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Tutorial

Creating Your First Bundle

Before we begin, you'll need to have Node.js installed so that you can use NPM. You'll also need to know how to access the command line on your machine.

The easiest way to use Rollup is via the Command Line Interface (or CLI). For now, we'll install it globally (later on we'll learn how to install it locally to your project so that your build process is portable, but don't worry about that yet). Type this into the command line:

shell
npm install rollup --global
# or `npm i rollup -g` for short

You can now run the rollup command. Try it!

shell
rollup

Because no arguments were passed, Rollup prints usage instructions. This is the same as running rollup --help, or rollup -h.

Let's create a simple project:

shell
mkdir -p my-rollup-project/src
cd my-rollup-project

First, we need an entry point. Paste this into a new file called src/main.js:

js
// src/main.js
import foo from './foo.js';
export default function () {
	console.log(foo);
}

Then, let's create the foo.js module that our entry point imports:

js
// src/foo.js
export default 'hello world!';

Now we're ready to create a bundle:

shell
rollup src/main.js -f cjs

The -f option (short for --format) specifies what kind of bundle we're creating — in this case, CommonJS (which will run in Node.js). Because we didn't specify an output file, it will be printed straight to stdout:

js
'use strict';

const foo = 'hello world!';

const main = function () {
	console.log(foo);
};

module.exports = main;

You can save the bundle as a file like so:

shell
rollup src/main.js -o bundle.js -f cjs

(You could also do rollup src/main.js -f cjs > bundle.js, but as we'll see later, this is less flexible if you're generating sourcemaps.)

Try running the code:

node
> var myBundle = require('./bundle.js');
> myBundle();
'hello world!'

Congratulations! You've created your first bundle with Rollup.

Using Config Files

So far, so good, but as we start adding more options it becomes a bit of a nuisance to type out the command.

To save repeating ourselves, we can create a config file containing all the options we need. A config file is written in JavaScript and is more flexible than the raw CLI.

Create a file in the project root called rollup.config.mjs, and add the following code:

js
// rollup.config.mjs
export default {
	
input
: 'src/main.js',
output
: {
file
: 'bundle.js',
format
: 'cjs'
} };

(Note that you can use CJS modules and therefore module.exports = {/* config */})

To use the config file, we use the --config or -c flag:

shell
rm bundle.js # so we can check the command works!
rollup -c

You can override any of the options in the config file with the equivalent command line options:

shell
rollup -c -o bundle-2.js # `-o` is equivalent to `--file` (formerly "output")

Note: Rollup itself processes the config file, which is why we're able to use export default syntax – the code isn't being transpiled with Babel or anything similar, so you can only use ES2015 features that are supported in the version of Node.js that you're running.

You can, if you like, specify a different config file from the default rollup.config.mjs:

shell
rollup --config rollup.config.dev.mjs
rollup --config rollup.config.prod.mjs

Installing Rollup locally

When working within teams or distributed environments it can be wise to add Rollup as a local dependency. Installing Rollup locally prevents the requirement that multiple contributors install Rollup separately as an extra step, and ensures that all contributors are using the same version of Rollup.

To install Rollup locally with NPM:

shell
npm install rollup --save-dev

Or with Yarn:

shell
yarn -D add rollup

After installing, Rollup can be run within the root directory of your project:

shell
npx rollup --config

Or with Yarn:

shell
yarn rollup --config

Once installed, it's common practice to add a single build script to package.json, providing a convenient command for all contributors. e.g.

json
{
	"scripts": {
		"build": "rollup --config"
	}
}

Note: Once installed locally, both NPM and Yarn will resolve the dependency's bin file and execute Rollup when called from a package script.

Using plugins

So far, we've created a simple bundle from an entry point and a module imported via a relative path. As you build more complex bundles, you'll often need more flexibility – importing modules installed with NPM, compiling code with Babel, working with JSON files and so on.

For that, we use plugins, which change the behaviour of Rollup at key points in the bundling process. A list of awesome plugins is maintained on the Rollup Awesome List.

For this tutorial, we'll use @rollup/plugin-json, which allows Rollup to import data from a JSON file.

Create a file in the project root called package.json, and add the following content:

json
{
	"name": "rollup-tutorial",
	"version": "1.0.0",
	"scripts": {
		"build": "rollup -c"
	}
}

Install @rollup/plugin-json as a development dependency:

shell
npm install --save-dev @rollup/plugin-json

(We're using --save-dev rather than --save because our code doesn't actually depend on the plugin when it runs – only when we're building the bundle.)

Update your src/main.js file so that it imports from your package.json instead of src/foo.js:

js
// src/main.js
import { version } from '../package.json';

export default function () {
	console.log('version ' + version);
}

Edit your rollup.config.mjs file to include the JSON plugin:

js
// rollup.config.mjs
import 
json
from '@rollup/plugin-json';
export default {
input
: 'src/main.js',
output
: {
file
: 'bundle.js',
format
: 'cjs'
},
plugins
: [
json
()]
};

Run Rollup with npm run build. The result should look like this:

js
'use strict';

var version = '1.0.0';

function main() {
	console.log('version ' + version);
}

module.exports = main;

Note: Only the data we actually need gets imported – name and devDependencies and other parts of package.json are ignored. That's tree-shaking in action.

Using output plugins

Some plugins can also be applied specifically to some outputs. See plugin hooks for the technical details of what output-specific plugins can do. In a nut-shell, those plugins can only modify code after the main analysis of Rollup has completed. Rollup will warn if an incompatible plugin is used as an output-specific plugin. One possible use-case is minification of bundles to be consumed in a browser.

Let us extend the previous example to provide a minified build together with the non-minified one. To that end, we install @rollup/plugin-terser:

shell
npm install --save-dev @rollup/plugin-terser

Edit your rollup.config.mjs file to add a second minified output. As format, we choose iife. This format wraps the code so that it can be consumed via a script tag in the browser while avoiding unwanted interactions with other code. As we have an export, we need to provide the name of a global variable that will be created by our bundle so that other code can access our export via this variable.

js
// rollup.config.mjs
import 
json
from '@rollup/plugin-json';
import
terser
from '@rollup/plugin-terser';
export default {
input
: 'src/main.js',
output
: [
{
file
: 'bundle.js',
format
: 'cjs'
}, {
file
: 'bundle.min.js',
format
: 'iife',
name
: 'version',
plugins
: [
terser
()]
} ],
plugins
: [
json
()]
};

Besides bundle.js, Rollup will now create a second file bundle.min.js:

js
var version = (function () {
	'use strict';
	var n = '1.0.0';
	return function () {
		console.log('version ' + n);
	};
})();

Code Splitting

For code splitting, there are cases where Rollup splits code into chunks automatically, like dynamic loading or multiple entry points, and there is a way to explicitly tell Rollup which modules to split into separate chunks via the output.manualChunks option.

To use the code splitting feature to achieve the lazy dynamic loading (where some imported module(s) is only loaded after executing a function), we go back to the original example and modify src/main.js to load src/foo.js dynamically instead of statically:

js
// src/main.js
export default function () {
	import('./foo.js').then(({ default: foo }) => console.log(foo));
}

Rollup will use the dynamic import to create a separate chunk that is only loaded on demand. In order for Rollup to know where to place the second chunk, instead of passing the --file option we set a folder to output to with the --dir option:

shell
rollup src/main.js -f cjs -d dist

This will create a folder dist containing two files, main.js and chunk-[hash].js, where [hash] is a content based hash string. You can supply your own naming patterns by specifying the output.chunkFileNames and output.entryFileNames options.

You can still run your code as before with the same output, albeit a little slower as loading and parsing of ./foo.js will only commence once we call the exported function for the first time.

shell
node -e "require('./dist/main.js')()"

If we do not use the --dir option, Rollup will again print the chunks to stdout, adding comments to highlight the chunk boundaries:

js
//→ main.js:
'use strict';

function main() {
	Promise.resolve(require('./chunk-b8774ea3.js')).then(({ default: foo }) =>
		console.log(foo)
	);
}

module.exports = main;

//→ chunk-b8774ea3.js:
('use strict');

var foo = 'hello world!';

exports.default = foo;

This is useful if you want to load and parse expensive features only once they are used.

A different use for code-splitting is the ability to specify several entry points that share some dependencies. Again we extend our example to add a second entry point src/main2.js that statically imports src/foo.js just like we did in the original example:

js
// src/main2.js
import foo from './foo.js';
export default function () {
	console.log(foo);
}

If we supply both entry points to rollup, three chunks are created:

shell
rollup src/main.js src/main2.js -f cjs

will output

js
//→ main.js:
'use strict';

function main() {
	Promise.resolve(require('./chunk-b8774ea3.js')).then(({ default: foo }) =>
		console.log(foo)
	);
}

module.exports = main;

//→ main2.js:
('use strict');

var foo_js = require('./chunk-b8774ea3.js');

function main2() {
	console.log(foo_js.default);
}

module.exports = main2;

//→ chunk-b8774ea3.js:
('use strict');

var foo = 'hello world!';

exports.default = foo;

Notice how both entry points import the same shared chunk. Rollup will never duplicate code and instead create additional chunks to only ever load the bare minimum necessary. Again, passing the --dir option will write the files to disk.

You can build the same code for the browser via native ES modules, an AMD loader or SystemJS.

For example, with -f es for native modules:

shell
rollup src/main.js src/main2.js -f es -d dist
html
<!doctype html>
<script type="module">
	import main2 from './dist/main2.js';
	main2();
</script>

Or alternatively, for SystemJS with -f system:

shell
rollup src/main.js src/main2.js -f system -d dist

Install SystemJS via

shell
npm install --save-dev systemjs

And then load either or both entry points in an HTML page as needed:

html
<!doctype html>
<script src="node_modules/systemjs/dist/s.min.js"></script>
<script>
	System.import('./dist/main2.js').then(({ default: main }) => main());
</script>

See rollup-starter-code-splitting for an example on how to set up a web app that uses native ES modules on browsers that support them with a fallback to SystemJS if necessary.

Released under the MIT License.