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Fastest JS implementation of ed25519 / ristretto255. High-security, auditable, 0-dependency EDDSA signatures and public keys

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noble-ed25519 Node CI code style: prettier

Fastest JS implementation of ed25519, an elliptic curve that could be used for asymmetric encryption and EDDSA signature scheme. Algorithmically resistant to timing attacks, conforms to RFC8032.

Includes ristretto255 support. Ristretto is a technique for constructing prime order elliptic curve groups with non-malleable encodings.

Check out the online demo.

This library belongs to noble crypto

noble-crypto — high-security, easily auditable set of contained cryptographic libraries and tools.

  • No dependencies, one small file
  • Easily auditable TypeScript/JS code
  • Supported in all major browsers and stable node.js versions
  • All releases are signed with PGP keys
  • Check out all libraries: secp256k1, ed25519, bls12-381, ripemd160

Usage

Node:

npm install noble-ed25519

import * as ed from 'noble-ed25519';

const privateKey = ed.utils.randomPrivateKey(); // 32-byte Uint8Array or string.
const msgHash = 'deadbeefdeadbeefdeadbeefdeadbeefdeadbeefdeadbeefdeadbeefdeadbeef';
(async () => {
  const publicKey = await ed.getPublicKey(privateKey);
  const signature = await ed.sign(msgHash, privateKey);
  const isSigned = await ed.verify(signature, msgHash, publicKey);
})();

Deno:

import * as ed from 'https://deno.land/x/ed25519/mod.ts';
const privateKey = ed.utils.randomPrivateKey();
const publicKey = await ed.getPublicKey(privateKey);

API

getPublicKey(privateKey)
function getPublicKey(privateKey: Uint8Array): Promise<Uint8Array>;
function getPublicKey(privateKey: string): Promise<string>;
function getPublicKey(privateKey: bigint): Promise<Uint8Array>;
  • privateKey: Uint8Array | string | bigint will be used to generate public key. Public key is generated by executing scalar multiplication of a base Point(x, y) by a fixed integer. The result is another Point(x, y) which we will by default encode to hex Uint8Array.

  • Returns:

    • Promise<Uint8Array> if Uint8Array was passed
    • Promise<string> if hex string was passed
    • Uses promises, because ed25519 uses SHA internally; and we're using built-in browser window.crypto, which returns Promise.
  • Use Point.fromPrivateKey(privateKey) if you want Point instance instead

  • Use Point.fromHex(publicKey) if you want to convert hex / bytes into Point. It will use decompression algorithm 5.1.3 of RFC 8032.

sign(hash, privateKey)
function sign(hash: Uint8Array, privateKey: Uint8Array): Promise<Uint8Array>;
function sign(hash: string, privateKey: string): Promise<string>;
  • hash: Uint8Array | string - message hash which would be signed
  • privateKey: Uint8Array | string - private key which will sign the hash
  • Returns EdDSA signature. You can consume it with Signature.fromHex() method:
    • Signature.fromHex(ed25519.sign(hash, privateKey))
verify(signature, hash, publicKey)
function verify(
  signature: Uint8Array | string | Signature,
  hash: Uint8Array | string,
  publicKey: Uint8Array | string | Point
): Promise<boolean>
  • signature: Uint8Array | string | Signature - returned by the sign function
  • hash: Uint8Array | string - message hash that needs to be verified
  • publicKey: Uint8Array | string | Point - e.g. that was generated from privateKey by getPublicKey
  • Returns Promise<boolean>: Promise<true> if signature == hash; otherwise Promise<false>
Ristretto255

To use Ristretto, simply use fromRistrettoHash() and toRistrettoBytes() methods.

// The hash-to-group operation applies Elligator twice and adds the results.
ExtendedPoint.fromRistrettoHash(hash: Uint8Array): ExtendedPoint;

// Decode a byte-string s_bytes representing a compressed Ristretto point into extended coordinates.
ExtendedPoint.fromRistrettoBytes(bytes: Uint8Array): ExtendedPoint;

// Encode a Ristretto point represented by the point (X:Y:Z:T) in extended coordinates to Uint8Array.
ExtendedPoint.toRistrettoBytes(): Uint8Array

It extends Mike Hamburg's Decaf approach to cofactor elimination to support cofactor-8 curves such as Curve25519.

In particular, this allows an existing Curve25519 library to implement a prime-order group with only a thin abstraction layer, and makes it possible for systems using Ed25519 signatures to be safely extended with zero-knowledge protocols, with no additional cryptographic assumptions and minimal code changes.

Helpers & Point

utils.randomPrivateKey()

Returns cryptographically random Uint8Array that could be used as Private Key.

utils.precompute(W = 8, point = Point.BASE)

Returns cached point which you can use to #multiply by it.

This is done by default, no need to run it unless you want to disable precomputation or change window size.

We're doing scalar multiplication (used in getPublicKey etc) with precomputed BASE_POINT values.

This slows down first getPublicKey() by milliseconds (see Speed section), but allows to speed-up subsequent getPublicKey() calls up to 20x.

You may want to precompute values for your own point.

utils.TORSION_SUBGROUP

The 8-torsion subgroup ℰ8. Those are "buggy" points, if you multiply them by 8, you'll receive Point.ZERO.

Useful to check implementations for signature malleability. See the link

Point#toX25519

You can use the method to use ed25519 keys for curve25519 encryption.

https://blog.filippo.io/using-ed25519-keys-for-encryption

ed25519.CURVE.P // 2 ** 255 - 19
ed25519.CURVE.n // 2 ** 252 - 27742317777372353535851937790883648493
ed25519.Point.BASE // new ed25519.Point(Gx, Gy) where
// Gx = 15112221349535400772501151409588531511454012693041857206046113283949847762202n
// Gy = 46316835694926478169428394003475163141307993866256225615783033603165251855960n;


// Elliptic curve point in Affine (x, y) coordinates.
ed25519.Point {
  constructor(x: bigint, y: bigint);
  static fromY(y: bigint);
  static fromHex(hash: string);
  static fromPrivateKey(privateKey: string | Uint8Array);
  toX25519(): bigint; // Converts to Curve25519
  toRawBytes(): Uint8Array;
  toHex(): string; // Compact representation of a Point
  equals(other: Point): boolean;
  negate(): Point;
  add(other: Point): Point;
  subtract(other: Point): Point;
  multiply(scalar: bigint): Point;
}
// Elliptic curve point in Extended (x, y, z, t) coordinates.
ed25519.ExtendedPoint {
  constructor(x: bigint, y: bigint, z: bigint, t: bigint);
  static fromAffine(point: Point): ExtendedPoint;
  static fromRistrettoHash(hash: Uint8Array): ExtendedPoint;
  static fromRistrettoBytes(bytes: Uint8Array): ExtendedPoint;
  toRistrettoBytes(): Uint8Array;
  toAffine(): Point;
}
ed25519.Signature {
  constructor(r: bigint, s: bigint);
  toHex(): string;
}

// Precomputation helper
utils.precompute(W, point);

Security

Noble is production-ready. Our goal is to have it audited by a good security expert.

We're using built-in JS BigInt, which is "unsuitable for use in cryptography" as per official spec. This means that the lib is potentially vulnerable to timing attacks. But:

  1. JIT-compiler and Garbage Collector make "constant time" extremely hard to achieve in a scripting language.
  2. Which means any other JS library doesn't use constant-time bigints. Including bn.js or anything else. Even statically typed Rust, a language without GC, makes it harder to achieve constant-time for some cases.
  3. If your goal is absolute security, don't use any JS lib — including bindings to native ones. Use low-level libraries & languages.
  4. We however consider infrastructure attacks like rogue NPM modules very important; that's why it's crucial to minimize the amount of 3rd-party dependencies & native bindings. If your app uses 500 dependencies, any dep could get hacked and you'll be downloading rootkits with every npm install. Our goal is to minimize this attack vector.

Speed

Benchmarks done with Apple M1.

getPublicKey(utils.randomPrivateKey()) x 6,562 ops/sec @ 152μs/op
sign x 3,017 ops/sec @ 331μs/op
verify x 696 ops/sec @ 1ms/op
verifyBatch x 825 ops/sec @ 1ms/op
Point.fromHex decompression x 10,626 ops/sec @ 94μs/op
ristretto255#fromHash x 5,031 ops/sec @ 198μs/op
ristretto255 round x 2,251 ops/sec @ 444μs/op

Compare to alternative implementations:

# [email protected]
getPublicKey x 920 ops/sec @ 1ms/op # aka scalarMultBase
sign x 519 ops/sec @ 2ms/op

# [email protected]
getPublicKey x 877 ops/sec @ 1ms/op # aka scalarMultBase

# [email protected], native bindings to libsodium, node.js-only
sodium-native#sign x 58,661 ops/sec @ 17μs/op

Contributing

  1. Clone the repository.
  2. npm install to install build dependencies like TypeScript
  3. npm run compile to compile TypeScript code
  4. npm run test to run jest on test/index.ts

License

MIT (c) Paul Miller (https://paulmillr.com), see LICENSE file.

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Fastest JS implementation of ed25519 / ristretto255. High-security, auditable, 0-dependency EDDSA signatures and public keys

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