Beginning React: Simplify your frontend development workflow and enhance the user experience of your applications with React

Fortunately, we can use create-react-app, a command-line interface (CLI) tool that allows us to set up a React-based application without needing to configure any of the aforementioned tools. It is based on Node.js and provides commands to set up and modify a React application in an immediate way.

In order to install create-react-app, you need Node.js installed on your machine. You can install the CLI by typing the following command in a console window:

npm install -g create-react-app

After installation, you can verify whether it is properly installed by typing the following command:

create-react-app --version

If all is OK, the installed version of create-react-app will be shown.

Now that the development environment is installed, let's create our first React application. We can do this by typing the following command in a console window:

create-react-app hello-react

This command tells create-react-app to set up all of the prerequisites for a React-based application named hello-react. The creation process may take several minutes, since it has to download the npm packages needed for the project.

Let's take a look at the files generated by create-react-app, so that we can get an understanding of the structure of a React-based application. We will find these files and folders inside of the HELLO-REACT folder as shown in the following screenshot:

In the root folder, we can see a README.md file, the package.json file, and the .gitignore file.

The README document contains references to all you need to start building a React-based application. It is written in Markdown format, and you can integrate or overwrite it with your own documentation.

The package.json file contains information about the project, such as the name, the version, and so on, and references to all the npm packages used by the current project. This is a Node.js asset that allows you to download the required packages when copying the project to another machine. It also contains the definitions of scripts that allow us to manage the project itself.

The following is an example of package.json file content:

{
  "name": "hello-react",
  "version": "0.1.0",
  "private": true,
  "dependencies": {
    "react": "^16.0.0",
    "react-dom": "^16.0.0",
    "react-scripts": "1.0.14"
  },
  "scripts": {
    "start": "react-scripts start",
    "build": "react-scripts build",
    "test": "react-scripts test --env=jsdom",
    "eject": "react-scripts eject"
  }
}

As we can see, the file's content is a JSON object, with a few easy to recognize properties. In particular, we can identify the project's name, the version, and package dependencies. Apart from the name and version properties, usually, you don't need to manually change these settings.

The .gitignore file is a hidden file in Unix-based systems, and it allows us to track which file(s) to ignore when using Git as a version control system. The create-react-app tool added this file because nowadays, it is essential to have a project under version control. It suggests Git, since it is one of the most popular version control systems.

The public folder contains the static parts of our application:

In particular, the index.html file is the starting point of our application. Let's take a look at it so that we can understand what's special about it:

<!doctype html>
<html lang="en">
  <head>
    <meta charset="utf-8">
    <meta name="viewport" content="width=device-width, initial-scale=1, shrink-to-fit=no">
    <meta name="theme-color" content="#000000">
    <link rel="manifest" href="%PUBLIC_URL%/manifest.json">
...
    <title>React App</title>
  </head>
  <body>
    <noscript>
      You need to enable JavaScript to run this app.
    </noscript>
  <div id="root"></div>
...
</html>

As we can see, it is a standard HTML page; however, a few things should be noted. First of all, we see a link to the manifest.json file:

<link rel="manifest" href="%PUBLIC_URL%/manifest.json">

This manifest contains metadata for configuring our app as a PWA.

The second thing we notice is the %PUBLIC_URL% placeholder in both link references:

<link rel="manifest" href="%PUBLIC_URL%/manifest.json">
<link rel="shortcut icon" href="%PUBLIC_URL%/favicon.ico">

This placeholder will be replaced with the actual URL of the public folder during the build process.

The body of the HTML page contains an empty div with a root identifier. This is an important item for the correct setup of our React application, as we will soon see. Apart from the <noscript> tag, we do not see any other element in the body. However, we need a binding between the HTML page and the JavaScript. The build process will be responsible for adding the required scripts to the body.

The most important folder for developing our application is the src folder. It contains the basic files, with the code that we can modify for our purposes.

In particular, we will find the following files:

Let's analyze the content of a couple of these files, since their code is fundamental to understanding how the startup of a React application works.

Let's start with the index.js file. Its content is shown as follows:

import React from 'react';
import ReactDOM from 'react-dom';
import './index.css';
import App from './App';
import registerServiceWorker from './registerServiceWorker';

ReactDOM.render(<App />, document.getElementById('root'));
registerServiceWorker();

It is an ECMAScript 2015 module, importing other modules. In particular, it imports the React and ReactDOM objects from the react and react-dom modules, respectively. Both modules are part of the React library and are stored inside the node_modules folder.

The react module provides functionality for component creation and state management. The react-dom module is the glue between React components and the HTML DOM. The React library has been split into two modules in order to separate the component management from the actual rendering. This separation may be useful when we want to target a rendering platform that is not the web; for example, if we want to target native mobile rendering.

Other modules are imported from the same folder as the index.js file. In particular, we import the App component from the App module. The App component is used by the render() method of the ReactDOM object in order to bind it to the div element in the HTML page. This magic is performed by the following statement:

ReactDOM.render(<App />, document.getElementById('root'));

For the moment, let's ignore the syntax used to render the App component. This will be covered in the next chapter. The meaning of this statement is to associate the React App component defined inside the App module with the HTML element identified by the root ID.

The registerServiceWorker() function import and invocation enables the support for offline behavior, in line with the PWA specification, while the import of index.css makes the CSS styling available to the application.

The App.js file contains the definition of the React component representing the application. Its content looks like the following:

import React, { Component } from 'react';
import logo from './logo.svg';
import './App.css';

class App extends Component {
  render() {
    return (
      <div className="App">
        <header className="App-header">
          <img src={logo} className="App-logo" alt="logo" />
          <h1 className="App-title">Welcome to React</h1>
        </header>
        <p className="App-intro">
...
export default App;

Let's take a quick look at the code, since it will be covered in detail in the next chapter. For the moment, we only want to get a very basic idea of how a React component is defined. Here, we see a module importing a few items from other modules, defining the App class by inheriting from the Component class and exporting the App class itself as a default export. That's all, for the moment. We will cover this code in depth in the next chapter, understanding its meaning in detail.

The create-react-app CLI provides a few commands to manage our React project. These commands appear in the form npm <command>, since they are based on the npm.

The npm start Command

The first command we will cover is npm start. This command starts a development web server accepting requests at http://localhost:3000.

So, after launching this command, we can open a browser and see the following result:

The development web server has a hot reloading system that allows us to change the code of our application and get the page refreshed in the browser after saving the file.

Changing File Content and Viewing the Result

This following steps show how changing the content of a file causes the application to reload in the browser:

1. Open a console window.
2. Go to the hello-react folder.
3. Run npm start.
4. Launch a browser and go to http://localhost:3000.
5. Launch a text editor and open the App.js file.
6. Search for the following line of code:

To get started, edit <code>src/App.js</code> and save to reload.

7. Replace the code mentioned in step 6 with the following line of code:

Hello React!

8. Save the file.
9. Check the browser content. Now it should display the new text.

Activity: Starting and Changing the Application

Scenario

We want to change the title of the application that was created in the previous activity.

Aim

The aim of the activity is to become familiar with launching an application and appreciating the hot reloading feature.

Steps for Completion

1. Start the application so that you can see it in a browser
2. Edit the App.js file and set the title to My Shop

Solution

There is no formal solution. You should focus on getting the title correctly changed and the application running.

The npm test Command

create-react-app promotes the use of unit tests by generating a sample unit test file, as we have already seen, and by providing a set of tools to run such tests.

These tools are based on Jest, and we can run the tests written within our application by running the following command:

npm test

This command will start running our test and will show the results, as shown in the following screenshot:

The npm run build Command

When we are ready to move our application into the production environment, we need the artifacts to publish. We can produce these artifacts by running the following command:

npm run build

The result of running this command is a new BUILD folder where we will find all of the files that we need to move into a production environment. The command carries out some processing on the files of our development environment. Put simply, it translates all of the ES2015 code we wrote into ES5 compatible code, so that it is also available for older browsers. This process is called transpilation. In addition, it reduces the size of the code itself, allowing for faster downloading over the network. This process is called minification. Finally, it takes the files in our development environment and combines them into a few files, called bundles, in order to decrease network requests.

The following screenshot shows the content of the BUILD folder of the sample application:

To publish the production build of our application, we can just copy the content of the BUILD folder into the production server's folder.

Note

The result of the production build assumes that the artifact will be published into the web server root, that is, at a location where the application will be accessible through a URL such as http://www.myapplication.com. If we need to publish the application in a root's subfolder, that is, at a location where the application will be accessible through a URL such as http://www.myapplication.com/app, we need to make a slight change to the package.json file. In this case, we need to add a homepage key to the configuration JSON with the URL as its value, as shown here:"homepage": "http://www.myapplication.com/app".

npm run eject

The main concept introduced by React in user interface design and implementation is the component concept. A user interface is an aggregate of components, and the whole React application is an aggregate of components. We will now see in more detail what components are from a design point of view.

Consider a form in a web page. It can be treated as a component, since it has a specific role: to collect data and send it to the server. Also, a textbox inside the form can be considered a component. It has a specific role: to collect a single piece of data that will be sent to the server. So, a component may contain other components. And this is what usually happens: a user interface is a hierarchy of components, where some components contain other components.

Keep this concept in mind, since it will be useful to implement efficient and reusable user interfaces.

To better understand how to design a user interface and how to create components to implement them, we will try to decompose a well-known web user interface—the YouTube main page:

We can detect several items on this page, each having a specific role, starting with the page itself, whose role is to allow the user to interact with the system.

If we consider the header, the left sidebar, and the main area, all of these items are components of the page. You can see them highlighted in the following screenshot:

Of course, we can go ahead and detect other components. For example, we can consider each video preview box in the main area as a component. You can see them in the following screenshot:

This decomposition process allows us to focus on the specific role of each item in an interface, so that we can try to isolate each functionality and create reusable components, that is, components with just the dependencies that really matter.

We can classify the components in a user interface into container and presentational components.

The container components are components that do not have a relevant visual effect. Their main role is to group other components, that is, contain other components. For example, a form is usually a container component, since its main role is to contain other components, such as textboxes, labels, buttons, and so on.

The presentational components are components that display data in some graphical form. A textbox, a date picker, and a toolbar are examples of presentational components.

The distinction between container and presentational components is very important in order to create efficient user interfaces in React. We will exploit this distinction later, when we learn to manage the components' state and to propagate data through the components.

Activity: Detecting Components in a Web User Interface

Scenario

We need to convert the Wikipedia website's user interface (https://en.wikipedia.org) into React components.

Aim

The aim of the activity is to address the design process when implementing React-based user interfaces.

Steps for Completion

1. Analyze the page's current structure and detect the items you can implement as components
2. Indicate which would be container and which would be presentational components

Solution

Assume that the following is the current Wikipedia home page:

A possible solution could be as follows.

We can detect the following components:

• The home page component contains the left sidebar component, the header component, and the main area component. All of these components are container components.
• The left-side component contains the logo component (presentational) and a list of section components (presentational).
• The header component contains a list of link components (presentational) to general pieces of functionality.
• The main area component contains a list of tab components (container) and a search component (presentational).
• The main tab component contains a banner component (presentational), a topic index component (presentational), and a list of block components (presentational).