Encode and parse data in the Concise Binary Object Representation (CBOR) data format (RFC8949).

This package supersedes node-cbor, with the following goals:

• Web-first. Usable in Node and Deno.
• Simpler where possible. Remove non-core features in favor of extensibility.
• Synchronous decoding. Removes streaming capabilities that are rarely used.
• Complete break of API compatibility, allowing use of newer JavaScript constructs.
• No work-arounds for older environments.

This project now only supports versions of Node.js that the Node team is currently supporting. Currently, that means Node 18+ is required.

npm install --save cbor2

See the full API documentation.

Example:

import {decode, diagnose, encode} from 'cbor';

const encoded = encode(true); // Returns Uint8Array(1) [ 245 ]
decode(encoded); // Returns true

// Use integers as keys:
const m = new Map();
m.set(1, 25);
encode(m); // Returns Uint8Array(3) [ 161, 1, 24, 25 ]
diagnose(encode(m)); // {1: 25_0}

If you load cbor2 using import {decode, encode} from 'cbor2';, all of the type converters will be loaded automatically. If you import only pieces of the API and you want the type converters loaded, please also do import 'cbor2/types';.

The following types are supported for encoding:

• boolean
• number (including -0, NaN, and ±Infinity)
• string
• bigint
• Array
• Set
• Object (including null)
• Map
• undefined
• Date,
• RegExp
• URL
• TypedArrays: Uint8Array is mapped to a CBOR byte array, others are tagged
• Boxed primitive types: String, Number, BigInt, Boolean
• cbor2.Simple
• cbor2.Tag

Decoding supports the above types, including the following CBOR tag numbers:

There are several ways to add a new encoder:

This is the easiest approach, if you can modify the class being encoded. Add a toCBOR() method to your class, which should return a two-element array containing the tag number and data item that encodes your class. If the tag number is NaN, no tag will be written. If you return undefined, nothing will be written. In this case you will likely write custom bytes to the Writer instance that is passed in, perhaps using the encoding options.

For example:

class Foo {
  constructor(one, two) {
    this.one = one;
    this.two = two;
  }

  toCBOR(_writer, _options) {
    return [64000, [this.one, this.two]];
  }
}

You can also modify an existing type by monkey-patching a toCBOR function onto its prototype, but this isn't recommended.

If your object does not have a toCBOR() method, but does have a toJSON() method, the value returned from toJSON() will be used to serialize the object.

Sometimes, you want to support an existing type without modification to that type. In this case, call registerEncoder(type, encodeFunction). The encodeFunction takes an object instance and returns the same type as toCBOR above:

import {registerEncoder} from 'cbor2/encoder';

class Bar {
  constructor() {
    this.three = 3;
  }
}
registerEncoder(Bar, (b, _writer, _options) => [NaN, b.three]);

Most of the time, you will want to add support for decoding a new tag type. If the Decoder class encounters a tag it doesn't support, it will generate a Tag instance that you can handle or ignore as needed. To have a specific type generated instead, call Tag.registerDecoder() with the tag number and a function that will convert the tags value to the appropriate type. For the Foo example above, this might look like:

import {Tag} from 'cbor2/tag';

Tag.registerDecoder(64000, tag => new Foo(tag.contents[0], tag.contents[1]));

You can also replace the default decoders by passing in an appropriate tag function. For example:

// Tag 0 is Date/Time as an ISO-8601 string
import 'cbor2/types';
import {Tag} from 'cbor2/tag';

Tag.registerDecoder(0, ({contents}) => Temporal.Instant.from(contents));

JavaScript "boxed" types, such as those created with new Number(3), are object wrappers around JavaScript primitives. These objects can be used in most places that a primitive value would be used, but since they are objects they can have associated properties. This library can decode CBOR values into boxed types if desired, such that the original CBOR encoding of that value is stored as a hidden property on the value, ensuring that round-tripping between decoding and encoding will produce the original CBOR value, no matter which of the many legal CBOR encodings were used for a given value. For example:

import {decode, encode} from 'cbor';

const val = decode('fa40800000', {boxed: true}); // [Number: 4]
encode(4); // 0x04
encode(new Number(4)); // 0x04
encode(val); // 0xfa40800000, the original encoding
encode(val, {ignoreOriginalEncoding: true}); // 0x04

When pedantic protocols are strict about the types they will accept, and you want to force a particular numeric encoding, you can use the encodedNumber function to create a boxed number with the desired encoding attached:

import {encode, encodedNumber} from 'cbor';

const val = encodedNumber(4, 'i64'); // [Number: 4]
encode(val); // 0x1b0000000000000004
encode(encodedNumber(4)); // 0xf94400

Note that the default format for encodedNumber is the preferred floating point representation, which can be explicitly selected with an encoding of 'f'.

The tests for this package use a set of test vectors from RFC 8949 appendix A by importing a machine readable version of them from https://github.com/cbor/test-vectors. For these tests to work, you will need to use the command git submodule update --init after cloning or pulling this code. See the git docs for more information.