter>
) which wraps specific child router components(<Route>
).<BrowserRouter>
component.The componentDidCatch lifecycle method is invoked after an error has been thrown by a descendant component. The method receives two parameters,
info: - An object with a componentStack key contains the information about which component threw the error.
The method structure would be as follows
componentDidCatch(error, info);
Below are the cases in which error boundaries don't work,
In React 16, errors that were not caught by any error boundary will result in unmounting of the whole React component tree. The reason behind this decision is that it is worse to leave corrupted UI in place than to completely remove it. For example, it is worse for a payments app to display a wrong amount than to render nothing.
The granularity of error boundaries usage is up to the developer based on project needs. You can follow either of these approaches,
Apart from error messages and javascript stack, React16 will display the component stack trace with file names and line numbers using error boundary concept.
For example, BuggyCounter component displays the component stack trace as below,
The defaultProps can be defined as a property on the component to set the default values for the props. These default props are used when props not supplied(i.e., undefined props), but not for null
or 0
as props. That means, If you provide null value then it remains null value. It's the same behavior with 0 as well.
For example, let us create color default prop for the button component,
function MyButton {
// ...
}
MyButton.defaultProps = {
color: "red",
};
If props.color
is not provided then it will set the default value to 'red'. i.e, Whenever you try to access the color prop it uses the default value
function MyButton() {
return <MyButton />; // props.color will contain red value
}
The displayName string is used in debugging messages. Usually, you don’t need to set it explicitly because it’s inferred from the name of the function or class that defines the component. You might want to set it explicitly if you want to display a different name for debugging purposes or when you create a higher-order component.
For example, To ease debugging, choose a display name that communicates that it’s the result of a withSubscription HOC.
function withSubscription(WrappedComponent) {
class WithSubscription extends React.Component {
/* ... */
}
WithSubscription.displayName = `WithSubscription(${getDisplayName(
WrappedComponent
)})`;
return WithSubscription;
}
function getDisplayName(WrappedComponent) {
return (
WrappedComponent.displayName || WrappedComponent.name || "Component"
);
}
React supports all popular browsers, including Internet Explorer 9 and above, although some polyfills are required for older browsers such as IE 9 and IE 10. If you use es5-shim and es5-sham polyfill then it even support old browsers that doesn't support ES5 methods.
Code-Splitting is a feature supported by bundlers like Webpack and Browserify which can create multiple bundles that can be dynamically loaded at runtime. The react project supports code splitting via dynamic import() feature.
For example, in the below code snippets, it will make moduleA.js and all its unique dependencies as a separate chunk that only loads after the user clicks the 'Load' button.
moduleA.js
const moduleA = "Hello";
export { moduleA };
App.js
export default function App {
function handleClick() {
import("./moduleA")
.then(({ moduleA }) => {
// Use moduleA
})
.catch((err) => {
// Handle failure
});
};
return (
<div>
<button onClick={this.handleClick}>Load</button>
</div>
);
}
```javascript import React, { Component } from "react"; class App extends Component { handleClick = () => { import("./moduleA") .then(({ moduleA }) => { // Use moduleA }) .catch((err) => { // Handle failure }); }; render() { return (
The Fragments declared with the explicit
function Glossary(props) {
return (
<dl>
{props.items.map((item) => (
// Without the `key`, React will fire a key warning
<React.Fragment key={item.id}>
<dt>{item.term}</dt>
<dd>{item.description}</dd>
</React.Fragment>
))}
</dl>
);
}
Note: key is the only attribute that can be passed to Fragment. In the future, there might be a support for additional attributes, such as event handlers.
As of React 16, both standard or custom DOM attributes are fully supported. Since React components often take both custom and DOM-related props, React uses the camelCase convention just like the DOM APIs.
Let us take few props with respect to standard HTML attributes,
<div tabIndex="-1" /> // Just like node.tabIndex DOM API
<div className="Button" /> // Just like node.className DOM API
<input readOnly={true} /> // Just like node.readOnly DOM API
These props work similarly to the corresponding HTML attributes, with the exception of the special cases. It also support all SVG attributes.
If you pass no value for a prop, it defaults to true. This behavior is available so that it matches the behavior of HTML.
For example, below expressions are equivalent,
<MyInput autocomplete />
<MyInput autocomplete={true} />
Note: It is not recommended to use this approach because it can be confused with the ES6 object shorthand (example, {name}
which is short for {name: name}
)
Next.js is a popular and lightweight framework for static and server‑rendered applications built with React. It also provides styling and routing solutions. Below are the major features provided by NextJS,
You can pass event handlers and other functions as props to child components. The functions can be passed to child component as below,
function Button({ onClick }) {
return <button onClick={onClick}>Download</button>;
}
export default function downloadExcel() {
function handleClick() {
alert("Downloaded");
}
return <Button onClick={handleClick}></Button>;
}
If you use an event handler such as onClick or onScroll and want to prevent the callback from being fired too quickly, then you can limit the rate at which callback is executed. This can be achieved in the below possible ways,
React DOM escapes any values embedded in JSX before rendering them. Thus it ensures that you can never inject anything that’s not explicitly written in your application. Everything is converted to a string before being rendered.
For example, you can embed user input as below,
const name = response.potentiallyMaliciousInput;
const element = <h1>{name}</h1>;
This way you can prevent XSS(Cross-site-scripting) attacks in the application.
You can update UI(represented by rendered element) by passing the newly created element to ReactDOM's render method.
For example, lets take a ticking clock example, where it updates the time by calling render method multiple times,
function tick() {
const element = (
<div>
<h1>Hello, world!</h1>
<h2>It is {new Date().toLocaleTimeString()}.</h2>
</div>
);
ReactDOM.render(element, document.getElementById("root"));
}
setInterval(tick, 1000);
When you declare a component as a function or a class, it must never modify its own props.
Let us take a below capital function,
function capital(amount, interest) {
return amount + interest;
}
The above function is called “pure” because it does not attempt to change their inputs, and always return the same result for the same inputs. Hence, React has a single rule saying "All React components must act like pure functions with respect to their props."
There are three conditions to make sure, it is safe use the index as a key.
The keys used within arrays should be unique among their siblings but they don’t need to be globally unique. i.e, You can use the same keys with two different arrays.
For example, the below Book
component uses two arrays with different arrays,
function Book(props) {
const index = (
<ul>
{props.pages.map((page) => (
<li key={page.id}>{page.title}</li>
))}
</ul>
);
const content = props.pages.map((page) => (
<div key={page.id}>
<h3>{page.title}</h3>
<p>{page.content}</p>
<p>{page.pageNumber}</p>
</div>
));
return (
<div>
{index}
<hr />
{content}
</div>
);
}
Formik
is a form library for react which provides solutions such as validation, keeping track of the visited fields, and handling form submission.
In detail, You can categorize them as follows,
Handling form submission
It is used to create a scalable, performant, form helper with a minimal API to solve annoying stuff.
Below are the main reasons to recommend formik over redux form library,
In React, it is recommended to use composition over inheritance to reuse code between components. Both Props and composition give you all the flexibility you need to customize a component’s look and behavior explicitly and safely. Whereas, If you want to reuse non-UI functionality between components, it is suggested to extract it into a separate JavaScript module. Later components import it and use that function, object, or class, without extending it.
Yes, you can use web components in a react application. Even though many developers won't use this combination, it may require especially if you are using third-party UI components that are written using Web Components.
For example, let us use Vaadin
date picker web component as below,
import "./App.css";
import "@vaadin/vaadin-date-picker";
export default function App() {
return (
<div className="App">
<vaadin-date-picker label="When were you born?"></vaadin-date-picker>
</div>
);
}
You can achieve code-splitting in your app using dynamic import.
Let's take an example of addition,
Normal Import
import { add } from "./math";
console.log(add(10, 20));
Dynamic Import
import("./math").then((math) => {
console.log(math.add(10, 20));
});
With the release of React 18, React.lazy and Suspense are now available for server-side rendering. However, prior to React 18, it was recommended to use Loadable Components for code-splitting in a server-side rendered app because React.lazy and Suspense were not available for server-side rendering. Loadable Components lets you render a dynamic import as a regular component. For example, you can use Loadable Components to load the OtherComponent in a separate bundle like this:
import loadable from "@loadable/component";
const OtherComponent = loadable(() => import("./OtherComponent"));
function MyComponent() {
return (
<div>
<OtherComponent />
</div>
);
}
Now OtherComponent will be loaded in a separated bundle Loadable Components provides additional benefits beyond just code-splitting, such as automatic code reloading, error handling, and preloading. By using Loadable Components, you can ensure that your application loads quickly and efficiently, providing a better user experience for your users.
If the module containing the dynamic import is not yet loaded by the time parent component renders, you must show some fallback content while you’re waiting for it to load using a loading indicator. This can be done using Suspense component.
For example, the below code uses suspense component,
const OtherComponent = React.lazy(() => import("./OtherComponent"));
function MyComponent() {
return (
<div>
<Suspense fallback={<div>Loading...</div>}>
<OtherComponent />
</Suspense>
</div>
);
}
As mentioned in the above code, Suspense is wrapped above the lazy component.
One of the best place to do code splitting is with routes. The entire page is going to re-render at once so users are unlikely to interact with other elements in the page at the same time. Due to this, the user experience won't be disturbed.
Let us take an example of route based website using libraries like React Router with React.lazy,
import { BrowserRouter as Router, Route, Switch } from "react-router-dom";
import React, { Suspense, lazy } from "react";
const Home = lazy(() => import("./routes/Home"));
const About = lazy(() => import("./routes/About"));
const App = () => (
<Router>
<Suspense fallback={<div>Loading...</div>}>
<Switch>
<Route exact path="/" component={Home} />
<Route path="/about" component={About} />
</Switch>
</Suspense>
</Router>
);
In the above code, the code splitting will happen at each route level.
The defaultValue argument is only used when a component does not have a matching Provider above it in the tree. This can be helpful for testing components in isolation without wrapping them.
Below code snippet provides default theme value as Luna.
const MyContext = React.createContext(defaultValue);
React needs to use algorithms to find out how to efficiently update the UI to match the most recent tree. The diffing algorithms is generating the minimum number of operations to transform one tree into another. However, the algorithms have a complexity in the order of O(n³) where n is the number of elements in the tree.
In this case, displaying 1000 elements would require in the order of one billion comparisons. This is far too expensive. Instead, React implements a heuristic O(n) algorithm based on two assumptions:
When diffing two trees, React first compares the two root elements. The behavior is different depending on the types of the root elements. It covers the below rules during reconciliation algorithm,
Elements Of Different Types:
Whenever the root elements have different types, React will tear down the old tree and build the new tree from scratch. For example, elements to , or from
DOM Elements Of The Same Type: When comparing two React DOM elements of the same type, React looks at the attributes of both, keeps the same underlying DOM node, and only updates the changed attributes. Lets take an example with same DOM elements except className attribute,
<div className="show" title="ReactJS" />
<div className="hide" title="ReactJS" />
Component Elements Of The Same Type: When a component updates, the instance stays the same, so that state is maintained across renders. React updates the props of the underlying component instance to match the new element, and calls componentWillReceiveProps() and componentWillUpdate() on the underlying instance. After that, the render() method is called and the diff algorithm recurses on the previous result and the new result.
Recursing On Children: when recursing on the children of a DOM node, React just iterates over both lists of children at the same time and generates a mutation whenever there’s a difference. For example, when adding an element at the end of the children, converting between these two trees works well.
<ul>
<li>first</li>
<li>second</li>
</ul>
<ul>
<li>first</li>
<li>second</li>
<li>third</li>
</ul>
Handling keys: React supports a key attribute. When children have keys, React uses the key to match children in the original tree with children in the subsequent tree. For example, adding a key can make the tree conversion efficient,
<ul>
<li key="2015">Duke</li>
<li key="2016">Villanova</li>
</ul>
<ul>
<li key="2014">Connecticut</li>
<li key="2015">Duke</li>
<li key="2016">Villanova</li>
</ul>
There are few use cases to go for refs,
Even though the pattern named render props, you don’t have to use a prop named render to use this pattern. i.e, Any prop that is a function that a component uses to know what to render is technically a “render prop”. Lets take an example with the children prop for render props,
<Mouse
children={(mouse) => (
<p>
The mouse position is {mouse.x}, {mouse.y}
</p>
)}
/>
Actually children prop doesn’t need to be named in the list of “attributes” in JSX element. Instead, you can keep it directly inside element,
<Mouse>
{(mouse) => (
<p>
The mouse position is {mouse.x}, {mouse.y}
</p>
)}
</Mouse>
While using this above technique(without any name), explicitly state that children should be a function in your propTypes.
Mouse.propTypes = {
children: PropTypes.func.isRequired,
};
If you create a function inside a render method, it negates the purpose of pure component. Because the shallow prop comparison will always return false for new props, and each render in this case will generate a new value for the render prop. You can solve this issue by defining the render function as instance method.
Windowing is a technique that only renders a small subset of your rows at any given time, and can dramatically reduce the time it takes to re-render the components as well as the number of DOM nodes created. If your application renders long lists of data then this technique is recommended. Both react-window and react-virtualized are popular windowing libraries which provides several reusable components for displaying lists, grids, and tabular data.
The falsy values such as false, null, undefined, and true are valid children but they don't render anything. If you still want to display them then you need to convert it to string. Let's take an example on how to convert to a string,
<div>My JavaScript variable is {String(myVariable)}.</div>
React portals are very useful when a parent component has overflow: hidden or has properties that affect the stacking context (e.g. z-index, position, opacity) and you need to visually “break out” of its container.
For example, dialogs, global message notifications, hovercards, and tooltips.
In React, the value attribute on form elements will override the value in the DOM. With an uncontrolled component, you might 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.
render() {
return (
<form onSubmit={this.handleSubmit}>
<label>
User Name:
<input
defaultValue="John"
type="text"
ref={this.input} />
</label>
<input type="submit" value="Submit" />
</form>
);
}
The same applies for select
and textArea
inputs. But you need to use defaultChecked for checkbox
and radio
inputs.
Even though the tech stack varies from developer to developer, the most popular stack is used in react boilerplate project code. It mainly uses Redux and redux-saga for state management and asynchronous side-effects, react-router for routing purpose, styled-components for styling react components, axios for invoking REST api, and other supported stack such as webpack, reselect, ESNext, Babel. You can clone the project https://github.com/react-boilerplate/react-boilerplate and start working on any new react project.
Below are the main differences between Real DOM and Virtual DOM,
Real DOM | Virtual DOM |
---|---|
Updates are slow | Updates are fast |
DOM manipulation is very expensive. | DOM manipulation is very easy |
You can update HTML directly. | You Can’t directly update HTML |
It causes too much of memory wastage | There is no memory wastage |
Creates a new DOM if element updates | It updates the JSX if element update |
Bootstrap can be added to your React app in a three possible ways,
npm install bootstrap
Below are the top 10 websites
using React as their front-end framework,
React does not have any opinion about how styles are defined but if you are a beginner then good starting point is to define your styles in a separate *.css file as usual and refer to them using className. This functionality is not part of React but came from third-party libraries. But If you want to try a different approach(CSS-In-JS) then styled-components library is a good option.
No. But you can try Hooks in a few components(or new components) without rewriting any existing code. Because there are no plans to remove classes in ReactJS.
The effect hook called useEffect
can be used to fetch data from an API and to set the data in the local state of the component with the useState hook’s update function.
Here is an example of fetching a list of react articles from an API using fetch.
import React from "react";
function App() {
const [data, setData] = React.useState({ hits: [] });
React.useEffect(() => {
fetch("http://hn.algolia.com/api/v1/search?query=react")
.then((response) => response.json())
.then((data) => setData(data));
}, []);
return (
<ul>
{data.hits.map((item) => (
<li key={item.objectID}>
<a href={item.url}>{item.title}</a>
</li>
))}
</ul>
);
}
export default App;
A popular way to simplify this is by using the library axios.
We provided an empty array as second argument to the useEffect hook to avoid activating it on component updates. This way, it only fetches on component mount.
Hooks doesn't cover all use cases of classes but there is a plan to add them soon. Currently there are no Hook equivalents to the uncommon getSnapshotBeforeUpdate and componentDidCatch lifecycles yet.
React includes a stable implementation of React Hooks in 16.8 release for below packages
useState
?When we declare a state variable with useState
, it returns a pair — an array with two items. The first item is the current value, and the second is a function that updates the value. Using [0] and [1] to access them is a bit confusing because they have a specific meaning. This is why we use array destructuring instead.
For example, the array index access would look as follows:
var userStateVariable = useState("userProfile"); // Returns an array pair
var user = userStateVariable[0]; // Access first item
var setUser = userStateVariable[1]; // Access second item
Whereas with array destructuring the variables can be accessed as follows:
const [user, setUser] = useState("userProfile");
Hooks got the ideas from several different sources. Below are some of them,
Web Components often expose an imperative API to implement its functions. You will need to use a ref to interact with the DOM node directly if you want to access imperative API of a web component. But 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.
Formik is a small react form library that helps you with the three major problems,
Some of the popular middleware choices for handling asynchronous calls in Redux eco system are Redux Thunk, Redux Promise, Redux Saga
.
No, browsers can't understand JSX code. You need a transpiler to convert your JSX to regular Javascript that browsers can understand. The most widely used transpiler right now is Babel.
React implements one-way reactive data flow using props which reduce boilerplate and is easier to understand than traditional two-way data binding.
MobX is a simple, scalable and battle tested state management solution for applying functional reactive programming (TFRP). For ReactJS application, you need to install below packages,
npm install mobx --save
npm install mobx-react --save
Below are the main differences between Redux and MobX,
Topic | Redux | MobX |
---|---|---|
Definition | It is a javascript library for managing the application state | It is a library for reactively managing the state of your applications |
Programming | It is mainly written in ES6 | It is written in JavaScript(ES5) |
Data Store | There is only one large store exist for data storage | There is more than one store for storage |
Usage | Mainly used for large and complex applications | Used for simple applications |
Performance | Need to be improved | Provides better performance |
How it stores | Uses JS Object to store | Uses observable to store the data |
No, you don’t have to learn es2015/es6 to learn react. But you may find many resources or React ecosystem uses ES6 extensively. Let's see some of the frequently used ES6 features,
Destructuring: To get props and use them in a component
// in es 5
var someData = this.props.someData;
var dispatch = this.props.dispatch;
// in es6
const { someData, dispatch } = this.props;
Spread operator: Helps in passing props down into a component
// in es 5
<SomeComponent someData={this.props.someData} dispatch={this.props.dispatch} />
// in es6
<SomeComponent {...this.props} />
Arrow functions: Makes compact syntax
// es 5
var users = usersList.map(function (user) {
return <li>{user.name}</li>;
});
// es 6
const users = usersList.map((user) => <li>{user.name}</li>);
The Concurrent rendering makes React apps to be more responsive by rendering component trees without blocking the main UI thread. It allows React to interrupt a long-running render to handle a high-priority event. i.e, When you enabled concurrent Mode, React will keep an eye on other tasks that need to be done, and if there's something with a higher priority it will pause what it is currently rendering and let the other task finish first. You can enable this in two ways,
// 1. Part of an app by wrapping with ConcurrentMode
<React.unstable_ConcurrentMode>
<Something />
</React.unstable_ConcurrentMode>;
// 2. Whole app using createRoot
ReactDOM.unstable_createRoot(domNode).render(<App />);
Both refers the same thing. Previously concurrent Mode being referred to as "Async Mode" by React team. The name has been changed to highlight React’s ability to perform work on different priority levels. So it avoids the confusion from other approaches to Async Rendering.
Yes, you can use javascript: URLs but it will log a warning in the console. Because URLs starting with javascript: are dangerous by including unsanitized output in a tag like <a href>
and create a security hole.
const companyProfile = {
website: "javascript: alert('Your website is hacked')",
};
// It will log a warning
<a href={companyProfile.website}>More details</a>;
Remember that the future versions will throw an error for javascript URLs.
The ESLint plugin enforces rules of Hooks to avoid bugs. It assumes that any function starting with ”use” and a capital letter right after it is a Hook. In particular, the rule enforces that,
Imagine a simple UI component, such as a "Like" button. When you tap it, it turns blue if it was previously grey, and grey if it was previously blue.
The imperative way of doing this would be:
if (user.likes()) {
if (hasBlue()) {
removeBlue();
addGrey();
} else {
removeGrey();
addBlue();
}
}
Basically, you have to check what is currently on the screen and handle all the changes necessary to redraw it with the current state, including undoing the changes from the previous state. You can imagine how complex this could be in a real-world scenario.
In contrast, the declarative approach would be:
if (this.state.liked) {
return <blueLike />;
} else {
return <greyLike />;
}
Because the declarative approach separates concerns, this part of it only needs to handle how the UI should look in a specific state, and is therefore much simpler to understand.
Below are some of the benefits of using TypeScript with ReactJS,
Avoid bugs with the ease of readability and Validation
When a user logs in and reload, to persist the state generally we add the load user action in the useEffect hooks in the main App.js. While using Redux, loadUser action can be easily accessed.
App.js
import { loadUser } from "../actions/auth";
store.dispatch(loadUser());
But while using Context API, to access context in App.js, wrap the AuthState in index.js so that App.js can access the auth context. Now whenever the page reloads, no matter what route you are on, the user will be authenticated as loadUser action will be triggered on each re-render.
index.js
import React from "react";
import ReactDOM from "react-dom";
import App from "./App";
import AuthState from "./context/auth/AuthState";
ReactDOM.render(
<React.StrictMode>
<AuthState>
<App />
</AuthState>
</React.StrictMode>,
document.getElementById("root")
);
App.js
const authContext = useContext(AuthContext);
const { loadUser } = authContext;
useEffect(() => {
loadUser();
}, []);
loadUser
const loadUser = async () => {
const token = sessionStorage.getItem("token");
if (!token) {
dispatch({
type: ERROR,
});
}
setAuthToken(token);
try {
const res = await axios("/api/auth");
dispatch({
type: USER_LOADED,
payload: res.data.data,
});
} catch (err) {
console.error(err);
}
};
There are three major benefits of new JSX transform,
The new JSX transform doesn’t require React to be in scope. i.e, You don't need to import React package for simple scenarios.
Let's take an example to look at the main differences between the old and the new transform,
Old Transform:
import React from "react";
function App() {
return <h1>Good morning!!</h1>;
}
Now JSX transform convert the above code into regular JavaScript as below,
import React from "react";
function App() {
return React.createElement("h1", null, "Good morning!!");
}
New Transform:
The new JSX transform doesn't require any React imports
function App() {
return <h1>Good morning!!</h1>;
}
Under the hood JSX transform compiles to below code
import { jsx as _jsx } from "react/jsx-runtime";
function App() {
return _jsx("h1", { children: "Good morning!!" });
}
Note: You still need to import React to use Hooks.
React Server Component is a way to write React component that gets rendered in the server-side with the purpose of improving React app performance. These components allow us to load components from the backend.
Note: React Server Components is still under development and not recommended for production yet.
Prop Drilling is the process by which you pass data from one component of the React Component tree to another by going through other components that do not need the data but only help in passing it around.
A wrapper in React is a component that wraps or surrounds another component or group of components. It can be used for a variety of purposes such as adding additional functionality, styling, or layout to the wrapped components.
For example, consider a simple component that displays a message:
const Message = ({ text }) => {
return <p>{text}</p>;
};
We can create a wrapper component that will add a border to the message component:
const MessageWrapper = (props) => {
return (
<div style={{ border: "1px solid black" }}>
<Message {...props} />
</div>
);
};
Now we can use the MessageWrapper component instead of the Message component and the message will be displayed with a border:
<MessageWrapper text="Hello World" />
Wrapper component can also accept its own props and pass them down to the wrapped component, for example, we can create a wrapper component that will add a title to the message component:
const MessageWrapperWithTitle = ({ title, ...props }) => {
return (
<div>
<h3>{title}</h3>
<Message {...props} />
</div>
);
};
Now we can use the MessageWrapperWithTitle component and pass title props:
<MessageWrapperWithTitle title="My Message" text="Hello World" />
This way, the wrapper component can add additional functionality, styling, or layout to the wrapped component while keeping the wrapped component simple and reusable.
useEffect and useLayoutEffect are both React hooks that can be used to synchronize a component with an external system, such as a browser API or a third-party library. However, there are some key differences between the two:
Timing: useEffect runs after the browser has finished painting, while useLayoutEffect runs synchronously before the browser paints. This means that useLayoutEffect can be used to measure and update layout in a way that feels more synchronous to the user.
Browser Paint: useEffect allows browser to paint the changes before running the effect, hence it may cause some visual flicker. useLayoutEffect synchronously runs the effect before browser paints and hence it will avoid visual flicker.
Execution Order: The order in which multiple useEffect hooks are executed is determined by React and may not be predictable. However, the order in which multiple useLayoutEffect hooks are executed is determined by the order in which they were called.
Error handling: useEffect has a built-in mechanism for handling errors that occur during the execution of the effect, so that it does not crash the entire application. useLayoutEffect does not have this mechanism, and errors that occur during the execution of the effect will crash the entire application.
In general, it's recommended to use useEffect as much as possible, because it is more performant and less prone to errors. useLayoutEffect should only be used when you need to measure or update layout, and you can't achieve the same result using useEffect.
There are two different ways to create components in ReactJS. The main differences are listed down as below,
The class components uses ES6 classes to create the components. It uses render
function to display the HTML content in the webpage.
The syntax for class component looks like as below.
class App extends React.Component {
render() {
return <h1>This is a class component</h1>;
}
}
Note: The Pascal Case is the recommended approach to provide naming to a component.
Functional component has been improved over the years with some added features like Hooks. Here is a syntax for functional component.
function App() {
return (
<div className="App">
<h1>Hello, I'm a function component</h1>
</div>
);
}
State contains information or data about a component which may change over time.
In class component, you can update the state when a user interacts with it or server updates the data using the setState()
method. The initial state is going to be assigned in the Constructor()
method using the this.state
object and it is possible to assign different data types such as string, boolean, numbers, etc.
A simple example showing how we use the setState() and constructor():
class App extends Component {
constructor() {
super();
this.state = {
message: "This is a class component",
};
}
updateMessage() {
this.setState({
message: "Updating the class component",
});
}
render() {
return (
<>
<h1>{this.state.message}</h1>
<button
onClick={() => {
this.updateMessage();
}}>
Click!!
</button>
</>
);
}
}
You didn't use state in functional components because it was only supported in class components. But over the years hooks have been implemented in functional components which enables to use state too.
The useState()
hook can used to implement state in functional components. It returns an array with two items: the first item is current state and the next one is a function (setState) that updates the value of the current state.
Let's see an example to demonstrate the state in functional components,
function App() {
const [message, setMessage] = useState("This is a functional component");
const updateMessage = () => {
setMessage("Updating the functional component");
};
return (
<div className="App">
<h1>{message} </h1>
<button onClick={updateMessage}>Click me!!</button>
</div>
);
}
Props are referred to as "properties". The props are passed into React component just like arguments passed to a function. In other words, they are similar to HTML attributes.
The props are accessible in child class component using this.props
as shown in below example,
class Child extends React.Component {
render() {
return (
<h1>
{" "}
This is a functional component and component name is {
this.props.name
}{" "}
</h1>
);
}
}
class Parent extends React.Component {
render() {
return (
<div className="Parent">
<Child name="First child component" />
<Child name="Second child component" />
</div>
);
}
}
Props in functional components are similar to that of the class components but the difference is the absence of 'this' keyword.
function Child(props) {
return (
<h1>
This is a child component and the component name is{props.name}
</h1>
);
}
function Parent() {
return (
<div className="Parent">
<Child name="First child component" />
<Child name="Second child component" />
</div>
);
}
React.StrictMode
is a useful component for highlighting potential problems in an application. Just like <Fragment>
, <StrictMode>
does not render any extra DOM elements. It activates additional checks and warnings for its descendants. These checks apply for development mode only.
import { StrictMode } from "react";
function App() {
return (
<div>
<Header />
<StrictMode>
<div>
<ComponentOne />
<ComponentTwo />
</div>
</StrictMode>
<Header />
</div>
);
}
In the example above, the strict mode checks apply to <ComponentOne>
and <ComponentTwo>
components only. i.e., Part of the application only.
Note: Frameworks such as NextJS has this flag enabled by default.
The
StrictMode renders components twice in development mode(not production) in order to detect any problems with your code and warn you about those problems. This is used to detect accidental side effects in the render phase. If you used create-react-app
development tool then it automatically enables StrictMode by default.
const root = createRoot(document.getElementById("root"));
root.render(
<StrictMode>
<App />
</StrictMode>
);
If you want to disable this behavior then you can simply remove strict
mode.
const root = createRoot(document.getElementById("root"));
root.render(<App />);
To detect side effects the following functions are invoked twice:
useState
, useMemo
, or useReducer
(any other Hook)constructor
, render
, and shouldComponentUpdate
methodsgetDerivedStateFromProps
methodThe below 3 rules needs to be followed while using JSX in a react application.
Return a single root element: If you are returning multiple elements from a component, wrap them in a single parent element. Otherwise you will receive the below error in your browser console.
html Adjacent JSX elements must be wrapped in an enclosing tag.
All the tags needs to be closed: Unlike HTML, all tags needs to closed explicitly with in JSX. This rule applies for self-closing tags(like hr, br and img tags) as well.
Use camelCase naming:
It is suggested to use camelCase naming for attributes in JSX. For example, the common attributes of HTML elements such as class
, tabindex
will be used as className
and tabIndex
.
Note: There is an exception for aria-*
and data-*
attributes which should be lower cased all the time.
Behind the scenes, JSX is transformed into plain javascript objects. It is not possible to return two or more objects from a function without wrapping into an array. This is the reason you can't simply return two or more JSX tags from a function without wrapping them into a single parent tag or a Fragment.
The preexisting variables outside of the function scope including state, props and context leads to a mutation and they result in unpredictable bugs during the rendering stage. The below points should be taken care while working with arrays variables.
The onClickCapture
React event is helpful to catch all the events of child elements irrespective of event propagation logic or even if the events propagation stopped. This is useful if you need to log every click events for analytics purpose.
For example, the below code triggers the click event of parent first followed by second level child eventhough leaf child button elements stops the propagation.
<div onClickCapture={() => alert("parent")}>
<div onClickCapture={() => alert("child")}>
<button onClick={(e) => e.stopPropagation()} />
<button onClick={(e) => e.stopPropagation()} />
</div>
</div>
The event propagation for the above code snippet happens in the following order:
onClickCapture
event handlers.onClick
event handler on the target element.onClick
event handlers above to it.React updates UI in three steps,
Triggering or initiating a render: The component is going to triggered for render in two ways.
creatRoot
with the target DOM node followed by invoking component's render
method. For example, the following code snippet renders App
component on root DOM node.import { createRoot } from "react-dom/client";
const root = createRoot(document.getElementById("root"));
root.render(<App />);
Rendering components: After triggering a render, React will call your components to display them on the screen. React will call the root component for initial render and call the function component whose state update triggered the render. This is a recursive process for all nested components of the target component.
Commit changes to DOM: After calling components, React will modify the DOM for initial render using appendChild()
DOM API and apply minimal necessary DOM updates for re-renders based on differences between rerenders.
React prevents component from re-rendering for each and every state update by grouping multiple state updates within an event handler. This strategy improves the application performance and this process known as batching. The older version of React only supported batching for browser events whereas React18 supported for asynchronous actions, timeouts and intervals along with native events. This improved version of batching is called automatic batching.
Let's demonstrate this automatic batching feature with a below example.
import { useState } from "react";
export default function BatchingState() {
const [count, setCount] = useState(0);
const [message, setMessage] = useState("batching");
console.log("Application Rendered");
const handleUsers = () => {
fetch("https://jsonplaceholder.typicode.com/users/1").then(() => {
// Automatic Batching re-render only once
setCount(count + 1);
setMessage("users fetched");
});
};
return (
<>
<h1>{count}</h1>
<button onClick={handleAsyncFetch}>Click Me!</button>
</>
);
}
The preceding code updated two state variables with in an event handler. However, React will perform automatic batching feature and the component will be re-rendered only once for better performance.
Yes, it is possible to prevent automatic batching default behavior. There might be cases where you need to re-render your component after each state update or updating one state depends on another state variable. Considering this situation, React introduced flushSync
method from react-dom
API for the usecases where you need to flush state updates to DOM immediately.
The usage of flushSync
method within an onClick
event handler will be looking like as below,
import { flushSync } from "react-dom";
const handleClick = () => {
flushSync(() => {
setClicked(!clicked); //Component will create a re-render here
});
setCount(count + 1); // Component will create a re-render again here
};
In the above click handler, React will update DOM at first using flushSync and second time updates DOM because of the counter setter function by avoiding automatic batching.
React hydration is used to add client-side JavaScript interactivity to pre-rendered static HTML generated by the server. It is used only for server-side rendering(SSR) to enhance the initial rendering time and make it SEO friendly application. This hydration acts as a bridge to reduce the gap between server side and client-side rendering.
After the page loaded with generated static HTML, React will add application state and interactivity by attaching all event handlers for the respective elements. Let's demonstrate this with an example.
Consider that React DOM API(using renderToString
) generated HTML for <App>
component which contains <button>
element to increment the counter.
import {useState} from 'react';
import { renderToString } from 'react-dom/server';
export default function App() {
const [count, setCount] = React.useState(0);
return (
<h1>Counter</h1>
<button onClick={() => setCount(prevCount => prevCount + 1)}>
{count} times
</button>
);
}
const html = renderToString(<App />);
The above code generates the below HTML with a header text and button component without any interactivity.
<h1>Counter</h1>
<button>
<!-- -->0<!-- -->
times
</button>
At this stage hydrateRoot
API can be used to perform hydration by attaching onClick
event handler.
import { hydrateRoot } from "react-dom/client";
import App from "./App.js";
hydrateRoot(document.getElementById("root"), <App />);
After this step, you are able to run React application on server-side and hydrating the javascript bundle on client-side for smooth user experience and SEO purposes.
You cannot update the objects which exists in the state directly. Instead, you should create a fresh new object (or copy from the existing object) and update the latest state using the newly created object. Eventhough JavaScript objects are mutable, you need to treat objects inside state as read-only while updating the state.
Let's see this comparison with an example. The issue with regular object mutation approach can be described by updating the user details fields of Profile
component. The properties of Profile
component such as firstName, lastName and age details mutated in an event handler as shown below.
import { useState } from "react";
export default function Profile() {
const [user, setUser] = useState({
firstName: "John",
lastName: "Abraham",
age: 30,
});
function handleFirstNameChange(e) {
user.firstName = e.target.value;
}
function handleLastNameChange(e) {
user.lastName = e.target.value;
}
function handleAgeChange(e) {
user.age = e.target.value;
}
return (
<>
<label>
First name:
<input value={user.firstName} onChange={handleFirstNameChange} />
</label>
<label>
Last name:
<input value={user.lastName} onChange={handleLastNameChange} />
</label>
<label>
Age:
<input value={user.age} onChange={handleAgeChange} />
</label>
<p>
Profile:
{person.firstName} {person.lastName} ({person.age})
</p>
</>
);
}
Once you run the application with above user profile component, you can observe that user profile details won't be update upon entering the input fields. This issue can be fixed by creating a new copy of object which includes existing properties through spread syntax(...obj) and add changed values in a single event handler itself as shown below.
handleProfileChange(e) {
setUser({
...user,
});
}
The above event handler is concise instead of maintaining separate event handler for each field. Now, UI displays the updated field values as expected without an issue.
You cannot simply use spread syntax for all kinds of objects inside state. Because spread syntax is shallow and it copies properties for one level deep only. If the object has nested object structure, UI doesn't work as expected with regular JavaScript nested property mutation. Let's demonstrate this behavior with an example of User object which has address nested object inside of it.
const user = {
name: "John",
age: 32,
address: {
country: "Singapore",
postalCode: 440004,
},
};
If you try to update the country nested field in a regular javascript fashion(as shown below) then user profile screen won't be updated with latest value.
user.address.country = "Germany";
This issue can be fixed by flattening all the fields into a top-level object or create a new object for each nested object and point it to it's parent object. In this example, first you need to create copy of address object and update it with the latest value. Later, the address object should be linked to parent user object something like below.
setUser({
...user,
address: {
...user.address,
country: "Germany",
},
});
This approach is bit verbose and not easy for deep hierarchical state updates. But this workaround can be used for few levels of nested objects without much hassle.
Eventhough arrays in JavaScript are mutable in nature, you need to treat them as immutable while storing them in a state. That means, similar to objects, the arrays cannot be updated directly inside state. Instead, you need to create a copy of the existing array and then set the state to use newly copied array.
To ensure that arrays are not mutated, the mutation operations like direct direct assignment(arr[1]='one'), push, pop, shift, unshift, splice etc methods should be avoided on original array. Instead, you can create a copy of existing array with help of array operations such as filter, map, slice, spread syntax etc.
For example, the below push operation doesn't add the new todo to the total todo's list in an event handler.
onClick = {
todos.push({
id: id+1,
name: name
})
}
This issue is fixed by replacing push operation with spread syntax where it will create a new array and the UI updated with new todo.
onClick = {
[
...todos,
{ id: id+1, name: name }
]
}
Immer library enforces the immutability of state based on copy-on-write mechanism. It uses JavaScript proxy to keep track of updates to immutable states. Immer has 3 main states as below,
Current state: It refers to actual state
Draft state: All new changes will be applied to this state. In this state, draft is just a proxy of the current state.
Next state: It is formed after all mutations applied to the draft state
Immer can be used by following below instructions,
Install the dependency using npm install use-immer
command
Replace useState
hook with useImmer
hook by importing at the top
The setter function of useImmer
hook can be used to update the state.
For example, the mutation syntax of immer library simplifies the nested address object of user state as follows,
import { useImmer } from "use-immer";
const [user, setUser] = useImmer({
name: "John",
age: 32,
address: {
country: "Singapore",
postalCode: 440004,
},
});
//Update user details upon any event
setUser((draft) => {
draft.address.country = "Germany";
});
The preceding code enables you to update nested objects with a conceise mutation syntax.
The below table represent preferred and non-preferred array operations for updating the component state.
Action | Preferred | Non-preferred |
---|---|---|
Adding | concat, [...arr] | push, unshift |
Removing | filter, slice | pop, shift, splice |
Replacing | map | splice, arr[i] = someValue |
sorting | copying to new array | reverse, sort |
If you use Immer library then you can able to use all array methods without any problem.
Technically it is possible to write nested function components but it is not suggested to write nested function definitions. Because it leads to unexpected bugs and performance issues.
Keys are primarily used for rendering list items but they are not just for list items. You can also use them React to distinguish components. By default, React uses order of the components in
There are two guidelines to be taken care while writing reducers in your code.
Reducers must be pure without mutating the state. That means, same input always returns the same output. These reducers run during rendering time similar to state updater functions. So these functions should not send any requests, schedule time outs and any other side effects.
Each action should describe a single user interaction eventhough there are multiple changes applied to data. For example, if you "reset" registration form which has many user input fields managed by a reducer, it is suggested to send one "reset" action instead of creating separate action for each fields. The proper ordering of actions should reflect the user interactions in the browser and it helps a lot for debugging purpose.
Some of the common use cases of useContext are listed below,
You can efficiently build nextjs application if you are aware about which part of the application needs to use client components and which other parts needs to use server components. The common cases of both client and server components are listed below:
**Client components:**
1. Whenever your need to add interactivity and event listeners such as onClick(), onChange(), etc to the pages
2. If you need to use State and Lifecycle Effects like useState(), useReducer(), useEffect() etc.
3. If there is a requirement to use browser-only APIs.
4. If you need to implement custom hooks that depend on state, effects, or browser-only APIs.
5. There are React Class components in the pages.
**Server components:**
1. If the component logic is about data fetching.
2. If you need to access backend resources directly.
3. When you need to keep sensitive information((access tokens, API keys, etc) ) on the server.
4. If you want reduce client-side JavaScript and placing large dependencies on the server.
If you try to update the state directly then it won't re-render the component.
//Wrong
this.state.message = "Hello world";
Instead use setState()
method. It schedules an update to a component's state object. When state changes, the component responds by re-rendering.
//Correct
this.setState({ message: "Hello World" });
Note: You can directly assign to the state object either in constructor or using latest javascript's class field declaration syntax.
setState()
?The callback function is invoked when setState finished and the component gets rendered. Since setState()
is asynchronous the callback function is used for any post action.
Note: It is recommended to use lifecycle method rather than this callback function.
setState({ name: "John" }, () =>
console.log("The name has updated and component re-rendered")
);
There are 3 possible ways to achieve this in class components:
Binding in Constructor: In JavaScript classes, the methods are not bound by default. The same rule applies for React event handlers defined as class methods. Normally we bind them in constructor.
class User extends Component {
constructor(props) {
super(props);
this.handleClick = this.handleClick.bind(this);
}
handleClick() {
console.log("SingOut triggered");
}
render() {
return <button onClick={this.handleClick}>SingOut</button>;
}
}
Public class fields syntax: If you don't like to use bind approach then public class fields syntax can be used to correctly bind callbacks. The Create React App enables this syntax by default.
handleClick = () => {
console.log("SingOut triggered", this);
};
<button onClick={this.handleClick}>SingOut</button>
Arrow functions in callbacks: It is possible to use arrow functions directly in the callbacks.
handleClick() {
console.log('SingOut triggered');
}
render() {
return <button onClick={() => this.handleClick()}>SignOut</button>;
}
Note: If the callback is passed as prop to child components, those components might do an extra re-rendering. In those cases, it is preferred to go with .bind()
or public class fields syntax approach considering performance.
You can use an arrow function to wrap around an event handler and pass parameters:
<button onClick={() => this.handleClick(id)} />
This is an equivalent to calling .bind
:
<button onClick={this.handleClick.bind(this, id)} />
Apart from these two approaches, you can also pass arguments to a function which is defined as arrow function
<button onClick={this.handleClick(id)} />;
handleClick = (id) => () => {
console.log("Hello, your ticket number is", id);
};
The ref is used to return a reference to the element. They should be avoided in most cases, however, they can be useful when you need a direct access to the DOM element or an instance of a component.
There are two approaches
This is a recently added approach. Refs are created using React.createRef()
method and attached to React elements via the ref
attribute. In order to use refs throughout the component, just assign the ref to the instance property within constructor.
class MyComponent extends React.Component {
constructor(props) {
super(props);
this.myRef = React.createRef();
}
render() {
return <div ref={this.myRef} />;
}
}
You can also use ref callbacks approach regardless of React version. For example, the search bar component's input element is accessed as follows,
class SearchBar extends Component {
constructor(props) {
super(props);
this.txtSearch = null;
this.state = { term: "" };
this.setInputSearchRef = (e) => {
this.txtSearch = e;
};
}
onInputChange(event) {
this.setState({ term: this.txtSearch.value });
}
render() {
return (
<input
value={this.state.term}
onChange={this.onInputChange.bind(this)}
ref={this.setInputSearchRef}
/>
);
}
}
You can also use refs in function components using closures. Note: You can also use inline ref callbacks even though it is not a recommended approach.
Ref forwarding is a feature that lets some components take a ref they receive, and pass it further down to a child.
const ButtonElement = React.forwardRef((props, ref) => (
<button ref={ref} className="CustomButton">
{props.children}
</button>
));
// Create ref to the DOM button:
const ref = React.createRef();
<ButtonElement ref={ref}>{"Forward Ref"}</ButtonElement>;
It is preferred to use callback refs over findDOMNode()
API. Because findDOMNode()
prevents certain improvements in React in the future.
The legacy approach of using findDOMNode
:
class MyComponent extends Component {
componentDidMount() {
findDOMNode(this).scrollIntoView();
}
render() {
return <div />;
}
}
The recommended approach is:
class MyComponent extends Component {
constructor(props) {
super(props);
this.node = createRef();
}
componentDidMount() {
this.node.current.scrollIntoView();
}
render() {
return <div ref={this.node} />;
}
}
If you worked with React before, you might be familiar with an older API where the ref
attribute is a string, like ref={'textInput'}
, and the DOM node is accessed as this.refs.textInput
. We advise against it because string refs have below issues, and are considered legacy. String refs were removed in React v16.
this.refs
, as well as its type (which could be different). Callback refs are friendlier to static analysis.It doesn't work as most people would expect with the "render callback" pattern (e.g.
class MyComponent extends Component {
renderRow = (index) => {
// This won't work. Ref will get attached to DataTable rather than MyComponent:
return <input ref={"input-" + index} />;
// This would work though! Callback refs are awesome.
return <input ref={(input) => (this["input-" + index] = input)} />;
};
render() {
return (
<DataTable data={this.props.data} renderRow={this.renderRow} />
);
}
}
The component lifecycle has three distinct lifecycle phases:
Mounting: The component is ready to mount in the browser DOM. This phase covers initialization from constructor()
, getDerivedStateFromProps()
, render()
, and componentDidMount()
lifecycle methods.
Updating: In this phase, the component gets updated in two ways, sending the new props and updating the state either from setState()
or forceUpdate()
. This phase covers getDerivedStateFromProps()
, shouldComponentUpdate()
, render()
, getSnapshotBeforeUpdate()
and componentDidUpdate()
lifecycle methods.
Unmounting: In this last phase, the component is not needed and gets unmounted from the browser DOM. This phase includes componentWillUnmount()
lifecycle method.
It's worth mentioning that React internally has a concept of phases when applying changes to the DOM. They are separated as follows
Render The component will render without any side effects. This applies to Pure components and in this phase, React can pause, abort, or restart the render.
Pre-commit Before the component actually applies the changes to the DOM, there is a moment that allows React to read from the DOM through the getSnapshotBeforeUpdate()
.
Commit React works with the DOM and executes the final lifecycles respectively componentDidMount()
for mounting, componentDidUpdate()
for updating, and componentWillUnmount()
for unmounting.
React 16.3+ Phases (or an interactive version)
Before React 16.3
Before React 16.3
true
. If you are sure that the component doesn't need to render after state or props are updated, you can return false value. It is a great place to improve performance as it allows you to prevent a re-render if component receives new prop.shouldComponentUpdate()
which returns true.React 16.3+
render()
and is invoked on every render. This exists for rare use cases where you need a derived state. Worth reading if you need derived state.true
. If you are sure that the component doesn't need to render after the state or props are updated, you can return a false value. It is a great place to improve performance as it allows you to prevent a re-render if component receives a new prop.componentDidUpdate()
. This is useful to capture information from the DOM i.e. scroll position.shouldComponentUpdate()
returns false
.You can add/edit props passed to the component using props proxy pattern like this:
function HOC(WrappedComponent) {
return class Test extends Component {
render() {
const newProps = {
title: "New Header",
footer: false,
showFeatureX: false,
showFeatureY: true,
};
return <WrappedComponent {...this.props} {...newProps} />;
}
};
}
Context provides a way to pass data through the component tree without having to pass props down manually at every level.
For example, authenticated users, locale preferences, UI themes need to be accessed in the application by many components.
const { Provider, Consumer } = React.createContext(defaultValue);
A child class constructor cannot make use of this
reference until the super()
method has been called. The same applies to ES6 sub-classes as well. The main reason for passing props parameter to super()
call is to access this.props
in your child constructors.
Passing props:
class MyComponent extends React.Component {
constructor(props) {
super(props);
console.log(this.props); // prints { name: 'John', age: 42 }
}
}
Not passing props:
class MyComponent extends React.Component {
constructor(props) {
super();
console.log(this.props); // prints undefined
// but props parameter is still available
console.log(props); // prints { name: 'John', age: 42 }
}
render() {
// no difference outside constructor
console.log(this.props); // prints { name: 'John', age: 42 }
}
}
The above code snippets reveals that this.props
is different only within the constructor. It would be the same outside the constructor.
If you are using ES6 or the Babel transpiler to transform your JSX code then you can accomplish this with computed property names.
handleInputChange(event) {
this.setState({ [event.target.id]: event.target.value })
}
You need to make sure that function is not being called while passing the function as a parameter.
render() {
// Wrong: handleClick is called instead of passed as a reference!
return <button onClick={this.handleClick()}>{'Click Me'}</button>
}
Instead, pass the function itself without parenthesis:
render() {
// Correct: handleClick is passed as a reference!
return <button onClick={this.handleClick}>{'Click Me'}</button>
}
Error boundaries are 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.
A class component becomes an error boundary if it defines a new lifecycle method called componentDidCatch(error, info)
or static getDerivedStateFromError()
:
class ErrorBoundary extends React.Component {
constructor(props) {
super(props);
this.state = { hasError: false };
}
componentDidCatch(error, info) {
// You can also log the error to an error reporting service
logErrorToMyService(error, info);
}
static getDerivedStateFromError(error) {
// Update state so the next render will show the fallback UI.
return { hasError: true };
}
render() {
if (this.state.hasError) {
// You can render any custom fallback UI
return <h1>{"Something went wrong."}</h1>;
}
return this.props.children;
}
}
After that use it as a regular component:
<ErrorBoundary>
<MyWidget />
</ErrorBoundary>
React v15 provided very basic support for error boundaries using unstable_handleError
method. It has been renamed to componentDidCatch
in React v16.
react-dom
?This method is used to render a React element into the DOM in the supplied container and return a reference to the component. If the React element was previously rendered into container, it will perform an update on it and only mutate the DOM as necessary to reflect the latest changes.
ReactDOM.render(element, container, [callback])
If the optional callback is provided, it will be executed after the component is rendered or updated.
setState()
in constructor?When you use setState()
, then apart from assigning to the object state React also re-renders the component and all its children. You would get error like this: Can only update a mounted or mounting component. So we need to use this.state
to initialize variables inside constructor.
setState()
in componentWillMount()
method?Yes, it is safe to use setState()
inside componentWillMount()
method. But at the same it is recommended to avoid async initialization in componentWillMount()
lifecycle method. componentWillMount()
is invoked immediately before mounting occurs. It is called before render()
, therefore setting state in this method will not trigger a re-render. Avoid introducing any side-effects or subscriptions in this method. We need to make sure async calls for component initialization happened in componentDidMount()
instead of componentWillMount()
.
componentDidMount() {
axios.get(`api/todos`)
.then((result) => {
this.setState({
messages: [...result.data]
})
})
}
If the props on the component are changed without the component being refreshed, the new prop value will never be displayed because the constructor function will never update the current state of the component. The initialization of state from props only runs when the component is first created.
The below component won't display the updated input value:
class MyComponent extends React.Component {
constructor(props) {
super(props);
this.state = {
records: [],
inputValue: this.props.inputValue,
};
}
render() {
return <div>{this.state.inputValue}</div>;
}
}
Using props inside render method will update the value:
class MyComponent extends React.Component {
constructor(props) {
super(props);
this.state = {
record: [],
};
}
render() {
return <div>{this.props.inputValue}</div>;
}
}
You can decorate your class components, which is the same as passing the component into a function. Decorators are flexible and readable way of modifying component functionality.
@setTitle("Profile")
class Profile extends React.Component {
//....
}
/*
title is a string that will be set as a document title
WrappedComponent is what our decorator will receive when
put directly above a component class as seen in the example above
*/
const setTitle = (title) => (WrappedComponent) => {
return class extends React.Component {
componentDidMount() {
document.title = title;
}
render() {
return <WrappedComponent {...this.props} />;
}
};
};
Note: Decorators are a feature that didn't make it into ES7, but are currently a stage 2 proposal.
The create-react-app
CLI tool allows you to quickly create & run React applications with no configuration step.
Let's create Todo App using CRA:
# Installation
$ npm install -g create-react-app
# Create new project
$ create-react-app todo-app
$ cd todo-app
# Build, test and run
$ npm run build
$ npm run test
$ npm start
It includes everything we need to build a React app:
The lifecycle methods are called in the following order when an instance of a component is being created and inserted into the DOM.
constructor()
static getDerivedStateFromProps()
render()
componentDidMount()
The following lifecycle methods going to be unsafe coding practices and will be more problematic with async rendering.
componentWillMount()
componentWillReceiveProps()
componentWillUpdate()
Starting with React v16.3 these methods are aliased with UNSAFE_
prefix, and the unprefixed version will be removed in React v17.
getDerivedStateFromProps()
lifecycle method?The new static getDerivedStateFromProps()
lifecycle method is invoked after a component is instantiated as well as before it is re-rendered. It can return an object to update state, or null
to indicate that the new props do not require any state updates.
class MyComponent extends React.Component {
static getDerivedStateFromProps(props, state) {
// ...
}
}
This lifecycle method along with componentDidUpdate()
covers all the use cases of componentWillReceiveProps()
.
getSnapshotBeforeUpdate()
lifecycle method?The new getSnapshotBeforeUpdate()
lifecycle method is called right before DOM updates. The return value from this method will be passed as the third parameter to componentDidUpdate()
.
class MyComponent extends React.Component {
getSnapshotBeforeUpdate(prevProps, prevState) {
// ...
}
}
This lifecycle method along with componentDidUpdate()
covers all the use cases of componentWillUpdate()
.
It is recommended to name the component by reference instead of using displayName
.
Using displayName
for naming component:
export default React.createClass({
displayName: "TodoApp",
// ...
});
The recommended approach:
export default class TodoApp extends React.Component {
// ...
}
also
const TodoApp = () => {
//...
};
export default TodoApp;
Recommended ordering of methods from mounting to render stage:
static
methodsconstructor()
getChildContext()
componentWillMount()
componentDidMount()
componentWillReceiveProps()
shouldComponentUpdate()
componentWillUpdate()
componentDidUpdate()
componentWillUnmount()
onClickSubmit()
or onChangeDescription()
getSelectReason()
or getFooterContent()
renderNavigation()
or renderProfilePicture()
render()
The reason behind for this is that setState()
is an asynchronous operation. React batches state changes for performance reasons, so the state may not change immediately after setState()
is called. That means you should not rely on the current state when calling setState()
since you can't be sure what that state will be. The solution is to pass a function to setState()
, with the previous state as an argument. By doing this you can avoid issues with the user getting the old state value on access due to the asynchronous nature of setState()
.
Let's say the initial count value is zero. After three consecutive increment operations, the value is going to be incremented only by one.
// assuming this.state.count === 0
this.setState({ count: this.state.count + 1 });
this.setState({ count: this.state.count + 1 });
this.setState({ count: this.state.count + 1 });
// this.state.count === 1, not 3
If we pass a function to setState()
, the count gets incremented correctly.
this.setState((prevState, props) => ({
count: prevState.count + props.increment,
}));
// this.state.count === 3 as expected
(OR)
setState()
?React may batch multiple setState()
calls into a single update for performance. Because this.props
and this.state
may be updated asynchronously, you should not rely on their values for calculating the next state.
This counter example will fail to update as expected:
// Wrong
this.setState({
counter: this.state.counter + this.props.increment,
});
The preferred approach is to call setState()
with function rather than object. That function will receive the previous state as the first argument, and the props at the time the update is applied as the second argument.
// Correct
this.setState((prevState, props) => ({
counter: prevState.counter + props.increment,
}));
isMounted()
an anti-pattern and what is the proper solution?The primary use case for isMounted()
is to avoid calling setState()
after a component has been unmounted, because it will emit a warning.
if (this.isMounted()) {
this.setState({...})
}
Checking isMounted()
before calling setState()
does eliminate the warning, but it also defeats the purpose of the warning. Using isMounted()
is a code smell because the only reason you would check is because you think you might be holding a reference after the component has unmounted.
An optimal solution would be to find places where setState()
might be called after a component has unmounted, and fix them. Such situations most commonly occur due to callbacks, when a component is waiting for some data and gets unmounted before the data arrives. Ideally, any callbacks should be canceled in componentWillUnmount()
, prior to unmounting.
You should initialize state in the constructor when using ES6 classes, and getInitialState()
method when using React.createClass()
.
Using ES6 classes:
class MyComponent extends React.Component {
constructor(props) {
super(props);
this.state = {
/* initial state */
};
}
}
Using React.createClass()
:
const MyComponent = React.createClass({
getInitialState() {
return {
/* initial state */
};
},
});
Note: React.createClass()
is deprecated and removed in React v16. Use plain JavaScript classes instead.
By default, when your component's state or props change, your component will re-render. If your render()
method depends on some other data, you can tell React that the component needs re-rendering by calling forceUpdate()
.
component.forceUpdate(callback);
It is recommended to avoid all uses of forceUpdate()
and only read from this.props
and this.state
in render()
.
super()
and super(props)
in React using ES6 classes?When you want to access this.props
in constructor()
then you should pass props to super()
method.
Using super(props)
:
class MyComponent extends React.Component {
constructor(props) {
super(props);
console.log(this.props); // { name: 'John', ... }
}
}
Using super()
:
class MyComponent extends React.Component {
constructor(props) {
super();
console.log(this.props); // undefined
}
}
Outside constructor()
both will display same value for this.props
.
setState()
and replaceState()
methods?When you use setState()
the current and previous states are merged. replaceState()
throws out the current state, and replaces it with only what you provide. Usually setState()
is used unless you really need to remove all previous keys for some reason. You can also set state to false
/null
in setState()
instead of using replaceState()
.
The componentDidUpdate
lifecycle method will be called when state changes. You can compare provided state and props values with current state and props to determine if something meaningful changed.
componentDidUpdate(object prevProps, object prevState)
Note: The previous releases of ReactJS also uses componentWillUpdate(object nextProps, object nextState)
for state changes. It has been deprecated in latest releases.
The better approach is to use Array.prototype.filter()
method.
For example, let's create a removeItem()
method for updating the state.
removeItem(index) {
this.setState({
data: this.state.data.filter((item, i) => i !== index)
})
}
It is possible. Below are the possible options:
render() {
return false
}
render() {
return true
}
render() {
return null
}
React version >=16.0.0:
render() {
return []
}
render() {
return ""
}
React version >=16.2.0:
render() {
return <React.Fragment></React.Fragment>
}
render() {
return <></>
}
React version >=18.0.0:
render() {
return undefined
}
Calling setState()
with an object to merge with state:
Using Object.assign()
to create a copy of the object:
const user = Object.assign({}, this.state.user, { age: 42 });
this.setState({ user });
Using spread operator:
const user = { ...this.state.user, age: 42 };
this.setState({ user });
Calling setState()
with a function:
this.setState((prevState) => ({
user: {
...prevState.user,
age: 42,
},
}));
create-react-app
?There are approaches to include polyfills in create-react-app,
Manual import from core-js
:
Create a file called (something like) polyfills.js
and import it into root index.js
file. Run npm install core-js
or yarn add core-js
and import your specific required features.
import "core-js/fn/array/find";
import "core-js/fn/array/includes";
import "core-js/fn/number/is-nan";
Using Polyfill service:
Use the polyfill.io CDN to retrieve custom, browser-specific polyfills by adding this line to index.html
:
<script src="https://cdn.polyfill.io/v2/polyfill.min.js?features=default,Array.prototype.includes"></script>
In the above script we had to explicitly request the Array.prototype.includes
feature as it is not included in the default feature set.
You just need to use HTTPS=true
configuration. You can edit your package.json
scripts section:
"scripts": {
"start": "set HTTPS=true && react-scripts start"
}
or just run set HTTPS=true && npm start
Create a file called .env
in the project root and write the import path:
NODE_PATH=src/app
After that restart the development server. Now you should be able to import anything inside src/app
without relative paths.
You need to use setInterval()
to trigger the change, but you also need to clear the timer when the component unmounts to prevent errors and memory leaks.
componentDidMount() {
this.interval = setInterval(() => this.setState({ time: Date.now() }), 1000)
}
componentWillUnmount() {
clearInterval(this.interval)
}
React's reconciliation algorithm assumes that without any information to the contrary, if a custom component appears in the same place on subsequent renders, it's the same component as before, so reuses the previous instance rather than creating a new one.
You can use ES7 static
field to define constant.
class MyComponent extends React.Component {
static DEFAULT_PAGINATION = 10;
}
You could use the ref prop to acquire a reference to the underlying HTMLInputElement
object through a callback, store the reference as a class property, then use that reference to later trigger a click from your event handlers using the HTMLElement.click
method.
This can be done in two steps:
Create ref in render method:
<input ref={(input) => (this.inputElement = input)} />
Apply click event in your event handler:
this.inputElement.click();
You can use AJAX libraries such as Axios, jQuery AJAX, and the browser built-in fetch
. You should fetch data in the componentDidMount()
lifecycle method. This is so you can use setState()
to update your component when the data is retrieved.
For example, the employees list fetched from API and set local state:
class MyComponent extends React.Component {
constructor(props) {
super(props);
this.state = {
employees: [],
error: null,
};
}
componentDidMount() {
fetch("https://api.example.com/items")
.then((res) => res.json())
.then(
(result) => {
this.setState({
employees: result.employees,
});
},
(error) => {
this.setState({ error });
}
);
}
render() {
const { error, employees } = this.state;
if (error) {
return <div>Error: {error.message}</div>;
} else {
return (
<ul>
{employees.map((employee) => (
<li key={employee.name}>
{employee.name}-{employee.experience}
</li>
))}
</ul>
);
}
}
}
Render Props is a simple technique for sharing code between components using a prop whose value is a function. The below component uses render prop which returns a React element.
<DataProvider render={(data) => <h1>{`Hello ${data.target}`}</h1>} />
Libraries such as React Router and DownShift are using this pattern.
You can dispatch an action in componentDidMount()
method and in render()
method you can verify the data.
class App extends Component {
componentDidMount() {
this.props.fetchData();
}
render() {
return this.props.isLoaded ? (
<div>{"Loaded"}</div>
) : (
<div>{"Not Loaded"}</div>
);
}
}
const mapStateToProps = (state) => ({
isLoaded: state.isLoaded,
});
const mapDispatchToProps = { fetchData };
export default connect(mapStateToProps, mapDispatchToProps)(App);
connect()
from React Redux?You need to follow two steps to use your store in your container:
mapStateToProps()
: It maps the state variables from your store to the props that you specify.Connect the above props to your container: The object returned by the mapStateToProps
function is connected to the container. You can import connect()
from react-redux
.
import React from "react";
import { connect } from "react-redux";
class App extends React.Component {
render() {
return <div>{this.props.containerData}</div>;
}
}
function mapStateToProps(state) {
return { containerData: state.data };
}
export default connect(mapStateToProps)(App);
at
symbol in the Redux connect decorator?The @ symbol is in fact a JavaScript expression used to signify decorators. Decorators make it possible to annotate and modify classes and properties at design time.
Let's take an example setting up Redux without and with a decorator.
Without decorator:
import React from "react";
import * as actionCreators from "./actionCreators";
import { bindActionCreators } from "redux";
import { connect } from "react-redux";
function mapStateToProps(state) {
return { todos: state.todos };
}
function mapDispatchToProps(dispatch) {
return { actions: bindActionCreators(actionCreators, dispatch) };
}
class MyApp extends React.Component {
// ...define your main app here
}
export default connect(mapStateToProps, mapDispatchToProps)(MyApp);
With decorator:
import React from "react";
import * as actionCreators from "./actionCreators";
import { bindActionCreators } from "redux";
import { connect } from "react-redux";
function mapStateToProps(state) {
return { todos: state.todos };
}
function mapDispatchToProps(dispatch) {
return { actions: bindActionCreators(actionCreators, dispatch) };
}
@connect(mapStateToProps, mapDispatchToProps)
export default class MyApp extends React.Component {
// ...define your main app here
}
The above examples are almost similar except the usage of decorator. The decorator syntax isn't built into any JavaScript runtimes yet, and is still experimental and subject to change. You can use babel for the decorators support.
create-react-app
application?Starting from react-scripts@3.3.0+ releases onwards, you can now optionally start a new app from a template by appending `--template [template-name]` to the creation command. If you don't select a template, it will create your project with base template. Remember that templates are always named in the format `cra-template-[template-name]`, here you only need to fill the `[template-name]` section.
The typeScript can be used in your project by appending `--template typescript` to the creation command.
```bash
npx create-react-app my-app --template typescript
```
But if you are using React Scripting between react-scripts@2.1.0 and react-scripts@3.2.x , there is a built-in support for TypeScript. i.e, `create-react-app` now supports TypeScript natively. You can just pass `--typescript` option as below
```bash
npx create-react-app my-app --typescript
# or
yarn create react-app my-app --typescript
```
Whereas for lower versions of react scripts, just supply `--scripts-version` option as `react-scripts-ts` while you create a new project. `react-scripts-ts` is a set of adjustments to take the standard `create-react-app` project pipeline and bring TypeScript into the mix.
Now the project layout should look like the following:
```
my-app/
├─ .gitignore
├─ images.d.ts
├─ node_modules/
├─ public/
├─ src/
│ └─ ...
├─ package.json
├─ tsconfig.json
├─ tsconfig.prod.json
├─ tsconfig.test.json
└─ tslint.json
```
No, statics
only works with React.createClass()
:
someComponent = React.createClass({
statics: {
someMethod: function () {
// ..
},
},
});
But you can write statics inside ES6+ classes as below,
class Component extends React.Component {
static propTypes = {
// ...
};
static someMethod() {
// ...
}
}
or writing them outside class as below,
class Component extends React.Component {
....
}
Component.propTypes = {...}
Component.someMethod = function(){....}
If the ref callback is defined as an inline function, it will get called twice during updates, first with null and then again with the DOM element. This is because a new instance of the function is created with each render, so React needs to clear the old ref and set up the new one.
class UserForm extends Component {
handleSubmit = () => {
console.log("Input Value is: ", this.input.value);
};
render() {
return (
<form onSubmit={this.handleSubmit}>
<input type="text" ref={(input) => (this.input = input)} /> //
Access DOM input in handle submit
<button type="submit">Submit</button>
</form>
);
}
}
But our expectation is for the ref callback to get called once, when the component mounts. One quick fix is to use the ES7 class property syntax to define the function
class UserForm extends Component {
handleSubmit = () => {
console.log("Input Value is: ", this.input.value);
};
setSearchInput = (input) => {
this.input = input;
};
render() {
return (
<form onSubmit={this.handleSubmit}>
<input type="text" ref={this.setSearchInput} /> // Access DOM input
in handle submit
<button type="submit">Submit</button>
</form>
);
}
}
There are two main ways of implementing HOCs in React.
But they follow different approaches for manipulating the WrappedComponent.
Props Proxy
In this approach, the render method of the HOC returns a React Element of the type of the WrappedComponent. We also pass through the props that the HOC receives, hence the name Props Proxy.
function ppHOC(WrappedComponent) {
return class PP extends React.Component {
render() {
return <WrappedComponent {...this.props} />;
}
};
}
Inheritance Inversion
In this approach, the returned HOC class (Enhancer) extends the WrappedComponent. It is called Inheritance Inversion because instead of the WrappedComponent extending some Enhancer class, it is passively extended by the Enhancer. In this way the relationship between them seems inverse.
function iiHOC(WrappedComponent) {
return class Enhancer extends WrappedComponent {
render() {
return super.render();
}
};
}
React Class Components can be made much more concise using the class field declarations. You can initialize the local state without using the constructor and declare class methods by using arrow functions without the extra need to bind them.
Let's take a counter example to demonstrate class field declarations for state without using constructor and methods without binding,
class Counter extends Component {
state = { value: 0 };
handleIncrement = () => {
this.setState((prevState) => ({
value: prevState.value + 1,
}));
};
handleDecrement = () => {
this.setState((prevState) => ({
value: prevState.value - 1,
}));
};
render() {
return (
<div>
{this.state.value}
<button onClick={this.handleIncrement}>+</button>
<button onClick={this.handleDecrement}>-</button>
</div>
);
}
}
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.
Try catch block works with imperative code whereas error boundaries are meant for declarative code to render on the screen.
For example, the try catch block used for below imperative code
try {
showButton();
} catch (error) {
// ...
}
Whereas error boundaries wrap declarative code as below,
<ErrorBoundary>
<MyComponent />
</ErrorBoundary>
So 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.
The render()
method is the only required method in a class component. i.e, All methods other than render method are optional for a class component.
Below are the list of following types used and return from render method,
<div/>
and user defined elements.The constructor is mainly used for two purposes,
constructor(props) {
super(props);
// Don't call this.setState() here!
this.state = { counter: 0 };
this.handleClick = this.handleClick.bind(this);
}
No, it is not mandatory. i.e, If you don’t initialize state and you don’t bind methods, you don’t need to implement a constructor for your React component.
You should not call setState()
in componentWillUnmount()
because once a component instance is unmounted, it will never be mounted again.
This lifecycle method is invoked after an error has been thrown by a descendant component. It receives the error that was thrown as a parameter and should return a value to update state.
The signature of the lifecycle method is as follows,
static getDerivedStateFromError(error)
Let us take error boundary use case with the above lifecycle method for demonstration purpose,
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 };
}
render() {
if (this.state.hasError) {
// You can render any custom fallback UI
return <h1>Something went wrong.</h1>;
}
return this.props.children;
}
}
An update can be caused by changes to props or state. The below methods are called in the following order when a component is being re-rendered.
Below methods are called when there is an error during rendering, in a lifecycle method, or in the constructor of any child component.
This method is available from react-dom package and it removes a mounted React component from the DOM and clean up its event handlers and state. If no component was mounted in the container, calling this function does nothing. Returns true if a component was unmounted and false if there was no component to unmount.
The method signature would be as follows,
ReactDOM.unmountComponentAtNode(container);
Higher-order components come with a few caveats apart from its benefits. Below are the few listed in an order,
Don’t use HOCs inside the render method: It is not recommended to apply a HOC to a component within the render method of a component.
render() {
// A new version of EnhancedComponent is created on every render
// EnhancedComponent1 !== EnhancedComponent2
const EnhancedComponent = enhance(MyComponent);
// That causes the entire subtree to unmount/remount each time!
return <EnhancedComponent />;
}
The above code impacts on performance by remounting a component that causes the state of that component and all of its children to be lost. Instead, apply HOCs outside the component definition so that the resulting component is created only once.
Static methods must be copied over: When you apply a HOC to a component the new component does not have any of the static methods of the original component
// Define a static method
WrappedComponent.staticMethod = function () {
/*...*/
};
// Now apply a HOC
const EnhancedComponent = enhance(WrappedComponent);
// The enhanced component has no static method
typeof EnhancedComponent.staticMethod === "undefined"; // true
You can overcome this by copying the methods onto the container before returning it,
function enhance(WrappedComponent) {
class Enhance extends React.Component {
/*...*/
}
// Must know exactly which method(s) to copy :(
Enhance.staticMethod = WrappedComponent.staticMethod;
return Enhance;
}
Refs aren’t passed through: For HOCs you need to pass through all props to the wrapped component but this does not work for refs. This is because ref is not really a prop similar to key. In this case you need to use the React.forwardRef API
React.forwardRef accepts a render function as parameter and DevTools uses this function to determine what to display for the ref forwarding component.
For example, If you don't name the render function or not using displayName property then it will appear as ”ForwardRef” in the DevTools,
const WrappedComponent = React.forwardRef((props, ref) => {
return <LogProps {...props} forwardedRef={ref} />;
});
But If you name the render function then it will appear as ”ForwardRef(myFunction)”
const WrappedComponent = React.forwardRef(function myFunction(props, ref) {
return <LogProps {...props} forwardedRef={ref} />;
});
As an alternative, You can also set displayName property for forwardRef function,
function logProps(Component) {
class LogProps extends React.Component {
// ...
}
function forwardRef(props, ref) {
return <LogProps {...props} forwardedRef={ref} />;
}
// Give this component a more helpful display name in DevTools.
// e.g. "ForwardRef(logProps(MyComponent))"
const name = Component.displayName || Component.name;
forwardRef.displayName = `logProps(${name})`;
return React.forwardRef(forwardRef);
}
Yes, You can use. It is often the easiest way to pass parameters to callback functions. But you need to optimize the performance while using it.
class Foo extends Component {
handleClick() {
console.log("Click happened");
}
render() {
return <button onClick={() => this.handleClick()}>Click Me</button>;
}
}
Note: Using an arrow function in render method creates a new function each time the component renders, which may have performance implications
When you call setState() in the component, React merges the object you provide into the current state.
For example, let us take a facebook user with posts and comments details as state variables,
constructor(props) {
super(props);
this.state = {
posts: [],
comments: []
};
}
Now you can update them independently with separate setState()
calls as below,
componentDidMount() {
fetchPosts().then(response => {
this.setState({
posts: response.posts
});
});
fetchComments().then(response => {
this.setState({
comments: response.comments
});
});
}
As mentioned in the above code snippets, this.setState({comments})
updates only comments variable without modifying or replacing posts
variable.
During iterations or loops, it is common to pass an extra parameter to an event handler. This can be achieved through arrow functions or bind method.
Let us take an example of user details updated in a grid,
<button onClick={(e) => this.updateUser(userId, e)}>Update User details</button>
<button onClick={this.updateUser.bind(this, userId)}>Update User details</button>
In the both approaches, the synthetic argument e
is passed as a second argument. You need to pass it explicitly for arrow functions and it will be passed automatically for bind
method.
You can prevent component from rendering by returning null based on specific condition. This way it can conditionally render component.
function Greeting(props) {
if (!props.loggedIn) {
return null;
}
return <div className="greeting">welcome, {props.name}</div>;
}
class User extends React.Component {
constructor(props) {
super(props);
this.state = {loggedIn: false, name: 'John'};
}
render() {
return (
<div>
//Prevent component render if it is not loggedIn
<Greeting loggedIn={this.state.loggedIn} />
<UserDetails name={this.state.name}>
</div>
);
}
In the above example, the greeting
component skips its rendering section by applying condition and returning null value.
Context is designed to share data that can be considered global for a tree of React components.
For example, in the code below lets manually thread through a “theme” prop in order to style the Button component.
//Lets create a context with a default theme value "luna"
const ThemeContext = React.createContext("luna");
// Create App component where it uses provider to pass theme value in the tree
class App extends React.Component {
render() {
return (
<ThemeContext.Provider value="nova">
<Toolbar />
</ThemeContext.Provider>
);
}
}
// A middle component where you don't need to pass theme prop anymore
function Toolbar(props) {
return (
<div>
<ThemedButton />
</div>
);
}
// Lets read theme value in the button component to use
class ThemedButton extends React.Component {
static contextType = ThemeContext;
render() {
return <Button theme={this.context} />;
}
}
ContextType is used to consume the context object. The contextType property can be used in two ways,
contextType as property of class: The contextType property on a class can be assigned a Context object created by React.createContext(). After that, you can consume the nearest current value of that Context type using this.context in any of the lifecycle methods and render function.
Lets assign contextType property on MyClass as below,
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;
Static field You can use a static class field to initialize your contextType using public class field syntax.
class MyClass extends React.Component {
static contextType = MyContext;
render() {
let value = this.context;
/* render something based on the value */
}
}
A Consumer is a React component that subscribes to context changes. It requires a function as a child which receives current context value as argument 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.
Lets take a simple example,
<MyContext.Consumer>
{value => /* render something based on the context value */}
</MyContext.Consumer>
The 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 (
<Provider value={{ something: "something" }}>
<Toolbar />
</Provider>
);
}
}
This can be solved by lifting up the value to parent state,
class App extends React.Component {
constructor(props) {
super(props);
this.state = {
value: { something: "something" },
};
}
render() {
return (
<Provider value={this.state.value}>
<Toolbar />
</Provider>
);
}
}
Refs will not get passed through because ref is not a prop. It is handled differently by React just like key. If you add a ref to a HOC, the ref will refer to the outermost container component, not the wrapped component. In this case, you can use Forward Ref API. For example, we can explicitly forward refs to the inner FancyButton component using the React.forwardRef API.
The below HOC logs all props,
function logProps(Component) {
class LogProps extends React.Component {
componentDidUpdate(prevProps) {
console.log("old props:", prevProps);
console.log("new props:", this.props);
}
render() {
const { forwardedRef, ...rest } = this.props;
// Assign the custom prop "forwardedRef" as a ref
return <Component ref={forwardedRef} {...rest} />;
}
}
return React.forwardRef((props, ref) => {
return <LogProps {...props} forwardedRef={ref} />;
});
}
Let's use this HOC to log all props that get passed to our “fancy button” component,
class FancyButton extends React.Component {
focus() {
// ...
}
// ...
}
export default logProps(FancyButton);
Now let's create a ref and pass it to FancyButton component. In this case, you can set focus to button element.
import FancyButton from "./FancyButton";
const ref = React.createRef();
ref.current.focus();
<FancyButton label="Click Me" handleClick={handleClick} ref={ref} />;
Regular function or class components don’t receive the ref argument, and ref is not available in props either. The second ref argument only exists when you define a component with React.forwardRef call.
When you start using forwardRef in a component library, you should treat it as a breaking change and release a new major version of your library. This is because your library likely has a different behavior such as what refs get assigned to, and what types are exported. These changes can break apps and other libraries that depend on the old behavior.
If you don’t use ES6 then you may need to use the create-react-class module instead. For default props, you need to define getDefaultProps() as a function on the passed object. Whereas for initial state, you have to provide a separate getInitialState method that returns the initial state.
var Greeting = createReactClass({
getDefaultProps: function () {
return {
name: "Jhohn",
};
},
getInitialState: function () {
return { message: this.props.message };
},
handleClick: function () {
console.log(this.state.message);
},
render: function () {
return <h1>Hello, {this.props.name}</h1>;
},
});
Note: If you use createReactClass then auto binding is available for all methods. i.e, You don't need to use .bind(this)
with in constructor for event handlers.
Yes, JSX is not mandatory for using React. Actually it is convenient when you don’t want to set up compilation in your build environment. Each JSX element is just syntactic sugar for calling React.createElement(component, props, ...children)
.
For example, let us take a greeting example with JSX,
class Greeting extends React.Component {
render() {
return <div>Hello {this.props.message}</div>;
}
}
ReactDOM.render(
<Greeting message="World" />,
document.getElementById("root")
);
You can write the same code without JSX as below,
class Greeting extends React.Component {
render() {
return React.createElement("div", null, `Hello ${this.props.message}`);
}
}
ReactDOM.render(
React.createElement(Greeting, { message: "World" }, null),
document.getElementById("root")
);
You can implement most higher-order components (HOC) using a regular component with a render prop. For example, if you would prefer to have a withMouse HOC instead of a
function withMouse(Component) {
return class extends React.Component {
render() {
return (
<Mouse
render={(mouse) => <Component {...this.props} mouse={mouse} />}
/>
);
}
};
}
This way render props gives the flexibility of using either pattern.
The react-scripts
package is a set of scripts from the create-react-app starter pack which helps you kick off projects without configuring. The react-scripts start
command sets up the development environment and starts a server, as well as hot module reloading.
Below are the list of some of the features provided by create react app.
The ReactDOMServer#renderToNodeStream
method is used to generate HTML on the server and send the markup down on the initial request for faster page loads. It also helps search engines to crawl your pages easily for SEO purposes.
Note: Remember this method is not available in the browser but only server.
Redux team has provided official redux+js or redux+typescript templates for create-react-app project. The generated project setup includes,
<Provider>
passing the store to React componentsnpx create-react-app my-app --template redux
npx create-react-app my-app --template redux-typescript
State mutation
happens when you try to update the state of a component without actually using setState
function. This can happen when you are trying to do some computations using a state variable and unknowingly save the result in the same state variable. This is the main reason why it is advised to return new instances of state variables from the reducers by using Object.assign({}, ...) or spread syntax.
This can cause unknown issues in the UI as the value of the state variable got updated without telling React to check what all components were being affected from this update and it can cause UI bugs.
Ex:
class A extends React.component {
constructor(props) {
super(props);
this.state = {
loading: false
}
}
componentDidMount() {
let { loading } = this.state;
loading = (() => true)(); // Trying to perform an operation and directly saving in a state variable
}
How to prevent it: Make sure your state variables are immutable by either enforcing immutability by using plugins like Immutable.js, always using setState
to make updates, and returning new instances in reducers when sending updated state values.
The questions provided in this repository are the summary of frequently asked questions across numerous companies. We cannot guarantee that these questions will actually be asked during your interview process, nor should you focus on memorizing all of them. The primary purpose is for you to get a sense of what some companies might ask — do not get discouraged if you don't know the answer to all of them — that is ok!
Good luck with your interview 😊