weierstrass: bits2int, int2octets, truncateHash now comply with standard

src/abstract/utils.ts

@@ -116,6 +116,12 @@ export function bytesToNumberLE(uint8a: Uint8Array): bigint {
 export const numberToBytesBE = (n: bigint, len: number) =>
   hexToBytes(n.toString(16).padStart(len * 2, '0'));
 export const numberToBytesLE = (n: bigint, len: number) => numberToBytesBE(n, len).reverse();
+// Returns variable number bytes (minimal bigint encoding?)
+export const numberToVarBytesBE = (n: bigint) => {
+  let hex = n.toString(16);
+  if (hex.length & 1) hex = '0' + hex;
+  return hexToBytes(hex);
+};
 
 export function ensureBytes(hex: Hex, expectedLength?: number): Uint8Array {
   // Uint8Array.from() instead of hash.slice() because node.js Buffer

src/abstract/weierstrass.ts

@@ -708,7 +708,7 @@ export type CurveType = BasicCurve<bigint> & {
   hash: ut.CHash; // Because we need outputLen for DRBG
   hmac: HmacFnSync;
   randomBytes: (bytesLength?: number) => Uint8Array;
-  truncateHash?: (hash: Uint8Array, truncateOnly?: boolean) => bigint;
+  truncateHash?: (hash: Uint8Array, truncateOnly?: boolean) => Uint8Array;
 };
 
 function validateOpts(curve: CurveType) {
@@ -881,18 +881,15 @@ export function weierstrass(curveDef: CurveType): CurveFn {
     return isBiggerThanHalfOrder(s) ? mod.mod(-s, CURVE_ORDER) : s;
   }
 
-  function bits2int_2(bytes: Uint8Array): bigint {
-    const delta = bytes.length * 8 - CURVE.nBitLength;
-    const num = ut.bytesToNumberBE(bytes);
-    return delta > 0 ? num >> BigInt(delta) : num;
-  }
-
   // Ensures ECDSA message hashes are 32 bytes and < curve order
-  function _truncateHash(hash: Uint8Array, truncateOnly = false): bigint {
-    const h = bits2int_2(hash);
-    if (truncateOnly) return h;
-    const { n } = CURVE;
-    return h >= n ? h - n : h;
+  // RFC6979 suggest optional truncating via bits2octets
+  // FIPS 186-4 Section 4.6 suggest the leftmost min(N, outlen) bits, where N = nBitLength, which is exactly what bits2int does
+  // However, result of bits2int can be higher than order, but since there is same amount of bits, modulo operation
+  // can be done via 'h >= n ? h - n : h'.
+  // But we cannot use int2octets, since it pads small hash with zeros which should not happen on truncate as per RFC6979 vectors
+  function _truncateHash(hash: Uint8Array, truncateOnly = false): Uint8Array {
+    const num = bits2int(hash);
+    return ut.numberToVarBytesBE(truncateOnly ? num : mod.mod(num, CURVE_ORDER)); // same as bits2octets but without zero padding
   }
   const truncateHash = CURVE.truncateHash || _truncateHash;
 
@@ -956,7 +953,7 @@ export function weierstrass(curveDef: CurveType): CurveFn {
       const { r, s, recovery } = this;
       if (recovery == null) throw new Error('Cannot recover: recovery bit is not present');
       if (![0, 1, 2, 3].includes(recovery)) throw new Error('Cannot recover: invalid recovery bit');
-      const h = truncateHash(ut.ensureBytes(msgHash));
+      const h = ut.bytesToNumberBE(truncateHash(ut.ensureBytes(msgHash)));
       const { n } = CURVE;
       const radj = recovery === 2 || recovery === 3 ? r + n : r;
       if (radj >= Fp.ORDER) throw new Error('Cannot recover: bit 2/3 is invalid with current r');
@@ -1099,38 +1096,42 @@ export function weierstrass(curveDef: CurveType): CurveFn {
 
   // RFC6979 methods
   function bits2int(bytes: Uint8Array): bigint {
-    const { nByteLength } = CURVE;
-    if (!(bytes instanceof Uint8Array)) throw new Error('Expected Uint8Array');
-    const slice = bytes.length > nByteLength ? bytes.slice(0, nByteLength) : bytes;
-    // const slice = bytes; nByteLength; nBitLength;
-    let num = ut.bytesToNumberBE(slice);
-    // const { nBitLength } = CURVE;
-    // const delta = (bytes.length * 8) - nBitLength;
-    // if (delta > 0) {
-    //   // console.log('bits=', bytes.length*8, 'CURVE n=', nBitLength, 'delta=', delta);
-    //   // console.log(bytes.length, nBitLength, delta);
-    //   // console.log(bytes, new Error().stack);
-    //   num >>= BigInt(delta);
-    // }
-    return num;
-  }
-  function bits2octets(bytes: Uint8Array): Uint8Array {
-    const z1 = bits2int(bytes);
-    const z2 = mod.mod(z1, CURVE_ORDER);
-    return int2octets(z2 < _0n ? z1 : z2);
+    // Truncate to nBitLength leftmost bits (kinda)
+    // NOTE: for curves with nBitLength % 8 !== 0: bits2octets(bits2octets(hash)) !== bits2octets(hash)
+    // for some cases, because bytes.length * 8 is not actual bitLength.
+    const delta = bytes.length * 8 - CURVE.nBitLength;
+    const num = ut.bytesToNumberBE(bytes);
+    return delta > 0 ? num >> BigInt(delta) : num;
   }
+  // NOTE: pads output with zero as per spec
+  const ORDER_MASK = ut.bitMask(CURVE.nBitLength);
   function int2octets(num: bigint): Uint8Array {
-    return numToField(num); // prohibits >nByteLength bytes
+    if (typeof num !== 'bigint') throw new Error('Expected bigint');
+    if (!(_0n <= num && num < ORDER_MASK))
+      throw new Error(`Expected number < 2^${CURVE.nBitLength}`);
+    return ut.numberToBytesBE(num, CURVE.nByteLength); // works with order, can have different size than numToField!
   }
   // Steps A, D of RFC6979 3.2
   // Creates RFC6979 seed; converts msg/privKey to numbers.
+  // Used only in sign, not in verify.
+  // NOTE: we cannot assume here that msgHash has same amount of bytes as curve order, this will be wrong at least for P521.
+  // Also it can be bigger for P224 + SHA256
   function initSigArgs(msgHash: Hex, privateKey: PrivKey, extraEntropy?: Entropy) {
     if (msgHash == null) throw new Error(`sign: expected valid message hash, not "${msgHash}"`);
     // Step A is ignored, since we already provide hash instead of msg
-    const h1 = numToField(truncateHash(ut.ensureBytes(msgHash)));
+
+    // NOTE: instead of bits2int, we calling here truncateHash, since we need
+    // custom truncation for stark. For other curves it is essentially same as calling bits2int + mod
+    // However, we cannot later call bits2octets (which is truncateHash + int2octets), since nested bits2int is broken
+    // for curves where nBitLength % 8 !== 0, so we unwrap it here as int2octets call.
+    // const bits2octets = (bits)=>int2octets(ut.bytesToNumberBE(truncateHash(bits)))
+    const h1 = truncateHash(ut.ensureBytes(msgHash));
+    const h1int = ut.bytesToNumberBE(h1);
+    const h1octets = int2octets(h1int);
+
     const d = normalizePrivateKey(privateKey);
     // K = HMAC_K(V || 0x00 || int2octets(x) || bits2octets(h1) || k')
-    const seedArgs = [int2octets(d), bits2octets(h1)];
+    const seedArgs = [int2octets(d), h1octets];
     // RFC6979 3.6: additional k' could be provided
     if (extraEntropy != null) {
       if (extraEntropy === true) extraEntropy = CURVE.randomBytes(Fp.BYTES);
@@ -1142,7 +1143,7 @@ export function weierstrass(curveDef: CurveType): CurveFn {
     // Step D
     // V, 0x00 are done in HmacDRBG constructor.
     const seed = ut.concatBytes(...seedArgs);
-    const m = bits2int(h1);
+    const m = h1int; // NOTE: no need to call bits2int second time here, it is inside truncateHash!
     return { seed, m, d };
   }
 
@@ -1156,7 +1157,8 @@ export function weierstrass(curveDef: CurveType): CurveFn {
    */
   function kmdToSig(kBytes: Uint8Array, m: bigint, d: bigint, lowS = true): Signature | undefined {
     const { n } = CURVE;
-    const k = truncateHash(kBytes, true);
+    // RFC 6979 Section 3.2, step 3: k = bits2int(T)
+    const k = ut.bytesToNumberBE(truncateHash(kBytes, true)); // Cannot use fields methods, since it is group element
     if (!isWithinCurveOrder(k)) return;
     // Important: all mod() calls in the function must be done over `n`
     const kinv = mod.invert(k, n);
@@ -1189,6 +1191,7 @@ export function weierstrass(curveDef: CurveType): CurveFn {
    * ```
    * @param opts `lowS, extraEntropy`
    */
+  // TODO: add opts.prehashed = True, if !opts.prehashed do hash on msg?
   function sign(msgHash: Hex, privKey: PrivKey, opts = defaultSigOpts): Signature {
     // Steps A, D of RFC6979 3.2.
     const { seed, m, d } = initSigArgs(msgHash, privKey, opts.extraEntropy);
@@ -1256,7 +1259,7 @@ export function weierstrass(curveDef: CurveType): CurveFn {
     }
     const { n } = CURVE;
     const { r, s } = signature;
-    const h = truncateHash(msgHash);
+    const h = ut.bytesToNumberBE(truncateHash(msgHash)); // Cannot use fields methods, since it is group element
     const sinv = mod.invert(s, n); // s^-1
     // R = u1⋅G - u2⋅P
     const u1 = mod.mod(h * sinv, n);

src/stark.ts

@@ -3,7 +3,7 @@ import { keccak_256 } from '@noble/hashes/sha3';
 import { sha256 } from '@noble/hashes/sha256';
 import { weierstrass, ProjectivePointType } from './abstract/weierstrass.js';
 import * as cutils from './abstract/utils.js';
-import { Fp } from './abstract/modular.js';
+import { Fp, mod } from './abstract/modular.js';
 import { getHash } from './_shortw_utils.js';
 
 type ProjectivePoint = ProjectivePointType<bigint>;
@@ -31,8 +31,7 @@ export const starkCurve = weierstrass({
   // Default options
   lowS: false,
   ...getHash(sha256),
-  truncateHash: (hash: Uint8Array, truncateOnly = false): bigint => {
-    // TODO: cleanup, ugly code
+  truncateHash: (hash: Uint8Array, truncateOnly = false): Uint8Array => {
     // Fix truncation
     if (!truncateOnly) {
       let hashS = bytesToNumber0x(hash).toString(16);
@@ -43,12 +42,13 @@ export const starkCurve = weierstrass({
     }
     // Truncate zero bytes on left (compat with elliptic)
     while (hash[0] === 0) hash = hash.subarray(1);
+    // bits2int + part of bits2octets (mod if !truncateOnly)
     const byteLength = hash.length;
     const delta = byteLength * 8 - nBitLength; // size of curve.n (252 bits)
     let h = hash.length ? bytesToNumber0x(hash) : 0n;
-    if (delta > 0) h = h >> BigInt(delta);
-    if (!truncateOnly && h >= CURVE_N) h -= CURVE_N;
-    return h;
+    if (delta > 0) h = h >> BigInt(delta); // truncate to nBitLength leftmost bits
+    if (!truncateOnly) h = mod(h, CURVE_N);
+    return cutils.numberToVarBytesBE(h);
   },
 });