A Beginner’s Guide to Webpack – SitePoint

Nowadays, we’re forced to use many accessory tools to facilitate, speed up and optimize our web development workflow. Often, though, such tools add an extra layer of complexity into the stack. As a result, we need to utilize additional time and effort to learn, understand and use these tools correctly. The same is true for webpack.
When using webpack for the first time, it can be difficult to understand how it works and how it should be used. Although it has good documentation, it can be daunting for novices, and it has a steep learning curve. However, webpack is worth learning and can save considerable time and effort in the long run. In this tutorial, I’ll introduce all the core concepts to help you get started.
Note: in this tutorial I’ve used webpack 5.9.0.
What Is Webpack?
As its core, webpack is a static module bundler. In a particular project, webpack treats all files and assets as modules. Under the hood, it relies on a dependency graph. A dependency graph describes how modules relate to each other using the references (require and import statements) between files. In this way, webpack statically traverses all modules to build the graph, and uses it to generate a single bundle (or several bundles) — a JavaScript file containing the code from all modules combined in the correct order. “Statically” means that, when webpack builds its dependency graph, it doesn’t execute the source code but stitches modules and their dependencies together into a bundle. This can then be included in your HTML files.
Now, to expand the above cursory overview, let’s explore the main concepts webpack uses.
Webpack Main Concepts
Webpack has some main concepts which we need to understand clearly before digging in its practical implementation. Let’s examine them one by one:
Entry: the entry point is the module that webpack uses to start building its internal dependency graph. From there, it determines which other modules and libraries that entry point depends on (directly and indirectly) and includes them in the graph until no dependency is left. By default, the entry property is set to ./src/index.js, but we can specify a different module (or even multiple modules) in the webpack configuration file.
Output: the output property instructs webpack where to emit the bundle(s) and what name to use for the file(s). The default value for this property is ./dist/main.js for the main bundle and ./dist for other generated files — such as images, for example. Of course, we can specify different values in the configuration depending on our needs.
Loaders: by default, webpack only understands JavaScript and JSON files. To process other types of files and convert them into valid modules, webpack uses loaders. Loaders transform the source code of non-JavaScript modules, allowing us to preprocess those files before they’re added to the dependency graph. For example, a loader can transform files from a CoffeeScript language to JavaScript or inline images to data URLs. With loaders we can even import CSS files directly from our JavaScript modules.
Plugins: plugins are used for any other task that loaders can’t do. They provide us with a wide range of solutions about asset management, bundle minimization and optimization, and so on.
Mode: typically, when we develop our application we work with two types of source code — one for the development build and one for the production build. Webpack allows us to set which one we want to be produced by changing the mode parameter to development, production or none. This allows webpack to use built-in optimizations corresponding to each environment. The default value is production. The none mode means that no default optimization options will be used. To learn more about the options webpack uses in development and production mode, visit the mode configuration page.
How Webpack Works
In this section, we’ll examine how webpack works. Even a simple project contains HTML, CSS and JavaScript files. Also, it can contains assets such as fonts, images, and so on. So, a typical webpack workflow would include setting up an index.html file with the appropriate CSS and JS links, and the necessary assets. Also, if you have many CSS and JS modules which depend on each other, they need to be optimized and properly combined in one unit ready for production.
To do all this, webpack relies on configuration. Starting from version 4 and above, webpack provides reasonable defaults out of the box, so creating a configuration file is not required. However, for any non-trivial project you’ll need to provide a special webpack.config.js file, which describes how the files and assets should be transformed and what kind of output should be generated. This file can quickly become monolithic, which makes it hard to understand how webpack does its job unless you know the main concepts behind its working.
Based on the provided configuration, webpack starts from the entry points and resolves each module it encounters while constructing the dependency graph. If a module contains dependencies, the process is performed recursively against each dependency until the traversal has completed. Then webpack bundles all the project’s modules into a small number of bundles — usually, just one — to be loaded by the browser.
What’s New in Webpack 5
A webpack 5 release was announced in October 2020. The post is quite long and explores all the changes made to webpack. It’s impossible to mention all changes and it’s unnecessary for a beginner’s guide like this. Instead, I’ll try to put a small list with some general highlights:
The build performance is improved with Persistent Caching. Developers can now enable a file-system–based cache, which will speed up the development builds.
The Long Term Caching is also improved. In webpack 5, changes made to the code that don’t affect the minimized bundle version (comments, variable names) won’t result in cache invalidation. Also, new algorithms were added which assign short numeric IDs to modules and chunks and short names to exports in a deterministic way. In webpack 5, they’re enabled by default in production mode.
Improved bundle size, thanks to better Tree Shaking and Code Generation. Thanks to the new Nested Tree-Shaking feature, webpack is now able to track access to nested properties of exports. The CommonJs Tree Shaking allows us to eliminate unused CommonJs exports.
The minimum supported Node.js version has increased from 6 to 10.13.0 (LTS).
The codebase is cleaned up. All items marked as deprecated in webpack 4 are removed.
Automatic Node.js polyfills are removed. Previous versions of webpack have included polyfills for native Node.js libraries like crypto. In many cases they are unnecessary and increase the bundle size drastically. That’s why webpack 5 stops automatically polyfilling these core modules and focuses on front-end–compatible modules.
As an improvement of development, webpack 5 allows us to pass a list of targets and also support versions of target. It provides automatic determination of the public path. And also, it offers automatic, unique naming, which prevents conflicts between multiple webpack runtimes that use the same global variable for chunk loading.
The webpack-dev-server command is now webpack serve.
Asset modules are introduced, which replace the uses of file-loader, raw-loader, and url-loader.
Please open the announcement link above to find more complete and detailed information about all the updates.
Finally, if you’re coming from webpack 4, here’s the migration guide.
Getting Started
Note: you can find the files for our project in the GitHub repo.
Now that we have a solid theoretical foundation, let’s implement it in practice.
To start, we’ll create a new directory and switch to it. Then we’ll initialize a new project:
mkdir learn-webpack
cd learn-webpack
npm init -y

Next, we need to install webpack and webpack CLI (command line interface) locally:
npm install webpack webpack-cli –save-dev

Now, the content of the generated package.json should be similar to the following:
{
“name”: “learn-webpack”,
“version”: “1.0.0”,
“description”: “”,
“main”: “index.js”,
“scripts”: {
“test”: “echo “Error: no test specified” && exit 1″
},
“keywords”: [],
“author”: “”,
“license”: “ISC”,
“devDependencies”: {
“webpack”: “^5.9.0”,
“webpack-cli”: “^4.2.0”
}
}

Besides being a package manager, npm can be used as a simple task runner. We can create webpack tasks by including the name of our task followed by its instructions in the scripts section of the package.json file. Let’s try this now. Open package.json and change the scripts object to the following:
“scripts”: {
“test”: “echo “Error: no test specified” && exit 1″,
“dev”: “webpack –mode development”,
“build”: “webpack –mode production”
},

Within the scripts property, npm allows us to reference locally installed Node.js packages by their names. We use that and the –mode flag to define dev and build tasks, which will run webpack in development (npm run dev) and production (npm run build) mode respectively.
Before we test the tasks we’ve just created, let’s create a src directory and put an index.js file in it so that it contains console.log(“Hello, Webpack!”);. Now we can already run the dev task to start webpack in development mode:
$ npm run dev

> [email protected] dev C:WEBDEVlearn-webpack
> webpack –mode development

[webpack-cli] Compilation finished
asset main.js 874 bytes [emitted] (name: main)
./src/index.js 31 bytes [built] [code generated]
webpack 5.9.0 compiled successfully in 122 ms

As I mentioned before, webpack sets the default entry point to ./src/index.js and the default output to ./dist/main.js. So what webpack does when we run the dev task is to get the source code from index.js file and bundle the final code in a main.js file.
Great! It works as expected. But to verify that we get the correct output, we need to display the result in the browser. To do that, let’s create an index.html file in the dist directory:



Getting Started With Webpack




Now, if we open the file in the browser, we should see the Hello, Webpack! message in the console.

So far, so good. But writing our index.html file manually can be problematic in some cases. For example, if we change the name of our entry point, the generated bundle will be renamed, but our index.html file will still reference the old name. So, we’ll need to update our HTML file manually every time we rename an entry point or add new one. Fortunately, we can easily fix that with the html-webpack-plugin. Let’s install it now:
npm install [email protected] –save-dev

Note: notice that I have typed [email protected] instead of just html-webpack-plugin. At the time of writing, the former is the proper version for webpack 5, and the latter is the version for webpack 4. This could change in future, so for the actual version check the html-webpack-plugin repo.
At this point, to activate the plugin, we need to create a webpack.config.js file in the root directory with the following content:
const HtmlWebpackPlugin = require(“html-webpack-plugin”);
const path = require(‘path’);

module.exports = {
plugins: [
new HtmlWebpackPlugin({
title: “Webpack Output”,
}),
],
};

As you can see, to activate a webpack plugin, we need to include it in the file and then add it to the plugins array. If needed, we also pass options to the plugin. See the html-webpack-plugin repo for all available options and the ability to write and use your own templates.
Let’s run webpack now to see what will happen:
$ npm run dev

> [email protected] dev C:WEBDEVlearn-webpack
> webpack –mode development

[webpack-cli] Compilation finished
asset main.js 874 bytes [compared for emit] (name: main)
asset index.html 234 bytes [emitted]
./src/index.js 31 bytes [built] [code generated]
webpack 5.9.0 compiled successfully in 151 ms

Let’s open the index.html. As we can see, the plugin automatically creates an updated index.html file for us, which uses the title option from the configuration:




Webpack Output





Let’s now expand our project and specify custom names for the entry and output properties. In webpack.config.js we add the following before the plugins property:
entry: {
main: path.resolve(__dirname, ‘./src/app.js’),
},
output: {
filename: ‘[name].bundle.js’,
path: path.resolve(__dirname, ‘deploy’)
},

Here, we change the entry file to app.js and the output folder to deploy. We also tweak the name of the generated bundle file slightly. Now it will start with the name of the entry (“main”) followed by the word “bundle” and the .js file extension.
Now, we’ll create an src/component.js file:
export default (text = “Hello, Webpack!”) => {
const element = document.createElement(“h1”);

element.innerHTML = text;

return element;
};

Next, we rename index.js to app.js to reflect our changes, and replace its content with the following:
import component from ‘./component’;

document.body.appendChild(component());

Now, let’s run webpack again:
$ npm run dev

> [email protected] dev C:WEBDEVlearn-webpack
> webpack –mode development

[webpack-cli] Compilation finished
asset main.bundle.js 4.67 KiB [emitted] (name: main)
asset index.html 241 bytes [emitted]
runtime modules 668 bytes 3 modules
cacheable modules 230 bytes
./src/app.js 79 bytes [built] [code generated]
./src/component.js 151 bytes [built] [code generated]
webpack 5.9.0 compiled successfully in 194 ms

Let’s examine and clarify the information from the webpack output. After the “Compilation finished” message you can see the files generated in the deploy directory (main.bundle.js and index.html). Below them, you can see the source files: the entry module (app.js) and its dependency (component.js).
So now, in the deploy folder, we have the newly generated bundle file main.bundle.js. If we open the index.html file in the browser, we should see Hello, Webpack! displayed on the page.

Also, if we check the source of index.html, we’ll see that the value of the src property in the script tag is updated to main.bundle.js.
At this point, we can delete the dist folder, which webpack generated initially, because we won’t need it anymore.
Transpiling Modern JavaScript to ES5
In this section, we’ll discover how ES6 can be transpiled to ES5-compliant code that works in all browsers. Let’s start by running the following command:
npm run dev — –devtool inline-source-map

Here, I run webpack with devtool option set to inline-source-map in order to render the code more readable. This way I can demonstrate the code transpilation from ES6 to ES5 more clearly.
Next, let’s open main.bundle.js:

__webpack_require__.d(__webpack_exports__, {
“default”: () => __WEBPACK_DEFAULT_EXPORT__
});
const __WEBPACK_DEFAULT_EXPORT__ = ((text = “Hello, Webpack!”) => {
const element = document.createElement(“h1”);

element.innerHTML = text;

return element;
});

As you can see, the modern ES6 features (the arrow function and the const declaration) from component.js module are not transformed to ES5-compliant code by default. To make our code work in older browsers, we must add the Babel loader:
npm install babel-loader @babel/core @babel/preset-env –save-dev

Then, in webpack.config.js add module after the output property:
module: {
rules: [
{
test: /.js$/,
exclude: /node_modules/,
use: {
loader: ‘babel-loader’,
options: {
presets: [‘@babel/preset-env’]
}
}
},
]
},

When we define rules for a webpack loader, there are usually three main properties we need to define:
test, which describes what kind of files should be transformed.
exclude, which defines the files that shouldn’t be processed from the loader(s), if we have such.
use, which tells which loader(s) should be used against the matched modules. Here, we can also set the loader options, as we’ve just done with the presets option.
Run the following command again:
npm run dev — –devtool inline-source-map

This time, the code in main.bundle.js is compiled:

__webpack_require__.d(__webpack_exports__, {
“default”: () => __WEBPACK_DEFAULT_EXPORT__
});
const __WEBPACK_DEFAULT_EXPORT__ = (function () {
var text = arguments.length > 0 && arguments[0] !== undefined ? arguments[0] : “Hello, Webpack!”;
var element = document.createElement(“h1”);
element.innerHTML = text;
return element;
});

Perfect. Now we can use the modern JS features, and webpack will transform our code so it can be executed by older browsers.
Working with Styles
In this section, we’ll see how we can add some styles to our project. To do this, we need to install two loaders:
npm install css-loader style-loader –save-dev

css-loader parses the CSS into JavaScript and resolves any dependencies
style-loader outputs our CSS into a