At its core, webpack is a static module bundler for modern JavaScript applications. When webpack processes your application, it internally builds a dependency graph which maps every module your project needs and generates one or more bundles.
Learn more about JavaScript modules and webpack modules here.
Since version 4.0.0, webpack does not require a configuration file to bundle your project. Nevertheless, it is incredibly configurable to better fit your needs.
To get started you only need to understand its Core Concepts:
This document is intended to give a high-level overview of these concepts, while providing links to detailed concept-specific use cases.
For a better understanding of the ideas behind module bundlers and how they work under the hood, consult these resources:
An entry point indicates which module webpack should use to begin building out its internal dependency graph. webpack will figure out which other modules and libraries that entry point depends on (directly and indirectly).
By default its value is ./src/index.js
, but you can specify a different (or multiple entry points) by setting an entry
property in the webpack configuration. For example:
webpack.config.js
module.exports = {
entry: './path/to/my/entry/file.js'
};
Learn more in the entry points section.
The output property tells webpack where to emit the bundles it creates and how to name these files. It defaults to ./dist/main.js
for the main output file and to the ./dist
folder for any other generated file.
You can configure this part of the process by specifying an output
field in your configuration:
webpack.config.js
const path = require('path');
module.exports = {
entry: './path/to/my/entry/file.js',
output: {
path: path.resolve(__dirname, 'dist'),
filename: 'my-first-webpack.bundle.js'
}
};
In the example above, we use the output.filename
and the output.path
properties to tell webpack the name of our bundle and where we want it to be emitted to. In case you're wondering about the path module being imported at the top, it is a core Node.js module that gets used to manipulate file paths.
The
output
property has many more configurable features. If you want to learn about the concepts behind it, you can read more in the output section.
Out of the box, webpack only understands JavaScript and JSON files. Loaders allow webpack to process other types of files and convert them into valid modules that can be consumed by your application and added to the dependency graph.
Note that the ability to
import
any type of module, e.g..css
files, is a feature specific to webpack and may not be supported by other bundlers or task runners. We feel this extension of the language is warranted as it allows developers to build a more accurate dependency graph.
At a high level, loaders have two properties in your webpack configuration:
test
property identifies which file or files should be transformed.use
property indicates which loader should be used to do the transforming.webpack.config.js
const path = require('path');
module.exports = {
output: {
filename: 'my-first-webpack.bundle.js'
},
module: {
rules: [
{ test: /\.txt$/, use: 'raw-loader' }
]
}
};
The configuration above has defined a rules
property for a single module with two required properties: test
and use
. This tells webpack's compiler the following:
"Hey webpack compiler, when you come across a path that resolves to a '.txt' file inside of a
require()
/import
statement, use theraw-loader
to transform it before you add it to the bundle."
It is important to remember that when defining rules in your webpack config, you are defining them under
module.rules
and notrules
. For your benefit, webpack will warn you if this is done incorrectly.
Keep in mind that when using regex to match files, you may not quote it. i.e
/\.txt$/
is not the same as'/\.txt$/'
or"/\.txt$/"
. The former instructs webpack to match any file that ends with .txt and the latter instructs webpack to match a single file with an absolute path '.txt'; this is likely not your intention.
You can check further customization when including loaders in the loaders section.
While loaders are used to transform certain types of modules, plugins can be leveraged to perform a wider range of tasks like bundle optimization, asset management and injection of environment variables.
Check out the plugin interface and how to use it to extend webpack's capabilities.
In order to use a plugin, you need to require()
it and add it to the plugins
array. Most plugins are customizable through options. Since you can use a plugin multiple times in a config for different purposes, you need to create an instance of it by calling it with the new
operator.
webpack.config.js
const HtmlWebpackPlugin = require('html-webpack-plugin'); //installed via npm
const webpack = require('webpack'); //to access built-in plugins
module.exports = {
module: {
rules: [
{ test: /\.txt$/, use: 'raw-loader' }
]
},
plugins: [
new HtmlWebpackPlugin({template: './src/index.html'})
]
};
In the example above, the html-webpack-plugin
generates an HTML file for your application by injecting automatically all your generated bundles.
There are many plugins that webpack provides out of the box! Check out the list of plugins.
Using plugins in your webpack config is straightforward. However, there are many use cases that are worth further exploration. Learn more about them here.
By setting the mode
parameter to either development
, production
or none
, you can enable webpack's built-in optimizations that correspond to each environment. The default value is production
.
module.exports = {
mode: 'production'
};
Learn more about the mode configuration here and what optimizations take place on each value.
webpack supports all browsers that are ES5-compliant (IE8 and below are not supported). webpack needs Promise
for import()
and require.ensure()
. If you want to support older browsers, you will need to load a polyfill before using these expressions.