When publishing a JavaScript library, we usually want to make it available to as many people as possible to maximize the library’s usefulness and adoption. In that respect, it can be helpful to users to have the library available in their preferred module format - CommonJS, AMD, ES6, etc. This article shows how to use webpack to automatically export multiple formats without having to maintain them separately.

Maybe you know the situation: You would like to pull a helpful JavaScript library into your client-side project, but it consists entirely of CommonJS modules, and you cannot or do not want to add an additional translation step into your build process to make it browser-compatible. Depending on the project, it would be more convenient to access the library through a single global variable. Or maybe this project is using RequireJS, so we would like to pull in an AMD module.

If we switch the perspective now, and think as library authors, how can we provide several ways of using our library, without causing additional maintenance overhead? At trivago, we use webpack to help us with that, because it has this functionality basically built in - you just have to configure it accordingly.

webpack configuration

The key to exporting our library in multiple formats is the libraryTarget option in the output configuration section. The following code example configures webpack to output a “global variable” version of our library:

var config = { entry : './index.js' , output : { path : './dist/' , filename : 'ourLibrary.var.js' , library : 'OurLibrary' libraryTarget : 'var' }, // ...

The path and filename options determine where to generate the file. We use the library option to specify a variable name for the library in the export. In the example, the name is set to “OurLibrary”, which will result in output code like:

var OurLibrary = ...

Finally, the libraryTarget option specifies the type of export. Possible options are:

var : The module is exported by setting a variable, as just mentioned. This is the default setting.

: The module is exported by setting a variable, as just mentioned. This is the default setting. this : The module is exported by setting this["OurLibrary"] = ... .

: The module is exported by setting . commonjs : Export by setting exports["OurLibrary"] = ...

: Export by setting commonjs2 : Export by setting module.exports = ...

: Export by setting amd : Export as an AMD module.

: Export as an AMD module. umd : Export as a UMD module.

See the webpack documentation for more information.

Varying the build configuration

So let us say we want to export our library as a global variable ( var ), as a CommonJS module ( commonjs2 ), and as AMD and UMD modules ( amd and umd , respectively). We prefer commonjs2 to commonjs since its output is more practical to include. Since we have multiple build targets, we will need multiple webpack compiler runs (example from the webpack documentation). So, instead of exporting a single webpack configuration, we export an array of configurations:

module exports = [ createConfig ( 'var' ), createConfig ( 'commonjs2' ), createConfig ( 'amd' ), createConfig ( 'umd' ) ];

The createConfig function might look something like the following:

function createConfig ( target ) { return { entry : './index.js' , output : { path : './dist/' , filename : 'ourLibrary.' + target + '.js' , library : 'OurLibrary' , libraryTarget : target }, // ... }; }

The only difference to the first code snippet in the article (where we hard-coded var as the libraryTarget ) is that we now pass a variable to webpack’s libraryTarget option, and also use this variable to generate the target filename. We will get 4 output files from this configuration:

And that’s basically it. A developer using our library can now choose from multiple formats. If she wants our library as a global variable, she can pull the var file in:

< script src = "assets/js/ourLibrary.var.js" ></ script >

Somebody using CommonJS can access our code using require , provided that the environment is set up correctly:

var ourLib = require ( 'ourLibrary' );

Build time considerations

Now, some of you might say: “Ok, so I’m running webpack 4 times instead of just once, so I end up with a quadrupled build time, more or less. That’s not good.” And you’re right, the build time will increase. But: We can work around that by using parallel-webpack, which can distribute the compilation work to multiple processor cores.

First, we install parallel-webpack. On the command line, go to your project directory, and type:

npm install parallel-webpack --save-dev

Instead of creating the array to be exported manually, we will use the createVariants function of parallel-webpack:

var createVariants = require ( 'parallel-webpack' ). createVariants ; // ... // At the end of the file: module . exports = createVariants ({ target : [ 'var' , 'commonjs2' , 'umd' , 'amd' ] }, createConfig );

The createVariants function receives an object containing the options that vary from build to build, along with all the possible values. In our simple case, we have only one option, target , and its values are the four export formats.

The second parameter to createVariants is a callback function ( createConfig ) which will be called once for every generated parameter combination. At every invocation, the parameter combination is passed to createConfig as an options object. As our existing createConfig function is expecting the target format as a single string parameter, we have to adapt it slightly:

function createConfig ( options ) { return { entry : './index.js' , output : { path : './dist/' , filename : 'ourLibrary.' + options . target + '.js' , library : 'OurLibrary' , libraryTarget : options . target }, // ... }; }

That is already all. If we now run webpack to build our library, the individual builds will be distributed to separate CPU cores (if available) to make use of parallelism. For more information on parallel-webpack usage, see also out related tech blog article.

Conclusion

The number of relevant JavaScript module formats might decrease in future, with more projects ultimately switching to ES6 modules. However, for the time being, we can still increase the number of users of our JavaScript library by providing not one, but several final formats in which it is offered for consumption. webpack has pre-defined functionality that lets us do exactly that very easily, and that shows once more its flexibility and usefulness.