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noble-secp256k1
Advanced tools
Noble secp256k1. High-security, easily auditable, 0-dep, 1-file pubkey & ECDSA.
secp256k1, an elliptic curve that could be used for assymetric encryption, ECDH key agreement protocol and ECDSA signature scheme.
Algorithmically resistant to timing attacks. With tens of thousands test vectors.
noble-crypto — high-security, easily auditable set of contained cryptographic libraries and tools.
npm install noble-secp256k1
import * as secp256k1 from "noble-secp256k1";
// You can also pass BigInt:
// const PRIVATE_KEY = 0xa665a45920422f9d417e4867efn;
const PRIVATE_KEY = Uint8Array.from([
0xa6, 0x65, 0xa4, 0x59, 0x20, 0x42, 0x2f,
0x9d, 0x41, 0x7e, 0x48, 0x67, 0xef
]);
const MESSAGE_HASH = "9c1185a5c5e9fc54612808977ee8f548b2258d31";
const publicKey = secp256k1.getPublicKey(PRIVATE_KEY);
const signature = secp256k1.sign(MESSAGE_HASH, PRIVATE_KEY);
const isMessageSigned = secp256k1.verify(signature, MESSAGE_HASH, publicKey);
getPublicKey(privateKey)
getSharedSecret(privateKeyA, publicKeyB)
sign(hash, privateKey)
verify(signature, hash)
recoverPublicKey(hash, signature, recovery)
getPublicKey(privateKey)
function getPublicKey(privateKey: Uint8Array, isCompressed?: false): Uint8Array;
function getPublicKey(privateKey: string, isCompressed?: false): string;
function getPublicKey(privateKey: bigint): Uint8Array;
privateKey
will be used to generate public key.
Public key is generated by doing 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.
isCompressed
(default is false
) determines whether the output should contain y
coordinate of the point.
To get Point instance, use Point.fromPrivateKey(privateKey)
.
getSharedSecret(privateKeyA, publicKeyB)
function getSharedSecret(privateKeyA: Uint8Array | string | bigint, publicKeyB: string | Uint8Array | Point): Uint8Array;
Computes ECDH (Elliptic Curve Diffie-Hellman) shared secret between a private key and a different public key.
To get Point instance, use Point.fromHex(publicKeyB).multiply(privateKeyA)
.
sign(hash, privateKey)
function sign(hash: Uint8Array, privateKey: Uint8Array | bigint, opts?: Options): Promise<Uint8Array>;
function sign(hash: string, privateKey: string | bigint, opts?: Options): Promise<string>;
function sign(hash: Uint8Array, privateKey: Uint8Array | bigint, opts?: Options): Promise<[Uint8Array | string, number]>;
Generates deterministic ECDSA signature as per RFC 6979. Asynchronous, so use await
.
hash: Uint8Array | string
- message hash which would be signedprivateKey: Uint8Array | string | bigint
- private key which will sign the hashoptions?: Options
- optional object related to signature value and formatoptions?.recovered: boolean = false
- determines whether the recovered bit should be included in the result. In this case, the result would be an array of two items.options?.canonical: boolean = false
- determines whether a signature s
should be no more than 1/2 prime orderoptions.recovered == true
.verify(signature, hash)
function verify(signature: Uint8Array | string | SignResult, hash: Uint8Array | string): boolean
signature: Uint8Array | string | { r: bigint, s: bigint }
- object returned by the sign
functionhash: string | Uint8Array
- message hash that needs to be verifiedpublicKey: string | Point
- e.g. that was generated from privateKey
by getPublicKey
boolean
: true
if signature == hash
; otherwise false
recoverPublicKey(hash, signature, recovery)
function recoverPublicKey(hash: Hex, signature: Signature, recovery: number | bigint): Point | undefined
hash: Uint8Array | string
- message hash which would be signedsignature: Uint8Array | string | { r: bigint, s: bigint }
- object returned by the sign
functionrecovery: number | bigint
- recovery bit returned by sign
with recovered
option
Public key is generated by doing 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.
If signature is invalid - function will return undefined
as result.// 𝔽p
secp256k1.P // 2 ^ 256 - 2 ^ 32 - 977
// Prime order
secp256k1.PRIME_ORDER // 2 ^ 256 - 432420386565659656852420866394968145599
// Base point
secp256k1.BASE_POINT // new secp256k1.Point(x, y) where
// x = 55066263022277343669578718895168534326250603453777594175500187360389116729240n
// y = 32670510020758816978083085130507043184471273380659243275938904335757337482424n;
// Elliptic curve point
secp256k1.Point {
constructor(x: bigint, y: bigint);
// Compressed elliptic curve point representation
static fromHex(hex: Uint8Array | string);
static fromPrivateKey(privateKey: Uint8Array | string | number | bigint);
static fromSignature(
hash: Hex,
signature: Signature,
recovery: number | bigint
): Point | undefined {
toHex(): string;
add(other: Point): Point;
// Constant-time scalar multiplication.
multiply(scalar: bigint | Uint8Array): Point;
}
secp256k1.SignResult {
constructor(r: bigint, s: bigint);
// DER encoded ECDSA signature
static fromHex(hex: Uint8Array | string);
toHex(): string;
}
npm install
to install build dependencies like TypeScriptnpm run compile
to compile TypeScript codenpm run test
to run jest on test/index.ts
Noble is production-ready & secure. 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:
npm install
. Our goal is to minimize this attack vector.MIT (c) Paul Miller (https://paulmillr.com), see LICENSE file.
FAQs
Fastest JS implementation of secp256k1. Independently audited, high-security, 0-dependency ECDSA & Schnorr signatures
The npm package noble-secp256k1 receives a total of 1,110 weekly downloads. As such, noble-secp256k1 popularity was classified as popular.
We found that noble-secp256k1 demonstrated a not healthy version release cadence and project activity because the last version was released a year ago. It has 1 open source maintainer collaborating on the project.
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