/** * Utils for modular division and fields. * Field over 11 is a finite (Galois) field is integer number operations `mod 11`. * There is no division: it is replaced by modular multiplicative inverse. * @module */ /*! noble-curves - MIT License (c) 2022 Paul Miller (paulmillr.com) */ import { type TArg, type TRet } from '../utils.ts'; /** * @param a - Dividend value. * @param b - Positive modulus. * @returns Reduced value in `[0, b)` only when `b` is positive. * @throws If the modulus is not positive. {@link Error} * @example * Normalize a bigint into one field residue. * * ```ts * mod(-1n, 5n); * ``` */ export declare function mod(a: bigint, b: bigint): bigint; /** * Efficiently raise num to a power with modular reduction. * Unsafe in some contexts: uses ladder, so can expose bigint bits. * Low-level helper: callers that need canonical residues must pass a valid `num` for the chosen * modulus instead of relying on the `power===0/1` fast paths to normalize it. * @param num - Base value. * @param power - Exponent value. * @param modulo - Reduction modulus. * @returns Modular exponentiation result. * @throws If the modulus or exponent is invalid. {@link Error} * @example * Raise one bigint to a modular power. * * ```ts * pow(2n, 6n, 11n) // 64n % 11n == 9n * ``` */ export declare function pow(num: bigint, power: bigint, modulo: bigint): bigint; /** * Does `x^(2^power)` mod p. `pow2(30, 4)` == `30^(2^4)`. * Low-level helper: callers that need canonical residues must pass a valid `x` for the chosen * modulus; the `power===0` fast path intentionally returns the input unchanged. * @param x - Base value. * @param power - Number of squarings. * @param modulo - Reduction modulus. * @returns Repeated-squaring result. * @throws If the exponent is negative. {@link Error} * @example * Apply repeated squaring inside one field. * * ```ts * pow2(3n, 2n, 11n); * ``` */ export declare function pow2(x: bigint, power: bigint, modulo: bigint): bigint; /** * Inverses number over modulo. * Implemented using the {@link https://brilliant.org/wiki/extended-euclidean-algorithm/ | extended Euclidean algorithm}. * @param number - Value to invert. * @param modulo - Positive modulus. * @returns Multiplicative inverse. * @throws If the modulus is invalid or the inverse does not exist. {@link Error} * @example * Compute one modular inverse with the extended Euclidean algorithm. * * ```ts * invert(3n, 11n); * ``` */ export declare function invert(number: bigint, modulo: bigint): bigint; /** * Tonelli-Shanks square root search algorithm. * This implementation is variable-time: it searches data-dependently for the first non-residue `Z` * and for the smallest `i` in the main loop, unlike RFC 9380 Appendix I.4's constant-time shape. * 1. {@link https://eprint.iacr.org/2012/685.pdf | eprint 2012/685}, page 12 * 2. Square Roots from 1; 24, 51, 10 to Dan Shanks * @param P - field order * @returns function that takes field Fp (created from P) and number n * @throws If the field is too small, non-prime, or the square root does not exist. {@link Error} * @example * Construct a square-root helper for primes that need Tonelli-Shanks. * * ```ts * import { Field, tonelliShanks } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const sqrt = tonelliShanks(17n)(Fp, 4n); * ``` */ export declare function tonelliShanks(P: bigint): TRet<((Fp: IField, n: T) => T)>; /** * Square root for a finite field. Will try optimized versions first: * * 1. P ≡ 3 (mod 4) * 2. P ≡ 5 (mod 8) * 3. P ≡ 9 (mod 16) * 4. Tonelli-Shanks algorithm * * Different algorithms can give different roots, it is up to user to decide which one they want. * For example there is FpSqrtOdd/FpSqrtEven to choose a root by oddness * (used for hash-to-curve). * @param P - Field order. * @returns Square-root helper. The generic fallback inherits Tonelli-Shanks' variable-time * behavior and this selector assumes prime-field-style integer moduli. * @throws If the field is unsupported or the square root does not exist. {@link Error} * @example * Choose the square-root helper appropriate for one field modulus. * * ```ts * import { Field, FpSqrt } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const sqrt = FpSqrt(17n)(Fp, 4n); * ``` */ export declare function FpSqrt(P: bigint): TRet<((Fp: IField, n: T) => T)>; /** * @param num - Value to inspect. * @param modulo - Field modulus. * @returns `true` when the least-significant little-endian bit is set. * @throws If the modulus is invalid for `mod(...)`. {@link Error} * @example * Inspect the low bit used by little-endian sign conventions. * * ```ts * isNegativeLE(3n, 11n); * ``` */ export declare const isNegativeLE: (num: bigint, modulo: bigint) => boolean; /** Generic field interface used by prime and extension fields alike. * Generic helpers treat field operations as pure functions: implementations MUST treat provided * values/byte buffers as read-only and return detached results instead of mutating arguments. */ export interface IField { /** Field order `q`, which may be prime or a prime power. */ ORDER: bigint; /** Canonical encoded byte length. */ BYTES: number; /** Canonical encoded bit length. */ BITS: number; /** Whether encoded field elements use little-endian bytes. */ isLE: boolean; /** Additive identity. */ ZERO: T; /** Multiplicative identity. */ ONE: T; /** * Normalize one value into the field. * @param num - Input value. * @returns Normalized field value. */ create: (num: T) => T; /** * Check whether one value already belongs to the field. * @param num - Input value. * Implementations may throw `TypeError` on malformed input types instead of returning `false`. * @returns Whether the value already belongs to the field. */ isValid: (num: T) => boolean; /** * Check whether one value is zero. * @param num - Input value. * @returns Whether the value is zero. */ is0: (num: T) => boolean; /** * Check whether one value is non-zero and belongs to the field. * @param num - Input value. * Implementations may throw `TypeError` on malformed input types instead of returning `false`. * @returns Whether the value is non-zero and valid. */ isValidNot0: (num: T) => boolean; /** * Negate one value. * @param num - Input value. * @returns Negated value. */ neg(num: T): T; /** * Invert one value multiplicatively. * @param num - Input value. * @returns Multiplicative inverse. */ inv(num: T): T; /** * Compute one square root when it exists. * @param num - Input value. * @returns Square root. */ sqrt(num: T): T; /** * Square one value. * @param num - Input value. * @returns Squared value. */ sqr(num: T): T; /** * Compare two field values. * @param lhs - Left value. * @param rhs - Right value. * @returns Whether both values are equal. */ eql(lhs: T, rhs: T): boolean; /** * Add two normalized field values. * @param lhs - Left value. * @param rhs - Right value. * @returns Sum value. */ add(lhs: T, rhs: T): T; /** * Subtract two normalized field values. * @param lhs - Left value. * @param rhs - Right value. * @returns Difference value. */ sub(lhs: T, rhs: T): T; /** * Multiply two field values. * @param lhs - Left value. * @param rhs - Right value or scalar. * @returns Product value. */ mul(lhs: T, rhs: T | bigint): T; /** * Raise one field value to a power. * @param lhs - Base value. * @param power - Exponent. * @returns Power value. */ pow(lhs: T, power: bigint): T; /** * Divide one field value by another. * @param lhs - Dividend. * @param rhs - Divisor or scalar. * @returns Quotient value. */ div(lhs: T, rhs: T | bigint): T; /** * Add two values without re-normalizing the result. * @param lhs - Left value. * @param rhs - Right value. * @returns Non-normalized sum. */ addN(lhs: T, rhs: T): T; /** * Subtract two values without re-normalizing the result. * @param lhs - Left value. * @param rhs - Right value. * @returns Non-normalized difference. */ subN(lhs: T, rhs: T): T; /** * Multiply two values without re-normalizing the result. * @param lhs - Left value. * @param rhs - Right value or scalar. * @returns Non-normalized product. */ mulN(lhs: T, rhs: T | bigint): T; /** * Square one value without re-normalizing the result. * @param num - Input value. * @returns Non-normalized square. */ sqrN(num: T): T; /** * Return the RFC 9380 `sgn0`-style oddness bit when supported. * This uses oddness instead of evenness so extension fields like Fp2 can expose the same hook. * Returns whether the value is odd under the field encoding. */ isOdd?(num: T): boolean; /** * Invert many field elements in one batch. * @param lst - Values to invert. * @returns Batch of inverses. */ invertBatch: (lst: T[]) => T[]; /** * Encode one field value into fixed-width bytes. * Callers that need canonical encodings MUST supply a valid field element. * Low-level protocols may also use this to serialize raw / non-canonical residues. * @param num - Input value. * @returns Fixed-width byte encoding. */ toBytes(num: T): Uint8Array; /** * Decode one field value from fixed-width bytes. * @param bytes - Fixed-width byte encoding. * @param skipValidation - Whether to skip range validation. * Implementations MUST treat `bytes` as read-only. * @returns Decoded field value. */ fromBytes(bytes: Uint8Array, skipValidation?: boolean): T; /** * Constant-time conditional move. * @param a - Value used when the condition is false. * @param b - Value used when the condition is true. * @param c - Selection bit. * @returns Selected value. */ cmov(a: T, b: T, c: boolean): T; } /** * @param field - Field implementation. * @returns Validated field. This only checks the arithmetic subset needed by generic helpers; it * does not guarantee full runtime-method coverage for serialization, batching, `cmov`, or * field-specific extras beyond positive `BYTES` / `BITS`. * @throws If the field shape or numeric metadata are invalid. {@link Error} * @example * Check that a field implementation exposes the operations curve code expects. * * ```ts * import { Field, validateField } from '@noble/curves/abstract/modular.js'; * const Fp = validateField(Field(17n)); * ``` */ export declare function validateField(field: TArg>): TRet>; /** * Same as `pow` but for Fp: non-constant-time. * Unsafe in some contexts: uses ladder, so can expose bigint bits. * @param Fp - Field implementation. * @param num - Base value. * @param power - Exponent value. * @returns Powered field element. * @throws If the exponent is negative. {@link Error} * @example * Raise one field element to a public exponent. * * ```ts * import { Field, FpPow } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const x = FpPow(Fp, 3n, 5n); * ``` */ export declare function FpPow(Fp: TArg>, num: T, power: bigint): T; /** * Efficiently invert an array of Field elements. * Exception-free. Zero-valued field elements stay `undefined` unless `passZero` is enabled. * @param Fp - Field implementation. * @param nums - Values to invert. * @param passZero - map 0 to 0 (instead of undefined) * @returns Inverted values. * @example * Invert several field elements with one shared inversion. * * ```ts * import { Field, FpInvertBatch } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const inv = FpInvertBatch(Fp, [1n, 2n, 4n]); * ``` */ export declare function FpInvertBatch(Fp: TArg>, nums: T[], passZero?: boolean): T[]; /** * @param Fp - Field implementation. * @param lhs - Dividend value. * @param rhs - Divisor value. * @returns Division result. * @throws If the divisor is non-invertible. {@link Error} * @example * Divide one field element by another. * * ```ts * import { Field, FpDiv } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const x = FpDiv(Fp, 6n, 3n); * ``` */ export declare function FpDiv(Fp: TArg>, lhs: T, rhs: T | bigint): T; /** * Legendre symbol. * Legendre constant is used to calculate Legendre symbol (a | p) * which denotes the value of a^((p-1)/2) (mod p). * * * (a | p) ≡ 1 if a is a square (mod p), quadratic residue * * (a | p) ≡ -1 if a is not a square (mod p), quadratic non residue * * (a | p) ≡ 0 if a ≡ 0 (mod p) * @param Fp - Field implementation. * @param n - Value to inspect. * @returns Legendre symbol. * @throws If the field returns an invalid Legendre symbol value. {@link Error} * @example * Compute the Legendre symbol of one field element. * * ```ts * import { Field, FpLegendre } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const symbol = FpLegendre(Fp, 4n); * ``` */ export declare function FpLegendre(Fp: TArg>, n: T): -1 | 0 | 1; /** * @param Fp - Field implementation. * @param n - Value to inspect. * @returns `true` when `Fp.sqrt(n)` exists. This includes `0`, even though strict "quadratic * residue" terminology often reserves that name for the non-zero square class. * @throws If the field returns an invalid Legendre symbol value. {@link Error} * @example * Check whether one field element has a square root in the field. * * ```ts * import { Field, FpIsSquare } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const isSquare = FpIsSquare(Fp, 4n); * ``` */ export declare function FpIsSquare(Fp: TArg>, n: T): boolean; /** Byte and bit lengths derived from one scalar order. */ export type NLength = { /** Canonical byte length. */ nByteLength: number; /** Canonical bit length. */ nBitLength: number; }; /** * @param n - Curve order. Callers are expected to pass a positive order. * @param nBitLength - Optional cached bit length. Callers are expected to pass a positive cached * value when overriding the derived bit length. * @returns Byte and bit lengths. * @throws If the order or cached bit length is invalid. {@link Error} * @example * Measure the encoding sizes needed for one modulus. * * ```ts * nLength(255n); * ``` */ export declare function nLength(n: bigint, nBitLength?: number): NLength; type FpField = IField & Required, 'isOdd'>>; type SqrtFn = (n: bigint) => bigint; type FieldOpts = Partial<{ isLE: boolean; BITS: number; sqrt: SqrtFn; allowedLengths?: readonly number[]; modFromBytes: boolean; }>; /** * Creates a finite field. Major performance optimizations: * * 1. Denormalized operations like mulN instead of mul. * * 2. Identical object shape: never add or remove keys. * * 3. Frozen stable object shape; the lazy sqrt cache lives in a module-level `WeakMap`. * Fragile: always run a benchmark on a change. * Security note: operations and low-level serializers like `toBytes` don't check `isValid` for * all elements for performance and protocol-flexibility reasons; callers are responsible for * supplying valid elements when they need canonical field behavior. * This is low-level code, please make sure you know what you're doing. * * Note about field properties: * * CHARACTERISTIC p = prime number, number of elements in main subgroup. * * ORDER q = similar to cofactor in curves, may be composite `q = p^m`. * * @param ORDER - field order, probably prime, or could be composite * @param opts - Field options such as bit length or endianness. See {@link FieldOpts}. * @returns Frozen field instance with a stable object shape. This wrapper forwards `opts` straight * into `_Field`, so it inherits `_Field`'s assumptions about cached sizes and `allowedLengths`. * @example * Construct one prime field with optional overrides. * * ```ts * Field(11n); * ``` */ export declare function Field(ORDER: bigint, opts?: FieldOpts): TRet>; /** * @param Fp - Field implementation. * @param elm - Value to square-root. * @returns Odd square root when two roots exist. The special case `elm = 0` still returns `0`, * which is the only square root but is not odd. * @throws If the field lacks oddness checks or the square root does not exist. {@link Error} * @example * Select the odd square root when two roots exist. * * ```ts * import { Field, FpSqrtOdd } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const root = FpSqrtOdd(Fp, 4n); * ``` */ export declare function FpSqrtOdd(Fp: TArg>, elm: T): T; /** * @param Fp - Field implementation. * @param elm - Value to square-root. * @returns Even square root. * @throws If the field lacks oddness checks or the square root does not exist. {@link Error} * @example * Select the even square root when two roots exist. * * ```ts * import { Field, FpSqrtEven } from '@noble/curves/abstract/modular.js'; * const Fp = Field(17n); * const root = FpSqrtEven(Fp, 4n); * ``` */ export declare function FpSqrtEven(Fp: TArg>, elm: T): T; /** * Returns total number of bytes consumed by the field element. * For example, 32 bytes for usual 256-bit weierstrass curve. * @param fieldOrder - number of field elements, usually CURVE.n. Callers are expected to pass an * order greater than 1. * @returns byte length of field * @throws If the field order is not a bigint. {@link Error} * @example * Read the fixed-width byte length of one field. * * ```ts * getFieldBytesLength(255n); * ``` */ export declare function getFieldBytesLength(fieldOrder: bigint): number; /** * Returns minimal amount of bytes that can be safely reduced * by field order. * Should be 2^-128 for 128-bit curve such as P256. * This is the reduction / modulo-bias lower bound; higher-level helpers may still impose a larger * absolute floor for policy reasons. * @param fieldOrder - number of field elements greater than 1, usually CURVE.n. * @returns byte length of target hash * @throws If the field order is invalid. {@link Error} * @example * Compute the minimum hash length needed for field reduction. * * ```ts * getMinHashLength(255n); * ``` */ export declare function getMinHashLength(fieldOrder: bigint): number; /** * "Constant-time" private key generation utility. * Can take (n + n/2) or more bytes of uniform input e.g. from CSPRNG or KDF * and convert them into private scalar, with the modulo bias being negligible. * Needs at least 48 bytes of input for 32-byte private key. The implementation also keeps a hard * 16-byte minimum even when `getMinHashLength(...)` is smaller, so toy-small inputs do not look * accidentally acceptable for real scalar derivation. * See {@link https://research.kudelskisecurity.com/2020/07/28/the-definitive-guide-to-modulo-bias-and-how-to-avoid-it/ | Kudelski's modulo-bias guide}, * {@link https://csrc.nist.gov/publications/detail/fips/186/5/final | FIPS 186-5 appendix A.2}, and * {@link https://www.rfc-editor.org/rfc/rfc9380#section-5 | RFC 9380 section 5}. Unlike RFC 9380 * `hash_to_field`, this helper intentionally maps into the non-zero private-scalar range `1..n-1`. * @param key - Uniform input bytes. * @param fieldOrder - Size of subgroup. * @param isLE - interpret hash bytes as LE num * @returns valid private scalar * @throws If the hash length or field order is invalid for scalar reduction. {@link Error} * @example * Map hash output into a private scalar range. * * ```ts * mapHashToField(new Uint8Array(48).fill(1), 255n); * ``` */ export declare function mapHashToField(key: TArg, fieldOrder: bigint, isLE?: boolean): TRet; export {}; //# sourceMappingURL=modular.d.ts.map