import { type CHash } from '../utils.ts'; import { type AffinePoint, type CurveLengths, type CurvePoint, type CurvePointCons } from './curve.ts'; import { type IField } from './modular.ts'; export type { AffinePoint }; type EndoBasis = [[bigint, bigint], [bigint, bigint]]; /** * When Weierstrass curve has `a=0`, it becomes Koblitz curve. * Koblitz curves allow using **efficiently-computable GLV endomorphism ψ**. * Endomorphism uses 2x less RAM, speeds up precomputation by 2x and ECDH / key recovery by 20%. * For precomputed wNAF it trades off 1/2 init time & 1/3 ram for 20% perf hit. * * Endomorphism consists of beta, lambda and splitScalar: * * 1. GLV endomorphism ψ transforms a point: `P = (x, y) ↦ ψ(P) = (β·x mod p, y)` * 2. GLV scalar decomposition transforms a scalar: `k ≡ k₁ + k₂·λ (mod n)` * 3. Then these are combined: `k·P = k₁·P + k₂·ψ(P)` * 4. Two 128-bit point-by-scalar multiplications + one point addition is faster than * one 256-bit multiplication. * * where * * beta: β ∈ Fₚ with β³ = 1, β ≠ 1 * * lambda: λ ∈ Fₙ with λ³ = 1, λ ≠ 1 * * splitScalar decomposes k ↦ k₁, k₂, by using reduced basis vectors. * Gauss lattice reduction calculates them from initial basis vectors `(n, 0), (-λ, 0)` * * Check out `test/misc/endomorphism.js` and * [gist](https://gist.github.com/paulmillr/eb670806793e84df628a7c434a873066). */ export type EndomorphismOpts = { beta: bigint; basises?: EndoBasis; splitScalar?: (k: bigint) => { k1neg: boolean; k1: bigint; k2neg: boolean; k2: bigint; }; }; export type ScalarEndoParts = { k1neg: boolean; k1: bigint; k2neg: boolean; k2: bigint; }; /** * Splits scalar for GLV endomorphism. */ export declare function _splitEndoScalar(k: bigint, basis: EndoBasis, n: bigint): ScalarEndoParts; /** * Option to enable hedged signatures with improved security. * * * Randomly generated k is bad, because broken CSPRNG would leak private keys. * * Deterministic k (RFC6979) is better; but is suspectible to fault attacks. * * We allow using technique described in RFC6979 3.6: additional k', a.k.a. adding randomness * to deterministic sig. If CSPRNG is broken & randomness is weak, it would STILL be as secure * as ordinary sig without ExtraEntropy. * * * `true` means "fetch data, from CSPRNG, incorporate it into k generation" * * `false` means "disable extra entropy, use purely deterministic k" * * `Uint8Array` passed means "incorporate following data into k generation" * * https://paulmillr.com/posts/deterministic-signatures/ */ export type ECDSAExtraEntropy = boolean | Uint8Array; /** * - `compact` is the default format * - `recovered` is the same as compact, but with an extra byte indicating recovery byte * - `der` is ASN.1 DER encoding */ export type ECDSASignatureFormat = 'compact' | 'recovered' | 'der'; /** * - `prehash`: (default: true) indicates whether to do sha256(message). * When a custom hash is used, it must be set to `false`. */ export type ECDSARecoverOpts = { prehash?: boolean; }; /** * - `prehash`: (default: true) indicates whether to do sha256(message). * When a custom hash is used, it must be set to `false`. * - `lowS`: (default: true) prohibits signatures which have (sig.s >= CURVE.n/2n). * Compatible with BTC/ETH. Setting `lowS: false` allows to create malleable signatures, * which is default openssl behavior. * Non-malleable signatures can still be successfully verified in openssl. * - `format`: (default: 'compact') 'compact' or 'recovered' with recovery byte */ export type ECDSAVerifyOpts = { prehash?: boolean; lowS?: boolean; format?: ECDSASignatureFormat; }; /** * - `prehash`: (default: true) indicates whether to do sha256(message). * When a custom hash is used, it must be set to `false`. * - `lowS`: (default: true) prohibits signatures which have (sig.s >= CURVE.n/2n). * Compatible with BTC/ETH. Setting `lowS: false` allows to create malleable signatures, * which is default openssl behavior. * Non-malleable signatures can still be successfully verified in openssl. * - `format`: (default: 'compact') 'compact' or 'recovered' with recovery byte * - `extraEntropy`: (default: false) creates sigs with increased security, see {@link ECDSAExtraEntropy} */ export type ECDSASignOpts = { prehash?: boolean; lowS?: boolean; format?: ECDSASignatureFormat; extraEntropy?: ECDSAExtraEntropy; }; /** Instance methods for 3D XYZ projective points. */ export interface WeierstrassPoint extends CurvePoint> { /** projective X coordinate. Different from affine x. */ readonly X: T; /** projective Y coordinate. Different from affine y. */ readonly Y: T; /** projective z coordinate */ readonly Z: T; /** affine x coordinate. Different from projective X. */ get x(): T; /** affine y coordinate. Different from projective Y. */ get y(): T; /** Encodes point using IEEE P1363 (DER) encoding. First byte is 2/3/4. Default = isCompressed. */ toBytes(isCompressed?: boolean): Uint8Array; toHex(isCompressed?: boolean): string; } /** Static methods for 3D XYZ projective points. */ export interface WeierstrassPointCons extends CurvePointCons> { /** Does NOT validate if the point is valid. Use `.assertValidity()`. */ new (X: T, Y: T, Z: T): WeierstrassPoint; CURVE(): WeierstrassOpts; } /** * Weierstrass curve options. * * * p: prime characteristic (order) of finite field, in which arithmetics is done * * n: order of prime subgroup a.k.a total amount of valid curve points * * h: cofactor, usually 1. h*n is group order; n is subgroup order * * a: formula param, must be in field of p * * b: formula param, must be in field of p * * Gx: x coordinate of generator point a.k.a. base point * * Gy: y coordinate of generator point */ export type WeierstrassOpts = Readonly<{ p: bigint; n: bigint; h: bigint; a: T; b: T; Gx: T; Gy: T; }>; export type WeierstrassExtraOpts = Partial<{ Fp: IField; Fn: IField; allowInfinityPoint: boolean; endo: EndomorphismOpts; isTorsionFree: (c: WeierstrassPointCons, point: WeierstrassPoint) => boolean; clearCofactor: (c: WeierstrassPointCons, point: WeierstrassPoint) => WeierstrassPoint; fromBytes: (bytes: Uint8Array) => AffinePoint; toBytes: (c: WeierstrassPointCons, point: WeierstrassPoint, isCompressed: boolean) => Uint8Array; }>; /** * Options for ECDSA signatures over a Weierstrass curve. * * * lowS: (default: true) whether produced / verified signatures occupy low half of ecdsaOpts.p. Prevents malleability. * * hmac: (default: noble-hashes hmac) function, would be used to init hmac-drbg for k generation. * * randomBytes: (default: webcrypto os-level CSPRNG) custom method for fetching secure randomness. * * bits2int, bits2int_modN: used in sigs, sometimes overridden by curves */ export type ECDSAOpts = Partial<{ lowS: boolean; hmac: (key: Uint8Array, message: Uint8Array) => Uint8Array; randomBytes: (bytesLength?: number) => Uint8Array; bits2int: (bytes: Uint8Array) => bigint; bits2int_modN: (bytes: Uint8Array) => bigint; }>; /** * Elliptic Curve Diffie-Hellman interface. * Provides keygen, secret-to-public conversion, calculating shared secrets. */ export interface ECDH { keygen: (seed?: Uint8Array) => { secretKey: Uint8Array; publicKey: Uint8Array; }; getPublicKey: (secretKey: Uint8Array, isCompressed?: boolean) => Uint8Array; getSharedSecret: (secretKeyA: Uint8Array, publicKeyB: Uint8Array, isCompressed?: boolean) => Uint8Array; Point: WeierstrassPointCons; utils: { isValidSecretKey: (secretKey: Uint8Array) => boolean; isValidPublicKey: (publicKey: Uint8Array, isCompressed?: boolean) => boolean; randomSecretKey: (seed?: Uint8Array) => Uint8Array; }; lengths: CurveLengths; } /** * ECDSA interface. * Only supported for prime fields, not Fp2 (extension fields). */ export interface ECDSA extends ECDH { sign: (message: Uint8Array, secretKey: Uint8Array, opts?: ECDSASignOpts) => Uint8Array; verify: (signature: Uint8Array, message: Uint8Array, publicKey: Uint8Array, opts?: ECDSAVerifyOpts) => boolean; recoverPublicKey(signature: Uint8Array, message: Uint8Array, opts?: ECDSARecoverOpts): Uint8Array; Signature: ECDSASignatureCons; } export declare class DERErr extends Error { constructor(m?: string); } export type IDER = { Err: typeof DERErr; _tlv: { encode: (tag: number, data: string) => string; decode(tag: number, data: Uint8Array): { v: Uint8Array; l: Uint8Array; }; }; _int: { encode(num: bigint): string; decode(data: Uint8Array): bigint; }; toSig(hex: string | Uint8Array): { r: bigint; s: bigint; }; hexFromSig(sig: { r: bigint; s: bigint; }): string; }; /** * ASN.1 DER encoding utilities. ASN is very complex & fragile. Format: * * [0x30 (SEQUENCE), bytelength, 0x02 (INTEGER), intLength, R, 0x02 (INTEGER), intLength, S] * * Docs: https://letsencrypt.org/docs/a-warm-welcome-to-asn1-and-der/, https://luca.ntop.org/Teaching/Appunti/asn1.html */ export declare const DER: IDER; /** * Creates weierstrass Point constructor, based on specified curve options. * * See {@link WeierstrassOpts}. * * @example ```js const opts = { p: 0xfffffffffffffffffffffffffffffffeffffac73n, n: 0x100000000000000000001b8fa16dfab9aca16b6b3n, h: 1n, a: 0n, b: 7n, Gx: 0x3b4c382ce37aa192a4019e763036f4f5dd4d7ebbn, Gy: 0x938cf935318fdced6bc28286531733c3f03c4feen, }; const secp160k1_Point = weierstrass(opts); ``` */ export declare function weierstrass(params: WeierstrassOpts, extraOpts?: WeierstrassExtraOpts): WeierstrassPointCons; /** Methods of ECDSA signature instance. */ export interface ECDSASignature { readonly r: bigint; readonly s: bigint; readonly recovery?: number; addRecoveryBit(recovery: number): ECDSASignature & { readonly recovery: number; }; hasHighS(): boolean; recoverPublicKey(messageHash: Uint8Array): WeierstrassPoint; toBytes(format?: string): Uint8Array; toHex(format?: string): string; } /** Methods of ECDSA signature constructor. */ export type ECDSASignatureCons = { new (r: bigint, s: bigint, recovery?: number): ECDSASignature; fromBytes(bytes: Uint8Array, format?: ECDSASignatureFormat): ECDSASignature; fromHex(hex: string, format?: ECDSASignatureFormat): ECDSASignature; }; /** * Implementation of the Shallue and van de Woestijne method for any weierstrass curve. * TODO: check if there is a way to merge this with uvRatio in Edwards; move to modular. * b = True and y = sqrt(u / v) if (u / v) is square in F, and * b = False and y = sqrt(Z * (u / v)) otherwise. * @param Fp * @param Z * @returns */ export declare function SWUFpSqrtRatio(Fp: IField, Z: T): (u: T, v: T) => { isValid: boolean; value: T; }; /** * Simplified Shallue-van de Woestijne-Ulas Method * https://www.rfc-editor.org/rfc/rfc9380#section-6.6.2 */ export declare function mapToCurveSimpleSWU(Fp: IField, opts: { A: T; B: T; Z: T; }): (u: T) => { x: T; y: T; }; /** * Sometimes users only need getPublicKey, getSharedSecret, and secret key handling. * This helper ensures no signature functionality is present. Less code, smaller bundle size. */ export declare function ecdh(Point: WeierstrassPointCons, ecdhOpts?: { randomBytes?: (bytesLength?: number) => Uint8Array; }): ECDH; /** * Creates ECDSA signing interface for given elliptic curve `Point` and `hash` function. * * @param Point created using {@link weierstrass} function * @param hash used for 1) message prehash-ing 2) k generation in `sign`, using hmac_drbg(hash) * @param ecdsaOpts rarely needed, see {@link ECDSAOpts} * * @example * ```js * const p256_Point = weierstrass(...); * const p256_sha256 = ecdsa(p256_Point, sha256); * const p256_sha224 = ecdsa(p256_Point, sha224); * const p256_sha224_r = ecdsa(p256_Point, sha224, { randomBytes: (length) => { ... } }); * ``` */ export declare function ecdsa(Point: WeierstrassPointCons, hash: CHash, ecdsaOpts?: ECDSAOpts): ECDSA; //# sourceMappingURL=weierstrass.d.ts.map