Node.js v20.6.1 documentation


Table of contents

Modules: ECMAScript modules#

Stability: 2 - Stable

Introduction#

ECMAScript modules are the official standard format to package JavaScript code for reuse. Modules are defined using a variety of import and export statements.

The following example of an ES module exports a function:

// addTwo.mjs
function addTwo(num) {
  return num + 2;
}

export { addTwo }; 

The following example of an ES module imports the function from addTwo.mjs:

// app.mjs
import { addTwo } from './addTwo.mjs';

// Prints: 6
console.log(addTwo(4)); 

Node.js fully supports ECMAScript modules as they are currently specified and provides interoperability between them and its original module format, CommonJS.

Enabling#

Node.js has two module systems: CommonJS modules and ECMAScript modules.

Authors can tell Node.js to use the ECMAScript modules loader via the .mjs file extension, the package.json "type" field, or the --input-type flag. Outside of those cases, Node.js will use the CommonJS module loader. See Determining module system for more details.

Packages#

This section was moved to Modules: Packages.

import Specifiers#

Terminology#

The specifier of an import statement is the string after the from keyword, e.g. 'node:path' in import { sep } from 'node:path'. Specifiers are also used in export from statements, and as the argument to an import() expression.

There are three types of specifiers:

  • Relative specifiers like './startup.js' or '../config.mjs'. They refer to a path relative to the location of the importing file. The file extension is always necessary for these.

  • Bare specifiers like 'some-package' or 'some-package/shuffle'. They can refer to the main entry point of a package by the package name, or a specific feature module within a package prefixed by the package name as per the examples respectively. Including the file extension is only necessary for packages without an "exports" field.

  • Absolute specifiers like 'file:///opt/nodejs/config.js'. They refer directly and explicitly to a full path.

Bare specifier resolutions are handled by the Node.js module resolution and loading algorithm. All other specifier resolutions are always only resolved with the standard relative URL resolution semantics.

Like in CommonJS, module files within packages can be accessed by appending a path to the package name unless the package's package.json contains an "exports" field, in which case files within packages can only be accessed via the paths defined in "exports".

For details on these package resolution rules that apply to bare specifiers in the Node.js module resolution, see the packages documentation.

Mandatory file extensions#

A file extension must be provided when using the import keyword to resolve relative or absolute specifiers. Directory indexes (e.g. './startup/index.js') must also be fully specified.

This behavior matches how import behaves in browser environments, assuming a typically configured server.

URLs#

ES modules are resolved and cached as URLs. This means that special characters must be percent-encoded, such as # with %23 and ? with %3F.

file:, node:, and data: URL schemes are supported. A specifier like 'https://example.com/app.js' is not supported natively in Node.js unless using a custom HTTPS loader.

file: URLs#

Modules are loaded multiple times if the import specifier used to resolve them has a different query or fragment.

import './foo.mjs?query=1'; // loads ./foo.mjs with query of "?query=1"
import './foo.mjs?query=2'; // loads ./foo.mjs with query of "?query=2" 

The volume root may be referenced via /, //, or file:///. Given the differences between URL and path resolution (such as percent encoding details), it is recommended to use url.pathToFileURL when importing a path.

data: imports#

data: URLs are supported for importing with the following MIME types:

  • text/javascript for ES modules
  • application/json for JSON
  • application/wasm for Wasm
import 'data:text/javascript,console.log("hello!");';
import _ from 'data:application/json,"world!"' assert { type: 'json' }; 

data: URLs only resolve bare specifiers for builtin modules and absolute specifiers. Resolving relative specifiers does not work because data: is not a special scheme. For example, attempting to load ./foo from data:text/javascript,import "./foo"; fails to resolve because there is no concept of relative resolution for data: URLs.

node: imports#

node: URLs are supported as an alternative means to load Node.js builtin modules. This URL scheme allows for builtin modules to be referenced by valid absolute URL strings.

import fs from 'node:fs/promises'; 

Import assertions#

Stability: 1 - Experimental

The Import Assertions proposal adds an inline syntax for module import statements to pass on more information alongside the module specifier.

import fooData from './foo.json' assert { type: 'json' };

const { default: barData } =
  await import('./bar.json', { assert: { type: 'json' } }); 

Node.js supports the following type values, for which the assertion is mandatory:

Assertion typeNeeded for
'json'JSON modules

Builtin modules#

Core modules provide named exports of their public API. A default export is also provided which is the value of the CommonJS exports. The default export can be used for, among other things, modifying the named exports. Named exports of builtin modules are updated only by calling module.syncBuiltinESMExports().

import EventEmitter from 'node:events';
const e = new EventEmitter(); 
import { readFile } from 'node:fs';
readFile('./foo.txt', (err, source) => {
  if (err) {
    console.error(err);
  } else {
    console.log(source);
  }
}); 
import fs, { readFileSync } from 'node:fs';
import { syncBuiltinESMExports } from 'node:module';
import { Buffer } from 'node:buffer';

fs.readFileSync = () => Buffer.from('Hello, ESM');
syncBuiltinESMExports();

fs.readFileSync === readFileSync; 

import() expressions#

Dynamic import() is supported in both CommonJS and ES modules. In CommonJS modules it can be used to load ES modules.

import.meta#

The import.meta meta property is an Object that contains the following properties.

import.meta.url#

  • <string> The absolute file: URL of the module.

This is defined exactly the same as it is in browsers providing the URL of the current module file.

This enables useful patterns such as relative file loading:

import { readFileSync } from 'node:fs';
const buffer = readFileSync(new URL('./data.proto', import.meta.url)); 

import.meta.resolve(specifier)#

Stability: 1.2 - Release candidate

  • specifier <string> The module specifier to resolve relative to the current module.
  • Returns: <string> The absolute (file:) URL string for the resolved module.

import.meta.resolve is a module-relative resolution function scoped to each module, returning the URL string.

const dependencyAsset = import.meta.resolve('component-lib/asset.css');
// file:///app/node_modules/component-lib/asset.css 

All features of the Node.js module resolution are supported. Dependency resolutions are subject to the permitted exports resolutions within the package.

import.meta.resolve('./dep', import.meta.url);
// file:///app/dep 

Caveat This can result in synchronous file-system operations, which can impact performance similarly to require.resolve.

Previously, Node.js implemented an asynchronous resolver which also permitted a second contextual argument. The implementation has since been updated to be synchronous, with the second contextual parent argument still accessible behind the --experimental-import-meta-resolve flag:

  • parent <string> | <URL> An optional absolute parent module URL to resolve from.

Interoperability with CommonJS#

import statements#

An import statement can reference an ES module or a CommonJS module. import statements are permitted only in ES modules, but dynamic import() expressions are supported in CommonJS for loading ES modules.

When importing CommonJS modules, the module.exports object is provided as the default export. Named exports may be available, provided by static analysis as a convenience for better ecosystem compatibility.

require#

The CommonJS module require always treats the files it references as CommonJS.

Using require to load an ES module is not supported because ES modules have asynchronous execution. Instead, use import() to load an ES module from a CommonJS module.

CommonJS Namespaces#

CommonJS modules consist of a module.exports object which can be of any type.

When importing a CommonJS module, it can be reliably imported using the ES module default import or its corresponding sugar syntax:

import { default as cjs } from 'cjs';

// The following import statement is "syntax sugar" (equivalent but sweeter)
// for `{ default as cjsSugar }` in the above import statement:
import cjsSugar from 'cjs';

console.log(cjs);
console.log(cjs === cjsSugar);
// Prints:
//   <module.exports>
//   true 

The ECMAScript Module Namespace representation of a CommonJS module is always a namespace with a default export key pointing to the CommonJS module.exports value.

This Module Namespace Exotic Object can be directly observed either when using import * as m from 'cjs' or a dynamic import:

import * as m from 'cjs';
console.log(m);
console.log(m === await import('cjs'));
// Prints:
//   [Module] { default: <module.exports> }
//   true 

For better compatibility with existing usage in the JS ecosystem, Node.js in addition attempts to determine the CommonJS named exports of every imported CommonJS module to provide them as separate ES module exports using a static analysis process.

For example, consider a CommonJS module written:

// cjs.cjs
exports.name = 'exported'; 

The preceding module supports named imports in ES modules:

import { name } from './cjs.cjs';
console.log(name);
// Prints: 'exported'

import cjs from './cjs.cjs';
console.log(cjs);
// Prints: { name: 'exported' }

import * as m from './cjs.cjs';
console.log(m);
// Prints: [Module] { default: { name: 'exported' }, name: 'exported' } 

As can be seen from the last example of the Module Namespace Exotic Object being logged, the name export is copied off of the module.exports object and set directly on the ES module namespace when the module is imported.

Live binding updates or new exports added to module.exports are not detected for these named exports.

The detection of named exports is based on common syntax patterns but does not always correctly detect named exports. In these cases, using the default import form described above can be a better option.

Named exports detection covers many common export patterns, reexport patterns and build tool and transpiler outputs. See cjs-module-lexer for the exact semantics implemented.

Differences between ES modules and CommonJS#

No require, exports, or module.exports#

In most cases, the ES module import can be used to load CommonJS modules.

If needed, a require function can be constructed within an ES module using module.createRequire().

No __filename or __dirname#

These CommonJS variables are not available in ES modules.

__filename and __dirname use cases can be replicated via import.meta.url.

No Addon Loading#

Addons are not currently supported with ES module imports.

They can instead be loaded with module.createRequire() or process.dlopen.

No require.resolve#

Relative resolution can be handled via new URL('./local', import.meta.url).

For a complete require.resolve replacement, there is the import.meta.resolve API.

Alternatively module.createRequire() can be used.

No NODE_PATH#

NODE_PATH is not part of resolving import specifiers. Please use symlinks if this behavior is desired.

No require.extensions#

require.extensions is not used by import. The expectation is that loader hooks can provide this workflow in the future.

No require.cache#

require.cache is not used by import as the ES module loader has its own separate cache.

JSON modules#

Stability: 1 - Experimental

JSON files can be referenced by import:

import packageConfig from './package.json' assert { type: 'json' }; 

The assert { type: 'json' } syntax is mandatory; see Import Assertions.

The imported JSON only exposes a default export. There is no support for named exports. A cache entry is created in the CommonJS cache to avoid duplication. The same object is returned in CommonJS if the JSON module has already been imported from the same path.

Wasm modules#

Stability: 1 - Experimental

Importing WebAssembly modules is supported under the --experimental-wasm-modules flag, allowing any .wasm files to be imported as normal modules while also supporting their module imports.

This integration is in line with the ES Module Integration Proposal for WebAssembly.

For example, an index.mjs containing:

import * as M from './module.wasm';
console.log(M); 

executed under:

node --experimental-wasm-modules index.mjs 

would provide the exports interface for the instantiation of module.wasm.

Top-level await#

The await keyword may be used in the top level body of an ECMAScript module.

Assuming an a.mjs with

export const five = await Promise.resolve(5); 

And a b.mjs with

import { five } from './a.mjs';

console.log(five); // Logs `5` 
node b.mjs # works 

If a top level await expression never resolves, the node process will exit with a 13 status code.

import { spawn } from 'node:child_process';
import { execPath } from 'node:process';

spawn(execPath, [
  '--input-type=module',
  '--eval',
  // Never-resolving Promise:
  'await new Promise(() => {})',
]).once('exit', (code) => {
  console.log(code); // Logs `13`
}); 

HTTPS and HTTP imports#

Stability: 1 - Experimental

Importing network based modules using https: and http: is supported under the --experimental-network-imports flag. This allows web browser-like imports to work in Node.js with a few differences due to application stability and security concerns that are different when running in a privileged environment instead of a browser sandbox.

Imports are limited to HTTP/1#

Automatic protocol negotiation for HTTP/2 and HTTP/3 is not yet supported.

HTTP is limited to loopback addresses#

http: is vulnerable to man-in-the-middle attacks and is not allowed to be used for addresses outside of the IPv4 address 127.0.0.0/8 (127.0.0.1 to 127.255.255.255) and the IPv6 address ::1. Support for http: is intended to be used for local development.

Authentication is never sent to the destination server.#

Authorization, Cookie, and Proxy-Authorization headers are not sent to the server. Avoid including user info in parts of imported URLs. A security model for safely using these on the server is being worked on.

CORS is never checked on the destination server#

CORS is designed to allow a server to limit the consumers of an API to a specific set of hosts. This is not supported as it does not make sense for a server-based implementation.

Cannot load non-network dependencies#

These modules cannot access other modules that are not over http: or https:. To still access local modules while avoiding the security concern, pass in references to the local dependencies:

// file.mjs
import worker_threads from 'node:worker_threads';
import { configure, resize } from 'https://example.com/imagelib.mjs';
configure({ worker_threads }); 
// https://example.com/imagelib.mjs
let worker_threads;
export function configure(opts) {
  worker_threads = opts.worker_threads;
}
export function resize(img, size) {
  // Perform resizing in worker_thread to avoid main thread blocking
} 

Network-based loading is not enabled by default#

For now, the --experimental-network-imports flag is required to enable loading resources over http: or https:. In the future, a different mechanism will be used to enforce this. Opt-in is required to prevent transitive dependencies inadvertently using potentially mutable state that could affect reliability of Node.js applications.

Loaders#

Stability: 1 - Experimental

This API is currently being redesigned and will still change.

To customize the default module resolution, loader hooks can optionally be provided via a --experimental-loader ./loader-name.mjs argument to Node.js.

When hooks are used they apply to each subsequent loader, the entry point, and all import calls. They won't apply to require calls; those still follow CommonJS rules.

Loaders follow the pattern of --require:

node \
  --experimental-loader unpkg \
  --experimental-loader http-to-https \
  --experimental-loader cache-buster 

These are called in the following sequence: cache-buster calls http-to-https which calls unpkg.

Hooks#

Hooks are part of a chain, even if that chain consists of only one custom (user-provided) hook and the default hook, which is always present. Hook functions nest: each one must always return a plain object, and chaining happens as a result of each function calling next<hookName>(), which is a reference to the subsequent loader's hook.

A hook that returns a value lacking a required property triggers an exception. A hook that returns without calling next<hookName>() and without returning shortCircuit: true also triggers an exception. These errors are to help prevent unintentional breaks in the chain.

Hooks are run in a separate thread, isolated from the main. That means it is a different realm. The hooks thread may be terminated by the main thread at any time, so do not depend on asynchronous operations (like console.log) to complete.

initialize()#

The loaders API is being redesigned. This hook may disappear or its signature may change. Do not rely on the API described below.

  • data <any> The data from register(loader, import.meta.url, { data }).
  • Returns: <any> The data to be returned to the caller of register.

The initialize hook provides a way to define a custom function that runs in the loader's thread when the loader is initialized. Initialization happens when the loader is registered via register or registered via the --experimental-loader command line option.

This hook can send and receive data from a register invocation, including ports and other transferrable objects. The return value of initialize must be either:

  • undefined,
  • something that can be posted as a message between threads (e.g. the input to port.postMessage),
  • a Promise resolving to one of the aforementioned values.

Loader code:

// In the below example this file is referenced as
// '/path-to-my-loader.js'

export async function initialize({ number, port }) {
  port.postMessage(`increment: ${number + 1}`);
  return 'ok';
} 

Caller code:

import assert from 'node:assert';
import { register } from 'node:module';
import { MessageChannel } from 'node:worker_threads';

// This example showcases how a message channel can be used to
// communicate between the main (application) thread and the loader
// running on the loaders thread, by sending `port2` to the loader.
const { port1, port2 } = new MessageChannel();

port1.on('message', (msg) => {
  assert.strictEqual(msg, 'increment: 2');
});

const result = register('/path-to-my-loader.js', {
  parentURL: import.meta.url,
  data: { number: 1, port: port2 },
  transferList: [port2],
});

assert.strictEqual(result, 'ok'); 
resolve(specifier, context, nextResolve)#

The loaders API is being redesigned. This hook may disappear or its signature may change. Do not rely on the API described below.

  • specifier <string>
  • context <Object>
    • conditions <string[]> Export conditions of the relevant package.json
    • importAssertions <Object> An object whose key-value pairs represent the assertions for the module to import
    • parentURL <string> | <undefined> The module importing this one, or undefined if this is the Node.js entry point
  • nextResolve <Function> The subsequent resolve hook in the chain, or the Node.js default resolve hook after the last user-supplied resolve hook
  • Returns: <Object> | <Promise>
    • format <string> | <null> | <undefined> A hint to the load hook (it might be ignored) 'builtin' | 'commonjs' | 'json' | 'module' | 'wasm'
    • importAssertions <Object> | <undefined> The import assertions to use when caching the module (optional; if excluded the input will be used)
    • shortCircuit <undefined> | <boolean> A signal that this hook intends to terminate the chain of resolve hooks. Default: false
    • url <string> The absolute URL to which this input resolves

Caveat Despite support for returning promises and async functions, calls to resolve may block the main thread which can impact performance.

The resolve hook chain is responsible for telling Node.js where to find and how to cache a given import statement or expression. It can optionally return its format (such as 'module') as a hint to the load hook. If a format is specified, the load hook is ultimately responsible for providing the final format value (and it is free to ignore the hint provided by resolve); if resolve provides a format, a custom load hook is required even if only to pass the value to the Node.js default load hook.

Import type assertions are part of the cache key for saving loaded modules into the internal module cache. The resolve hook is responsible for returning an importAssertions object if the module should be cached with different assertions than were present in the source code.

The conditions property in context is an array of conditions for package exports conditions that apply to this resolution request. They can be used for looking up conditional mappings elsewhere or to modify the list when calling the default resolution logic.

The current package exports conditions are always in the context.conditions array passed into the hook. To guarantee default Node.js module specifier resolution behavior when calling defaultResolve, the context.conditions array passed to it must include all elements of the context.conditions array originally passed into the resolve hook.

export function resolve(specifier, context, nextResolve) {
  const { parentURL = null } = context;

  if (Math.random() > 0.5) { // Some condition.
    // For some or all specifiers, do some custom logic for resolving.
    // Always return an object of the form {url: <string>}.
    return {
      shortCircuit: true,
      url: parentURL ?
        new URL(specifier, parentURL).href :
        new URL(specifier).href,
    };
  }

  if (Math.random() < 0.5) { // Another condition.
    // When calling `defaultResolve`, the arguments can be modified. In this
    // case it's adding another value for matching conditional exports.
    return nextResolve(specifier, {
      ...context,
      conditions: [...context.conditions, 'another-condition'],
    });
  }

  // Defer to the next hook in the chain, which would be the
  // Node.js default resolve if this is the last user-specified loader.
  return nextResolve(specifier);
} 
load(url, context, nextLoad)#

The loaders API is being redesigned. This hook may disappear or its signature may change. Do not rely on the API described below.

In a previous version of this API, this was split across 3 separate, now deprecated, hooks (getFormat, getSource, and transformSource).

The load hook provides a way to define a custom method of determining how a URL should be interpreted, retrieved, and parsed. It is also in charge of validating the import assertion.

The final value of format must be one of the following:

formatDescriptionAcceptable types for source returned by load
'builtin'Load a Node.js builtin moduleNot applicable
'commonjs'Load a Node.js CommonJS module{ string, ArrayBuffer, TypedArray, null, undefined }
'json'Load a JSON file{ string, ArrayBuffer, TypedArray }
'module'Load an ES module{ string, ArrayBuffer, TypedArray }
'wasm'Load a WebAssembly module{ ArrayBuffer, TypedArray }

The value of source is ignored for type 'builtin' because currently it is not possible to replace the value of a Node.js builtin (core) module.

The value of source can be omitted for type 'commonjs'. When a source is provided, all require calls from this module will be processed by the ESM loader with registered resolve and load hooks; all require.resolve calls from this module will be processed by the ESM loader with registered resolve hooks; require.extensions and monkey-patching on the CommonJS module loader will not apply. If source is undefined or null, it will be handled by the CommonJS module loader and require/require.resolve calls will not go through the registered hooks. This behavior for nullish source is temporary — in the future, nullish source will not be supported.

The Node.js own load implementation, which is the value of next for the last loader in the load chain, returns null for source when format is 'commonjs' for backward compatibility. Here is an example loader that would opt-in to using the non-default behavior:

import { readFile } from 'node:fs/promises';

export async function load(url, context, nextLoad) {
  const result = await nextLoad(url, context);
  if (result.format === 'commonjs') {
    result.source ??= await readFile(new URL(result.responseURL ?? url));
  }
  return result;
} 

Caveat: The ESM load hook and namespaced exports from CommonJS modules are incompatible. Attempting to use them together will result in an empty object from the import. This may be addressed in the future.

These types all correspond to classes defined in ECMAScript.

If the source value of a text-based format (i.e., 'json', 'module') is not a string, it is converted to a string using util.TextDecoder.

The load hook provides a way to define a custom method for retrieving the source code of an ES module specifier. This would allow a loader to potentially avoid reading files from disk. It could also be used to map an unrecognized format to a supported one, for example yaml to module.

export async function load(url, context, nextLoad) {
  const { format } = context;

  if (Math.random() > 0.5) { // Some condition
    /*
      For some or all URLs, do some custom logic for retrieving the source.
      Always return an object of the form {
        format: <string>,
        source: <string|buffer>,
      }.
    */
    return {
      format,
      shortCircuit: true,
      source: '...',
    };
  }

  // Defer to the next hook in the chain.
  return nextLoad(url);
} 

In a more advanced scenario, this can also be used to transform an unsupported source to a supported one (see Examples below).

globalPreload()#

This hook will be removed in a future version. Use initialize instead. When a loader has an initialize export, globalPreload will be ignored.

In a previous version of this API, this hook was named getGlobalPreloadCode.

Sometimes it might be necessary to run some code inside of the same global scope that the application runs in. This hook allows the return of a string that is run as a sloppy-mode script on startup.

Similar to how CommonJS wrappers work, the code runs in an implicit function scope. The only argument is a require-like function that can be used to load builtins like "fs": getBuiltin(request: string).

If the code needs more advanced require features, it has to construct its own require using module.createRequire().

export function globalPreload(context) {
  return `\
globalThis.someInjectedProperty = 42;
console.log('I just set some globals!');

const { createRequire } = getBuiltin('module');
const { cwd } = getBuiltin('process');

const require = createRequire(cwd() + '/<preload>');
// [...]
`;
} 

In order to allow communication between the application and the loader, another argument is provided to the preload code: port. This is available as a parameter to the loader hook and inside of the source text returned by the hook. Some care must be taken in order to properly call port.ref() and port.unref() to prevent a process from being in a state where it won't close normally.

/**
 * This example has the application context send a message to the loader
 * and sends the message back to the application context
 */
export function globalPreload({ port }) {
  port.onmessage = (evt) => {
    port.postMessage(evt.data);
  };
  return `\
    port.postMessage('console.log("I went to the Loader and back");');
    port.onmessage = (evt) => {
      eval(evt.data);
    };
  `;
} 

Examples#

The various loader hooks can be used together to accomplish wide-ranging customizations of the Node.js code loading and evaluation behaviors.

HTTPS loader#

In current Node.js, specifiers starting with https:// are experimental (see HTTPS and HTTP imports).

The loader below registers hooks to enable rudimentary support for such specifiers. While this may seem like a significant improvement to Node.js core functionality, there are substantial downsides to actually using this loader: performance is much slower than loading files from disk, there is no caching, and there is no security.

// https-loader.mjs
import { get } from 'node:https';

export function load(url, context, nextLoad) {
  // For JavaScript to be loaded over the network, we need to fetch and
  // return it.
  if (url.startsWith('https://')) {
    return new Promise((resolve, reject) => {
      get(url, (res) => {
        let data = '';
        res.setEncoding('utf8');
        res.on('data', (chunk) => data += chunk);
        res.on('end', () => resolve({
          // This example assumes all network-provided JavaScript is ES module
          // code.
          format: 'module',
          shortCircuit: true,
          source: data,
        }));
      }).on('error', (err) => reject(err));
    });
  }

  // Let Node.js handle all other URLs.
  return nextLoad(url);
} 
// main.mjs
import { VERSION } from 'https://coffeescript.org/browser-compiler-modern/coffeescript.js';

console.log(VERSION); 

With the preceding loader, running node --experimental-loader ./https-loader.mjs ./main.mjs prints the current version of CoffeeScript per the module at the URL in main.mjs.

Transpiler loader#

Sources that are in formats Node.js doesn't understand can be converted into JavaScript using the load hook.

This is less performant than transpiling source files before running Node.js; a transpiler loader should only be used for development and testing purposes.

// coffeescript-loader.mjs
import { readFile } from 'node:fs/promises';
import { dirname, extname, resolve as resolvePath } from 'node:path';
import { cwd } from 'node:process';
import { fileURLToPath, pathToFileURL } from 'node:url';
import CoffeeScript from 'coffeescript';

const baseURL = pathToFileURL(`${cwd()}/`).href;

export async function load(url, context, nextLoad) {
  if (extensionsRegex.test(url)) {
    // Now that we patched resolve to let CoffeeScript URLs through, we need to
    // tell Node.js what format such URLs should be interpreted as. Because
    // CoffeeScript transpiles into JavaScript, it should be one of the two
    // JavaScript formats: 'commonjs' or 'module'.

    // CoffeeScript files can be either CommonJS or ES modules, so we want any
    // CoffeeScript file to be treated by Node.js the same as a .js file at the
    // same location. To determine how Node.js would interpret an arbitrary .js
    // file, search up the file system for the nearest parent package.json file
    // and read its "type" field.
    const format = await getPackageType(url);
    // When a hook returns a format of 'commonjs', `source` is ignored.
    // To handle CommonJS files, a handler needs to be registered with
    // `require.extensions` in order to process the files with the CommonJS
    // loader. Avoiding the need for a separate CommonJS handler is a future
    // enhancement planned for ES module loaders.
    if (format === 'commonjs') {
      return {
        format,
        shortCircuit: true,
      };
    }

    const { source: rawSource } = await nextLoad(url, { ...context, format });
    // This hook converts CoffeeScript source code into JavaScript source code
    // for all imported CoffeeScript files.
    const transformedSource = coffeeCompile(rawSource.toString(), url);

    return {
      format,
      shortCircuit: true,
      source: transformedSource,
    };
  }

  // Let Node.js handle all other URLs.
  return nextLoad(url);
}

async function getPackageType(url) {
  // `url` is only a file path during the first iteration when passed the
  // resolved url from the load() hook
  // an actual file path from load() will contain a file extension as it's
  // required by the spec
  // this simple truthy check for whether `url` contains a file extension will
  // work for most projects but does not cover some edge-cases (such as
  // extensionless files or a url ending in a trailing space)
  const isFilePath = !!extname(url);
  // If it is a file path, get the directory it's in
  const dir = isFilePath ?
    dirname(fileURLToPath(url)) :
    url;
  // Compose a file path to a package.json in the same directory,
  // which may or may not exist
  const packagePath = resolvePath(dir, 'package.json');
  // Try to read the possibly nonexistent package.json
  const type = await readFile(packagePath, { encoding: 'utf8' })
    .then((filestring) => JSON.parse(filestring).type)
    .catch((err) => {
      if (err?.code !== 'ENOENT') console.error(err);
    });
  // Ff package.json existed and contained a `type` field with a value, voila
  if (type) return type;
  // Otherwise, (if not at the root) continue checking the next directory up
  // If at the root, stop and return false
  return dir.length > 1 && getPackageType(resolvePath(dir, '..'));
} 
# main.coffee
import { scream } from './scream.coffee'
console.log scream 'hello, world'

import { version } from 'node:process'
console.log "Brought to you by Node.js version #{version}" 
# scream.coffee
export scream = (str) -> str.toUpperCase() 

With the preceding loader, running node --experimental-loader ./coffeescript-loader.mjs main.coffee causes main.coffee to be turned into JavaScript after its source code is loaded from disk but before Node.js executes it; and so on for any .coffee, .litcoffee or .coffee.md files referenced via import statements of any loaded file.

"import map" loader#

The previous two loaders defined load hooks. This is an example of a loader that does its work via the resolve hook. This loader reads an import-map.json file that specifies which specifiers to override to another URL (this is a very simplistic implemenation of a small subset of the "import maps" specification).

// import-map-loader.js
import fs from 'node:fs/promises';

const { imports } = JSON.parse(await fs.readFile('import-map.json'));

export async function resolve(specifier, context, nextResolve) {
  if (Object.hasOwn(imports, specifier)) {
    return nextResolve(imports[specifier], context);
  }

  return nextResolve(specifier, context);
} 

Let's assume we have these files:

// main.js
import 'a-module'; 
// import-map.json
{
  "imports": {
    "a-module": "./some-module.js"
  }
} 
// some-module.js
console.log('some module!'); 

If you run node --experimental-loader ./import-map-loader.js main.js the output will be some module!.

Register loaders programmatically#

In addition to using the --experimental-loader option in the CLI, loaders can also be registered programmatically. You can find detailed information about this process in the documentation page for module.register().

Resolution and loading algorithm#

Features#

The default resolver has the following properties:

  • FileURL-based resolution as is used by ES modules
  • Relative and absolute URL resolution
  • No default extensions
  • No folder mains
  • Bare specifier package resolution lookup through node_modules
  • Does not fail on unknown extensions or protocols
  • Can optionally provide a hint of the format to the loading phase

The default loader has the following properties

  • Support for builtin module loading via node: URLs
  • Support for "inline" module loading via data: URLs
  • Support for file: module loading
  • Fails on any other URL protocol
  • Fails on unknown extensions for file: loading (supports only .cjs, .js, and .mjs)

Resolution algorithm#

The algorithm to load an ES module specifier is given through the ESM_RESOLVE method below. It returns the resolved URL for a module specifier relative to a parentURL.

The resolution algorithm determines the full resolved URL for a module load, along with its suggested module format. The resolution algorithm does not determine whether the resolved URL protocol can be loaded, or whether the file extensions are permitted, instead these validations are applied by Node.js during the load phase (for example, if it was asked to load a URL that has a protocol that is not file:, data:, node:, or if --experimental-network-imports is enabled, https:).

The algorithm also tries to determine the format of the file based on the extension (see ESM_FILE_FORMAT algorithm below). If it does not recognize the file extension (eg if it is not .mjs, .cjs, or .json), then a format of undefined is returned, which will throw during the load phase.

The algorithm to determine the module format of a resolved URL is provided by ESM_FILE_FORMAT, which returns the unique module format for any file. The "module" format is returned for an ECMAScript Module, while the "commonjs" format is used to indicate loading through the legacy CommonJS loader. Additional formats such as "addon" can be extended in future updates.

In the following algorithms, all subroutine errors are propagated as errors of these top-level routines unless stated otherwise.

defaultConditions is the conditional environment name array, ["node", "import"].

The resolver can throw the following errors:

  • Invalid Module Specifier: Module specifier is an invalid URL, package name or package subpath specifier.
  • Invalid Package Configuration: package.json configuration is invalid or contains an invalid configuration.
  • Invalid Package Target: Package exports or imports define a target module for the package that is an invalid type or string target.
  • Package Path Not Exported: Package exports do not define or permit a target subpath in the package for the given module.
  • Package Import Not Defined: Package imports do not define the specifier.
  • Module Not Found: The package or module requested does not exist.
  • Unsupported Directory Import: The resolved path corresponds to a directory, which is not a supported target for module imports.

Resolution Algorithm Specification#

ESM_RESOLVE(specifier, parentURL)

  1. Let resolved be undefined.
  2. If specifier is a valid URL, then
    1. Set resolved to the result of parsing and reserializing specifier as a URL.
  3. Otherwise, if specifier starts with "/", "./", or "../", then
    1. Set resolved to the URL resolution of specifier relative to parentURL.
  4. Otherwise, if specifier starts with "#", then
    1. Set resolved to the result of PACKAGE_IMPORTS_RESOLVE(specifier, parentURL, defaultConditions).
  5. Otherwise,
    1. Note: specifier is now a bare specifier.
    2. Set resolved the result of PACKAGE_RESOLVE(specifier, parentURL).
  6. Let format be undefined.
  7. If resolved is a "file:" URL, then
    1. If resolved contains any percent encodings of "/" or "\" ("%2F" and "%5C" respectively), then
      1. Throw an Invalid Module Specifier error.
    2. If the file at resolved is a directory, then
      1. Throw an Unsupported Directory Import error.
    3. If the file at resolved does not exist, then
      1. Throw a Module Not Found error.
    4. Set resolved to the real path of resolved, maintaining the same URL querystring and fragment components.
    5. Set format to the result of ESM_FILE_FORMAT(resolved).
  8. Otherwise,
    1. Set format the module format of the content type associated with the URL resolved.
  9. Return format and resolved to the loading phase

PACKAGE_RESOLVE(packageSpecifier, parentURL)

  1. Let packageName be undefined.
  2. If packageSpecifier is an empty string, then
    1. Throw an Invalid Module Specifier error.
  3. If packageSpecifier is a Node.js builtin module name, then
    1. Return the string "node:" concatenated with packageSpecifier.
  4. If packageSpecifier does not start with "@", then
    1. Set packageName to the substring of packageSpecifier until the first "/" separator or the end of the string.
  5. Otherwise,
    1. If packageSpecifier does not contain a "/" separator, then
      1. Throw an Invalid Module Specifier error.
    2. Set packageName to the substring of packageSpecifier until the second "/" separator or the end of the string.
  6. If packageName starts with "." or contains "\" or "%", then
    1. Throw an Invalid Module Specifier error.
  7. Let packageSubpath be "." concatenated with the substring of packageSpecifier from the position at the length of packageName.
  8. If packageSubpath ends in "/", then
    1. Throw an Invalid Module Specifier error.
  9. Let selfUrl be the result of PACKAGE_SELF_RESOLVE(packageName, packageSubpath, parentURL).
  10. If selfUrl is not undefined, return selfUrl.
  11. While parentURL is not the file system root,
    1. Let packageURL be the URL resolution of "node_modules/" concatenated with packageSpecifier, relative to parentURL.
    2. Set parentURL to the parent folder URL of parentURL.
    3. If the folder at packageURL does not exist, then
      1. Continue the next loop iteration.
    4. Let pjson be the result of READ_PACKAGE_JSON(packageURL).
    5. If pjson is not null and pjson.exports is not null or undefined, then
      1. Return the result of PACKAGE_EXPORTS_RESOLVE(packageURL, packageSubpath, pjson.exports, defaultConditions).
    6. Otherwise, if packageSubpath is equal to ".", then
      1. If pjson.main is a string, then
        1. Return the URL resolution of main in packageURL.
    7. Otherwise,
      1. Return the URL resolution of packageSubpath in packageURL.
  12. Throw a Module Not Found error.

PACKAGE_SELF_RESOLVE(packageName, packageSubpath, parentURL)

  1. Let packageURL be the result of LOOKUP_PACKAGE_SCOPE(parentURL).
  2. If packageURL is null, then
    1. Return undefined.
  3. Let pjson be the result of READ_PACKAGE_JSON(packageURL).
  4. If pjson is null or if pjson.exports is null or undefined, then
    1. Return undefined.
  5. If pjson.name is equal to packageName, then
    1. Return the result of PACKAGE_EXPORTS_RESOLVE(packageURL, packageSubpath, pjson.exports, defaultConditions).
  6. Otherwise, return undefined.

PACKAGE_EXPORTS_RESOLVE(packageURL, subpath, exports, conditions)

  1. If exports is an Object with both a key starting with "." and a key not starting with ".", throw an Invalid Package Configuration error.
  2. If subpath is equal to ".", then
    1. Let mainExport be undefined.
    2. If exports is a String or Array, or an Object containing no keys starting with ".", then
      1. Set mainExport to exports.
    3. Otherwise if exports is an Object containing a "." property, then
      1. Set mainExport to exports["."].
    4. If mainExport is not undefined, then
      1. Let resolved be the result of PACKAGE_TARGET_RESOLVE( packageURL, mainExport, null, false, conditions).
      2. If resolved is not null or undefined, return resolved.
  3. Otherwise, if exports is an Object and all keys of exports start with ".", then
    1. Let matchKey be the string "./" concatenated with subpath.
    2. Let resolved be the result of PACKAGE_IMPORTS_EXPORTS_RESOLVE( matchKey, exports, packageURL, false, conditions).
    3. If resolved is not null or undefined, return resolved.
  4. Throw a Package Path Not Exported error.

PACKAGE_IMPORTS_RESOLVE(specifier, parentURL, conditions)

  1. Assert: specifier begins with "#".
  2. If specifier is exactly equal to "#" or starts with "#/", then
    1. Throw an Invalid Module Specifier error.
  3. Let packageURL be the result of LOOKUP_PACKAGE_SCOPE(parentURL).
  4. If packageURL is not null, then
    1. Let pjson be the result of READ_PACKAGE_JSON(packageURL).
    2. If pjson.imports is a non-null Object, then
      1. Let resolved be the result of PACKAGE_IMPORTS_EXPORTS_RESOLVE( specifier, pjson.imports, packageURL, true, conditions).
      2. If resolved is not null or undefined, return resolved.
  5. Throw a Package Import Not Defined error.

PACKAGE_IMPORTS_EXPORTS_RESOLVE(matchKey, matchObj, packageURL, isImports, conditions)

  1. If matchKey is a key of matchObj and does not contain "*", then
    1. Let target be the value of matchObj[matchKey].
    2. Return the result of PACKAGE_TARGET_RESOLVE(packageURL, target, null, isImports, conditions).
  2. Let expansionKeys be the list of keys of matchObj containing only a single "*", sorted by the sorting function PATTERN_KEY_COMPARE which orders in descending order of specificity.
  3. For each key expansionKey in expansionKeys, do
    1. Let patternBase be the substring of expansionKey up to but excluding the first "*" character.
    2. If matchKey starts with but is not equal to patternBase, then
      1. Let patternTrailer be the substring of expansionKey from the index after the first "*" character.
      2. If patternTrailer has zero length, or if matchKey ends with patternTrailer and the length of matchKey is greater than or equal to the length of expansionKey, then
        1. Let target be the value of matchObj[expansionKey].
        2. Let patternMatch be the substring of matchKey starting at the index of the length of patternBase up to the length of matchKey minus the length of patternTrailer.
        3. Return the result of PACKAGE_TARGET_RESOLVE(packageURL, target, patternMatch, isImports, conditions).
  4. Return null.

PATTERN_KEY_COMPARE(keyA, keyB)

  1. Assert: keyA ends with "/" or contains only a single "*".
  2. Assert: keyB ends with "/" or contains only a single "*".
  3. Let baseLengthA be the index of "*" in keyA plus one, if keyA contains "*", or the length of keyA otherwise.
  4. Let baseLengthB be the index of "*" in keyB plus one, if keyB contains "*", or the length of keyB otherwise.
  5. If baseLengthA is greater than baseLengthB, return -1.
  6. If baseLengthB is greater than baseLengthA, return 1.
  7. If keyA does not contain "*", return 1.
  8. If keyB does not contain "*", return -1.
  9. If the length of keyA is greater than the length of keyB, return -1.
  10. If the length of keyB is greater than the length of keyA, return 1.
  11. Return 0.

PACKAGE_TARGET_RESOLVE(packageURL, target, patternMatch, isImports, conditions)

  1. If target is a String, then
    1. If target does not start with "./", then
      1. If isImports is false, or if target starts with "../" or "/", or if target is a valid URL, then
        1. Throw an Invalid Package Target error.
      2. If patternMatch is a String, then
        1. Return PACKAGE_RESOLVE(target with every instance of "*" replaced by patternMatch, packageURL + "/").
      3. Return PACKAGE_RESOLVE(target, packageURL + "/").
    2. If target split on "/" or "\" contains any "", ".", "..", or "node_modules" segments after the first "." segment, case insensitive and including percent encoded variants, throw an Invalid Package Target error.
    3. Let resolvedTarget be the URL resolution of the concatenation of packageURL and target.
    4. Assert: resolvedTarget is contained in packageURL.
    5. If patternMatch is null, then
      1. Return resolvedTarget.
    6. If patternMatch split on "/" or "\" contains any "", ".", "..", or "node_modules" segments, case insensitive and including percent encoded variants, throw an Invalid Module Specifier error.
    7. Return the URL resolution of resolvedTarget with every instance of "*" replaced with patternMatch.
  2. Otherwise, if target is a non-null Object, then
    1. If exports contains any index property keys, as defined in ECMA-262 6.1.7 Array Index, throw an Invalid Package Configuration error.
    2. For each property p of target, in object insertion order as,
      1. If p equals "default" or conditions contains an entry for p, then
        1. Let targetValue be the value of the p property in target.
        2. Let resolved be the result of PACKAGE_TARGET_RESOLVE( packageURL, targetValue, patternMatch, isImports, conditions).
        3. If resolved is equal to undefined, continue the loop.
        4. Return resolved.
    3. Return undefined.
  3. Otherwise, if target is an Array, then
    1. If _target.length is zero, return null.
    2. For each item targetValue in target, do
      1. Let resolved be the result of PACKAGE_TARGET_RESOLVE( packageURL, targetValue, patternMatch, isImports, conditions), continuing the loop on any Invalid Package Target error.
      2. If resolved is undefined, continue the loop.
      3. Return resolved.
    3. Return or throw the last fallback resolution null return or error.
  4. Otherwise, if target is null, return null.
  5. Otherwise throw an Invalid Package Target error.

ESM_FILE_FORMAT(url)

  1. Assert: url corresponds to an existing file.
  2. If url ends in ".mjs", then
    1. Return "module".
  3. If url ends in ".cjs", then
    1. Return "commonjs".
  4. If url ends in ".json", then
    1. Return "json".
  5. Let packageURL be the result of LOOKUP_PACKAGE_SCOPE(url).
  6. Let pjson be the result of READ_PACKAGE_JSON(packageURL).
  7. If pjson?.type exists and is "module", then
    1. If url ends in ".js", then
      1. Return "module".
    2. Return undefined.
  8. Otherwise,
    1. Return undefined.

LOOKUP_PACKAGE_SCOPE(url)

  1. Let scopeURL be url.
  2. While scopeURL is not the file system root,
    1. Set scopeURL to the parent URL of scopeURL.
    2. If scopeURL ends in a "node_modules" path segment, return null.
    3. Let pjsonURL be the resolution of "package.json" within scopeURL.
    4. if the file at pjsonURL exists, then
      1. Return scopeURL.
  3. Return null.

READ_PACKAGE_JSON(packageURL)

  1. Let pjsonURL be the resolution of "package.json" within packageURL.
  2. If the file at pjsonURL does not exist, then
    1. Return null.
  3. If the file at packageURL does not parse as valid JSON, then
    1. Throw an Invalid Package Configuration error.
  4. Return the parsed JSON source of the file at pjsonURL.

Customizing ESM specifier resolution algorithm#

The Loaders API provides a mechanism for customizing the ESM specifier resolution algorithm. An example loader that provides CommonJS-style resolution for ESM specifiers is commonjs-extension-resolution-loader.