This section covers all methods available in code compiled with webpack. When using webpack to bundle your application, you can pick from a variety of module syntax styles including ES6, CommonJS, and AMD.
While webpack supports multiple module syntaxes, we recommend following a single syntax for consistency and to avoid odd behaviors/bugs. Here's one example of mixing ES6 and CommonJS, however there are surely others.
Version 2 of webpack supports ES6 module syntax natively, meaning you can use import
and export
without a tool like babel to handle this for you. Keep in mind that you will still probably need babel for other ES6+ features. The following methods are supported by webpack:
import
Statically import
the export
s of another module.
import MyModule from './my-module.js';
import { NamedExport } from './other-module.js';
The keyword here is statically. Normalimport
statement cannot be used dynamically within other logic or contain variables. See the spec for more information andimport()
below for dynamic usage.
export
Export anything as a default
or named export.
// Named exports
export var Count = 5;
export function Multiply(a, b) {
return a * b;
}
// Default export
export default {
// Some data...
}
import()
import('path/to/module') -> Promise
Dynamically load modules. Calls to import()
are treated as split points, meaning the requested module and it's children are split out into a separate chunk.
The ES2015 Loader spec definesimport()
as method to load ES2015 modules dynamically on runtime.
if ( module.hot ) {
import('lodash').then(_ => {
// Do something with lodash (a.k.a '_')...
})
}
This feature relies onPromise
internally. If you useimport()
with older browsers, remember to shimPromise
using a polyfill such as es6-promise or promise-polyfill.
The spec for import
doesn't allow control over the chunk's name or other properties as "chunks" are only a concept within webpack. Luckily webpack allows some special parameters via comments so as to not break the spec:
import(
/* webpackChunkName: "my-chunk-name" */
/* webpackMode: "lazy" */
'module'
);
webpackChunkName
: A name for the new chunk. Since webpack 2.6.0, the placeholders [index]
and [request]
are supported within the given string to an incremented number or the actual resolved filename respectively.
webpackMode
: Since webpack 2.6.0, different modes for resolving dynamic imports can be specified. The following options are supported:
"lazy"
(default): Generates a lazy-loadable chunk for each import()
ed module."lazy-once"
: Generates a single lazy-loadable chunk that can satisfy all calls to import()
. The chunk will be fetched on the first call to import()
, and subsequent calls to import()
will use the same network response. Note that this only makes sense in the case of a partially dynamic statement, e.g. import(`./locales/${language}.json`)
, where there are multiple module paths that could potentially be requested."eager"
: Generates no extra chunk. All modules are included in the current chunk and no additional network requests are made. A Promise
is still returned but is already resolved. In contrast to a static import, the module isn't executed until the call to import()
is made."weak"
: Tries to load the module if the module function has already been loaded in some other way (i. e. another chunk imported it or a script containing the module was loaded). A Promise
is still returned but, only successfully resolves if the chunks are already on the client. If the module is not available, the Promise
is rejected. A network request will never be performed. This is useful for universal rendering when required chunks are always manually served in initial requests (embedded within the page), but not in cases where app navigation will trigger an import not initially served.Note that both options can be combined like so/* webpackMode: "lazy-once", webpackChunkName: "all-i18n-data" */
. This is parsed as a JSON5 object without curly brackets.
Fully dynamic statements, such asimport(foo)
, will fail because webpack requires at least some file location information. This is becausefoo
could potentially be any path to any file in your system or project. Theimport()
must contain at least some information about where the module is located, so bundling can be limited to a specific directory or set of files.
Every module that could potentially be requested on animport()
call is included. For example,import(`./locale/${language}.json`)
will cause every.json
file in the./locale
directory to be bundled into the new chunk. At run time, when the variablelanguage
has been computed, any file likeenglish.json
orgerman.json
will be available for consumption.
The use ofSystem.import
in webpack did not fit the proposed spec, so it was deprecated in webpack 2.1.0-beta.28 in favor ofimport()
.
The goal of CommonJS is to specify an ecosystem for JavaScript outside the browser. The following CommonJS methods are supported by webpack:
require
require(dependency: String)
Synchronously retrieve the exports from another module. The compiler will ensure that the dependency is available in the output bundle.
var $ = require("jquery");
var myModule = require("my-module");
Using it asynchronously may not have the expected effect.
require.resolve
require.resolve(dependency: String)
Synchronously retrieve a module's ID. The compiler will ensure that the dependency is available in the output bundle. See module.id
for more information.
Module ID is a number in webpack (in contrast to NodeJS where it is a string -- the filename).
require.cache
Multiple requires to the same module result in only one module execution and only one export. Therefore a cache in the runtime exists. Removing values from this cache cause new module execution and a new export.
This is only needed in rare cases for compatibility!
var d1 = require("dependency");
require("dependency") === d1
delete require.cache[require.resolve("dependency")];
require("dependency") !== d1
// in file.js
require.cache[module.id] === module
require("./file.js") === module.exports
delete require.cache[module.id];
require.cache[module.id] === undefined
require("./file.js") !== module.exports // in theory; in praxis this causes a stack overflow
require.cache[module.id] !== module
require.ensure
require.ensure()
is specific to webpack and superseded byimport()
.
require.ensure(dependencies: String[], callback: function(require), errorCallback: function(error), chunkName: String)
Split out the given dependencies
to a separate bundle that that will be loaded asynchronously. When using CommonJS module syntax, this is the only way to dynamically load dependencies. Meaning, this code can be run within execution, only loading the dependencies
if certain conditions are met.
This feature relies onPromise
internally. If you userequire.ensure
with older browsers, remember to shimPromise
using a polyfill such as es6-promise or promise-polyfill.
var a = require('normal-dep');
if ( module.hot ) {
require.ensure(['b'], function(require) {
var c = require('c');
// Do something special...
});
}
The following parameters are supported in the order specified above:
dependencies
: An array of strings declaring all modules required for the code in the callback
to execute.callback
: A function that webpack will execute once the dependencies are loaded. An implementation of the require
function is sent as a parameter to this function. The function body can use this to further require()
modules it needs for execution.errorCallback
: A function that is executed when webpack fails to load the dependencies.chunkName
: A name given to the chunk created by this particular require.ensure()
. By passing the same chunkName
to various require.ensure()
calls, we can combine their code into a single chunk, resulting in only one bundle that the browser must load.Although the implementation ofrequire
is passed as an argument to thecallback
function, using an arbitrary name e.g.require.ensure([], function(request) { request('someModule'); })
isn't handled by webpack's static parser. Userequire
instead, e.g.require.ensure([], function(require) { require('someModule'); })
.
Asynchronous Module Definition (AMD) is a JavaScript specification that defines an interface for writing and loading modules. The following AMD methods are supported by webpack:
define
(with factory)define([name: String], [dependencies: String[]], factoryMethod: function(...))
If dependencies
are provided, factoryMethod
will be called with the exports of each dependency (in the same order). If dependencies
are not provided, factoryMethod
is called with require
, exports
and module
(for compatibility!). If this function returns a value, this value is exported by the module. The compiler ensures that each dependency is available.
Note that webpack ignores thename
argument.
define(['jquery', 'my-module'], function($, myModule) {
// Do something with $ and myModule...
// Export a function
return function doSomething() {
// ...
};
});
This CANNOT be used in an asynchronous function.
define
(with value)define(value: !Function)
This will simply export the provided value
. The value
here can be anything except a function.
define({
answer: 42
});
This CANNOT be used in an async function.
require
(amd-version)require(dependencies: String[], [callback: function(...)])
Similar to require.ensure
, this will split the given dependencies
into a separate bundle that will be loaded asynchronously. The callback
will be called with the exports of each dependency in the dependencies
array.
This feature relies onPromise
internally. If you use AMD with older browsers (e.g. Internet Explorer 11), remember to shimPromise
using a polyfill such as es6-promise or promise-polyfill.
require(['b'], function(b) {
var c = require("c");
});
There is no option to provide a chunk name.
The internal LabeledModulesPlugin
enables you to use the following methods for exporting and requiring within your modules:
export
labelExport the given value
. The label can occur before a function declaration or a variable declaration. The function name or variable name is the identifier under which the value is exported.
export: var answer = 42;
export: function method(value) {
// Do something...
};
Using it in an async function may not have the expected effect.
require
labelMake all exports from the dependency available in the current scope. The require
label can occur before a string. The dependency must export values with the export
label. CommonJS or AMD modules cannot be consumed.
some-dependency.js
export: var answer = 42;
export: function method(value) {
// Do something...
};
require: 'some-dependency';
console.log(answer);
method(...);
Aside from the module syntaxes described above, webpack also allows a few custom, webpack-specific methods:
require.context
require.context(directory:String, includeSubdirs:Boolean /* optional, default true */, filter:RegExp /* optional */)
Specify a whole group of dependencies using a path to the directory
, an option to includeSubdirs
, and a filter
for more fine grained control of the modules included. These can then be easily resolved later on:
var context = require.context('components', true, /\.html$/);
var componentA = context.resolve('componentA');
require.include
require.include(dependency: String)
Include a dependency
without executing it. This can be used for optimizing the position of a module in the output chunks.
require.include('a');
require.ensure(['a', 'b'], function(require) { /* ... */ });
require.ensure(['a', 'c'], function(require) { /* ... */ });
This will result in following output:
file.js
and a
b
c
Without require.include('a')
it would be duplicated in both anonymous chunks.
require.resolveWeak
Similar to require.resolve
, but this won't pull the module
into the bundle. It's what is considered a "weak" dependency.
if(__webpack_modules__[require.resolveWeak('module')]) {
// Do something when module is available...
}
if(require.cache[require.resolveWeak('module')]) {
// Do something when module was loaded before...
}
// You can perform dynamic resolves ("context")
// just as with other require/import methods.
const page = 'Foo';
__webpack_modules__[require.resolveWeak(`./page/${page}`)]
require.resolveWeak
is the foundation of universal rendering (SSR + Code Splitting), as used in packages such as react-universal-component. It allows code to render synchronously on both the server and initial page-loads on the client. It requires that chunks are manually served or somehow available. It's able to require modules without indicating they should be bundled into a chunk. It's used in conjunction withimport()
which takes over when user navigation triggers additional imports.