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Migrating from Node.js to Deno

Deno supports modern Node.js projects out of the box, with no changes to your code. Running your Node.js project with Deno is a straightforward process, the main points to be aware of are:

  1. Usage of Node.js globals (like process, Buffer, etc)
  2. Imported Node.js built-in modules need the node: specifier (fs -> node:fs)

This guide will walk you through migrating your Node.js project to Deno and offer some optional suggestions of ways to optimize your codebase.

Tip

If your project is written with CommonJS (i.e. require), you will need to update it to use ECMAScript modules, check out our helpful CommonJS to ESM guide to get you up and running with Deno.

Node.js built-ins Jump to heading

In Node.js 20 and earlier, built-in modules in the Node.js standard library could be imported with "bare specifiers". Consider the Node program below with a .mjs extension:

index.mjs
import * as os from "os";
console.log(os.cpus());

The os module is built in to the Node.js runtime, and can be imported using a bare specifier as above.

.mjs extensions not required in Deno

The .mjs file extension is supported but not required in Deno. Because Node doesn't support ESM by default, it requires you to name any files that use ESM with a .mjs file extension.

Deno provides a compatibility layer that allows the use of Node.js built-in APIs within Deno programs. However, in order to use them, you will need to add the node: specifier to any import statements that use them.

For example - if you update the code above to be this instead:

import * as os from "node:os";
console.log(os.cpus());

And run it with deno run index.mjs - you will notice you get the same output as running the program in Node.js. Updating any imports in your application to use node: specifiers should enable any code using Node built-ins to function as it did in Node.js.

Runtime permissions in Deno Jump to heading

Consider the following simple Express server:

import express from "npm:express@4";

const app = express();

app.get("/", function (_req, res) {
  res.send("hello");
});

app.listen(3000, () => {
  console.log("Express listening on :3000");
});

If you run the above with deno run server.js, you would be prompted for permissions required to execute the code and its dependencies.

$ deno run server.js
┌ ⚠️  Deno requests net access to "0.0.0.0:8000".
├ Requested by `Deno.listen()` API.
├ Run again with --allow-net to bypass this prompt.
└ Allow? [y/n/A] (y = yes, allow; n = no, deny; A = allow all net permissions) >

Deno features runtime security by default, meaning that you as the developer must opt in to giving your code access to the filesystem, network, system environment, and more. Doing this prevents supply chain attacks and other potential vulnerabilities in your code. By comparison, Node.js has no concept of runtime security, with all code executed with the same level of permission as the user running the code.

To run your code like it would in Node.js, you can pass the -A flag to enable all permissions.

deno run -A server.js

For more granular control, you can enable access to specific features by opting in to individual permissions.

Running scripts from package.json Jump to heading

Deno supports running npm scripts natively with the deno task subcommand. Consider the following Node.js project with a script called start inside its package.json:

package.json
{
  "name": "my-project",
  "scripts": {
    "start": "eslint"
  }
}

You can execute this script with Deno by running:

deno task start

Node.js global objects Jump to heading

In Node.js, there are a number of global objects available in the scope of all programs, like the process object, Buffer, or __dirname and __filename.

Deno does not add additional objects and variables to the global scope, other than the Deno global. Any API that doesn't exist as a web-standard browser API will be found in Deno. Alternatively, you can import Node.js built-in modules using the node: specifier.

import process from "node:process";
import { Buffer } from "node:buffer";

const __filename = import.meta.filename;
const __dirname = import.meta.dirname;

Note

If you do run into a problem with Node.js compatibility, please let us know by opening an issue on GitHub.

Optional improvements with Deno's built-in tools Jump to heading

One of Deno's core strengths is a unified toolchain that comes with support for TypeScript out of the box, and tools like a linter, formatter and a test runner. Switching to Deno allows you to simplify your toolchain and reduces the number of moving components in your project. Deno also has a more secure runtime, with runtime permissions that allow you to control what your code can access.

deno.json (optional) Jump to heading

Deno has its own config file, deno.json or deno.jsonc, which can be used to configure your project. You can use it to define tasks, dependencies, path mappings, and other runtime configurations.

Migrating npm scripts to deno.json (optional) Jump to heading

If preferred, you can move your npm scripts over to deno.json, where they can be run using deno task. This allows you to manage all necessary permission flags and other runtime configuration in one place.

{
  "tasks": {
    "dev": "deno run --allow-net --allow-read --allow-env server.js"
  }
}

deno task dev

Migrating npm dependencies to deno.json (optional) Jump to heading

You can also migrate your dependencies over to deno.json. Deno supports importing dependencies from external package repositories, local files, and/or URLs. To import your npm dependencies, you can add them to the imports field in deno.json, and add the npm: specifier to the import path:

{
  "imports": {
    "express": "npm:express@4"
  }
}

Deno supports multiple package registries and allows you to import dependencies from npm, JSR and HTTP URLs.

{
  "imports": {
    "express": "npm:express@4",
    "@luca/cases": "jsr:@luca/cases@1",
    "foo": "https://example.com/foo.ts"
  }
}

Linting (optional) Jump to heading

Deno ships with a built-in linter that is written with performance in mind. Deno can lint large projects in just a few milliseconds. You can try it out on your project by running:

deno lint

This will lint all files in your project. When the linter detects a problem, it will show the line in your editor and in the terminal output. An example of what that might look like:

error[no-constant-condition]: Use of a constant expressions as conditions is not allowed.
 --> /my-project/bar.ts:1:5
  | 
1 | if (true) {
  |     ^^^^
  = hint: Remove the constant expression

  docs: https://lint.deno.land/rules/no-constant-condition


Found 1 problem
Checked 4 files

Many linting issues can be fixed automatically by passing the --fix flag:

deno lint --fix

A full list of all supported linting rules can be found on https://lint.deno.land/. To learn more about how to configure the linter, check out the deno lint subcommand.

Formatting (optional) Jump to heading

Deno ships with a built-in formatter that can optionally format your code according to the Deno style guide. You can run the formatter on your project by running:

deno fmt

If using deno fmt in CI, you can pass the --check argument to make the formatter exit with an error when it detects improperly formatted code.

deno fmt --check

The formatting rules can be configured in your deno.json file. To learn more about how to configure the formatter, check out the deno fmt subcommand.

Testing (optional) Jump to heading

Deno encourages writing tests for your code, and provides a built-in test runner to make it easy to write and run tests. The test runner is tightly integrated into Deno, so that you don't have to do any additional configuration to make TypeScript or other features work.

my_test.ts
Deno.test("my test", () => {
  // Your test code here
});

deno test

When passing the --watch flag, the test runner will automatically reload when any of the imported modules change.

To learn more about the test runner and how to configure it, check out the deno test subcommand documentation.