594 lines
28 KiB
C
594 lines
28 KiB
C
/***********************************************************************
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* Copyright (c) 2020 Peter Dettman *
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* Distributed under the MIT software license, see the accompanying *
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* file COPYING or https://www.opensource.org/licenses/mit-license.php.*
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**********************************************************************/
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#ifndef SECP256K1_MODINV64_IMPL_H
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#define SECP256K1_MODINV64_IMPL_H
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#include "modinv64.h"
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#include "util.h"
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/* This file implements modular inversion based on the paper "Fast constant-time gcd computation and
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* modular inversion" by Daniel J. Bernstein and Bo-Yin Yang.
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*
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* For an explanation of the algorithm, see doc/safegcd_implementation.md. This file contains an
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* implementation for N=62, using 62-bit signed limbs represented as int64_t.
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*/
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#ifdef VERIFY
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/* Helper function to compute the absolute value of an int64_t.
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* (we don't use abs/labs/llabs as it depends on the int sizes). */
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static int64_t rustsecp256k1_v0_4_1_modinv64_abs(int64_t v) {
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VERIFY_CHECK(v > INT64_MIN);
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if (v < 0) return -v;
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return v;
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}
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static const rustsecp256k1_v0_4_1_modinv64_signed62 SECP256K1_SIGNED62_ONE = {{1}};
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/* Compute a*factor and put it in r. All but the top limb in r will be in range [0,2^62). */
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static void rustsecp256k1_v0_4_1_modinv64_mul_62(rustsecp256k1_v0_4_1_modinv64_signed62 *r, const rustsecp256k1_v0_4_1_modinv64_signed62 *a, int alen, int64_t factor) {
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const int64_t M62 = (int64_t)(UINT64_MAX >> 2);
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int128_t c = 0;
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int i;
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for (i = 0; i < 4; ++i) {
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if (i < alen) c += (int128_t)a->v[i] * factor;
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r->v[i] = (int64_t)c & M62; c >>= 62;
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}
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if (4 < alen) c += (int128_t)a->v[4] * factor;
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VERIFY_CHECK(c == (int64_t)c);
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r->v[4] = (int64_t)c;
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}
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/* Return -1 for a<b*factor, 0 for a==b*factor, 1 for a>b*factor. A has alen limbs; b has 5. */
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static int rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(const rustsecp256k1_v0_4_1_modinv64_signed62 *a, int alen, const rustsecp256k1_v0_4_1_modinv64_signed62 *b, int64_t factor) {
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int i;
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rustsecp256k1_v0_4_1_modinv64_signed62 am, bm;
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rustsecp256k1_v0_4_1_modinv64_mul_62(&am, a, alen, 1); /* Normalize all but the top limb of a. */
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rustsecp256k1_v0_4_1_modinv64_mul_62(&bm, b, 5, factor);
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for (i = 0; i < 4; ++i) {
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/* Verify that all but the top limb of a and b are normalized. */
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VERIFY_CHECK(am.v[i] >> 62 == 0);
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VERIFY_CHECK(bm.v[i] >> 62 == 0);
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}
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for (i = 4; i >= 0; --i) {
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if (am.v[i] < bm.v[i]) return -1;
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if (am.v[i] > bm.v[i]) return 1;
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}
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return 0;
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}
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#endif
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/* Take as input a signed62 number in range (-2*modulus,modulus), and add a multiple of the modulus
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* to it to bring it to range [0,modulus). If sign < 0, the input will also be negated in the
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* process. The input must have limbs in range (-2^62,2^62). The output will have limbs in range
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* [0,2^62). */
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static void rustsecp256k1_v0_4_1_modinv64_normalize_62(rustsecp256k1_v0_4_1_modinv64_signed62 *r, int64_t sign, const rustsecp256k1_v0_4_1_modinv64_modinfo *modinfo) {
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const int64_t M62 = (int64_t)(UINT64_MAX >> 2);
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int64_t r0 = r->v[0], r1 = r->v[1], r2 = r->v[2], r3 = r->v[3], r4 = r->v[4];
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int64_t cond_add, cond_negate;
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#ifdef VERIFY
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/* Verify that all limbs are in range (-2^62,2^62). */
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int i;
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for (i = 0; i < 5; ++i) {
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VERIFY_CHECK(r->v[i] >= -M62);
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VERIFY_CHECK(r->v[i] <= M62);
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}
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(r, 5, &modinfo->modulus, -2) > 0); /* r > -2*modulus */
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(r, 5, &modinfo->modulus, 1) < 0); /* r < modulus */
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#endif
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/* In a first step, add the modulus if the input is negative, and then negate if requested.
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* This brings r from range (-2*modulus,modulus) to range (-modulus,modulus). As all input
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* limbs are in range (-2^62,2^62), this cannot overflow an int64_t. Note that the right
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* shifts below are signed sign-extending shifts (see assumptions.h for tests that that is
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* indeed the behavior of the right shift operator). */
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cond_add = r4 >> 63;
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r0 += modinfo->modulus.v[0] & cond_add;
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r1 += modinfo->modulus.v[1] & cond_add;
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r2 += modinfo->modulus.v[2] & cond_add;
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r3 += modinfo->modulus.v[3] & cond_add;
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r4 += modinfo->modulus.v[4] & cond_add;
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cond_negate = sign >> 63;
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r0 = (r0 ^ cond_negate) - cond_negate;
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r1 = (r1 ^ cond_negate) - cond_negate;
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r2 = (r2 ^ cond_negate) - cond_negate;
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r3 = (r3 ^ cond_negate) - cond_negate;
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r4 = (r4 ^ cond_negate) - cond_negate;
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/* Propagate the top bits, to bring limbs back to range (-2^62,2^62). */
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r1 += r0 >> 62; r0 &= M62;
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r2 += r1 >> 62; r1 &= M62;
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r3 += r2 >> 62; r2 &= M62;
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r4 += r3 >> 62; r3 &= M62;
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/* In a second step add the modulus again if the result is still negative, bringing
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* r to range [0,modulus). */
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cond_add = r4 >> 63;
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r0 += modinfo->modulus.v[0] & cond_add;
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r1 += modinfo->modulus.v[1] & cond_add;
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r2 += modinfo->modulus.v[2] & cond_add;
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r3 += modinfo->modulus.v[3] & cond_add;
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r4 += modinfo->modulus.v[4] & cond_add;
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/* And propagate again. */
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r1 += r0 >> 62; r0 &= M62;
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r2 += r1 >> 62; r1 &= M62;
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r3 += r2 >> 62; r2 &= M62;
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r4 += r3 >> 62; r3 &= M62;
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r->v[0] = r0;
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r->v[1] = r1;
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r->v[2] = r2;
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r->v[3] = r3;
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r->v[4] = r4;
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#ifdef VERIFY
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VERIFY_CHECK(r0 >> 62 == 0);
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VERIFY_CHECK(r1 >> 62 == 0);
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VERIFY_CHECK(r2 >> 62 == 0);
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VERIFY_CHECK(r3 >> 62 == 0);
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VERIFY_CHECK(r4 >> 62 == 0);
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(r, 5, &modinfo->modulus, 0) >= 0); /* r >= 0 */
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(r, 5, &modinfo->modulus, 1) < 0); /* r < modulus */
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#endif
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}
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/* Data type for transition matrices (see section 3 of explanation).
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*
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* t = [ u v ]
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* [ q r ]
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*/
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typedef struct {
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int64_t u, v, q, r;
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} rustsecp256k1_v0_4_1_modinv64_trans2x2;
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/* Compute the transition matrix and eta for 59 divsteps (where zeta=-(delta+1/2)).
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* Note that the transformation matrix is scaled by 2^62 and not 2^59.
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*
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* Input: zeta: initial zeta
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* f0: bottom limb of initial f
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* g0: bottom limb of initial g
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* Output: t: transition matrix
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* Return: final zeta
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*
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* Implements the divsteps_n_matrix function from the explanation.
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*/
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static int64_t rustsecp256k1_v0_4_1_modinv64_divsteps_59(int64_t zeta, uint64_t f0, uint64_t g0, rustsecp256k1_v0_4_1_modinv64_trans2x2 *t) {
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/* u,v,q,r are the elements of the transformation matrix being built up,
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* starting with the identity matrix times 8 (because the caller expects
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* a result scaled by 2^62). Semantically they are signed integers
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* in range [-2^62,2^62], but here represented as unsigned mod 2^64. This
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* permits left shifting (which is UB for negative numbers). The range
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* being inside [-2^63,2^63) means that casting to signed works correctly.
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*/
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uint64_t u = 8, v = 0, q = 0, r = 8;
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uint64_t c1, c2, f = f0, g = g0, x, y, z;
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int i;
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for (i = 3; i < 62; ++i) {
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VERIFY_CHECK((f & 1) == 1); /* f must always be odd */
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VERIFY_CHECK((u * f0 + v * g0) == f << i);
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VERIFY_CHECK((q * f0 + r * g0) == g << i);
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/* Compute conditional masks for (zeta < 0) and for (g & 1). */
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c1 = zeta >> 63;
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c2 = -(g & 1);
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/* Compute x,y,z, conditionally negated versions of f,u,v. */
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x = (f ^ c1) - c1;
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y = (u ^ c1) - c1;
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z = (v ^ c1) - c1;
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/* Conditionally add x,y,z to g,q,r. */
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g += x & c2;
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q += y & c2;
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r += z & c2;
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/* In what follows, c1 is a condition mask for (zeta < 0) and (g & 1). */
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c1 &= c2;
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/* Conditionally change zeta into -zeta-2 or zeta-1. */
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zeta = (zeta ^ c1) - 1;
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/* Conditionally add g,q,r to f,u,v. */
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f += g & c1;
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u += q & c1;
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v += r & c1;
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/* Shifts */
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g >>= 1;
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u <<= 1;
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v <<= 1;
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/* Bounds on zeta that follow from the bounds on iteration count (max 10*59 divsteps). */
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VERIFY_CHECK(zeta >= -591 && zeta <= 591);
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}
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/* Return data in t and return value. */
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t->u = (int64_t)u;
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t->v = (int64_t)v;
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t->q = (int64_t)q;
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t->r = (int64_t)r;
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/* The determinant of t must be a power of two. This guarantees that multiplication with t
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* does not change the gcd of f and g, apart from adding a power-of-2 factor to it (which
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* will be divided out again). As each divstep's individual matrix has determinant 2, the
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* aggregate of 59 of them will have determinant 2^59. Multiplying with the initial
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* 8*identity (which has determinant 2^6) means the overall outputs has determinant
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* 2^65. */
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VERIFY_CHECK((int128_t)t->u * t->r - (int128_t)t->v * t->q == ((int128_t)1) << 65);
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return zeta;
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}
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/* Compute the transition matrix and eta for 62 divsteps (variable time, eta=-delta).
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*
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* Input: eta: initial eta
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* f0: bottom limb of initial f
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* g0: bottom limb of initial g
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* Output: t: transition matrix
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* Return: final eta
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*
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* Implements the divsteps_n_matrix_var function from the explanation.
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*/
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static int64_t rustsecp256k1_v0_4_1_modinv64_divsteps_62_var(int64_t eta, uint64_t f0, uint64_t g0, rustsecp256k1_v0_4_1_modinv64_trans2x2 *t) {
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/* Transformation matrix; see comments in rustsecp256k1_v0_4_1_modinv64_divsteps_62. */
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uint64_t u = 1, v = 0, q = 0, r = 1;
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uint64_t f = f0, g = g0, m;
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uint32_t w;
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int i = 62, limit, zeros;
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for (;;) {
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/* Use a sentinel bit to count zeros only up to i. */
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zeros = rustsecp256k1_v0_4_1_ctz64_var(g | (UINT64_MAX << i));
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/* Perform zeros divsteps at once; they all just divide g by two. */
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g >>= zeros;
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u <<= zeros;
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v <<= zeros;
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eta -= zeros;
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i -= zeros;
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/* We're done once we've done 62 divsteps. */
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if (i == 0) break;
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VERIFY_CHECK((f & 1) == 1);
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VERIFY_CHECK((g & 1) == 1);
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VERIFY_CHECK((u * f0 + v * g0) == f << (62 - i));
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VERIFY_CHECK((q * f0 + r * g0) == g << (62 - i));
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/* Bounds on eta that follow from the bounds on iteration count (max 12*62 divsteps). */
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VERIFY_CHECK(eta >= -745 && eta <= 745);
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/* If eta is negative, negate it and replace f,g with g,-f. */
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if (eta < 0) {
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uint64_t tmp;
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eta = -eta;
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tmp = f; f = g; g = -tmp;
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tmp = u; u = q; q = -tmp;
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tmp = v; v = r; r = -tmp;
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/* Use a formula to cancel out up to 6 bits of g. Also, no more than i can be cancelled
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* out (as we'd be done before that point), and no more than eta+1 can be done as its
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* will flip again once that happens. */
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limit = ((int)eta + 1) > i ? i : ((int)eta + 1);
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VERIFY_CHECK(limit > 0 && limit <= 62);
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/* m is a mask for the bottom min(limit, 6) bits. */
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m = (UINT64_MAX >> (64 - limit)) & 63U;
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/* Find what multiple of f must be added to g to cancel its bottom min(limit, 6)
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* bits. */
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w = (f * g * (f * f - 2)) & m;
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} else {
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/* In this branch, use a simpler formula that only lets us cancel up to 4 bits of g, as
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* eta tends to be smaller here. */
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limit = ((int)eta + 1) > i ? i : ((int)eta + 1);
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VERIFY_CHECK(limit > 0 && limit <= 62);
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/* m is a mask for the bottom min(limit, 4) bits. */
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m = (UINT64_MAX >> (64 - limit)) & 15U;
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/* Find what multiple of f must be added to g to cancel its bottom min(limit, 4)
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* bits. */
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w = f + (((f + 1) & 4) << 1);
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w = (-w * g) & m;
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}
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g += f * w;
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q += u * w;
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r += v * w;
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VERIFY_CHECK((g & m) == 0);
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}
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/* Return data in t and return value. */
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t->u = (int64_t)u;
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t->v = (int64_t)v;
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t->q = (int64_t)q;
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t->r = (int64_t)r;
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/* The determinant of t must be a power of two. This guarantees that multiplication with t
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* does not change the gcd of f and g, apart from adding a power-of-2 factor to it (which
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* will be divided out again). As each divstep's individual matrix has determinant 2, the
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* aggregate of 62 of them will have determinant 2^62. */
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VERIFY_CHECK((int128_t)t->u * t->r - (int128_t)t->v * t->q == ((int128_t)1) << 62);
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return eta;
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}
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/* Compute (t/2^62) * [d, e] mod modulus, where t is a transition matrix scaled by 2^62.
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*
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* On input and output, d and e are in range (-2*modulus,modulus). All output limbs will be in range
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* (-2^62,2^62).
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*
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* This implements the update_de function from the explanation.
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*/
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static void rustsecp256k1_v0_4_1_modinv64_update_de_62(rustsecp256k1_v0_4_1_modinv64_signed62 *d, rustsecp256k1_v0_4_1_modinv64_signed62 *e, const rustsecp256k1_v0_4_1_modinv64_trans2x2 *t, const rustsecp256k1_v0_4_1_modinv64_modinfo* modinfo) {
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const int64_t M62 = (int64_t)(UINT64_MAX >> 2);
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const int64_t d0 = d->v[0], d1 = d->v[1], d2 = d->v[2], d3 = d->v[3], d4 = d->v[4];
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const int64_t e0 = e->v[0], e1 = e->v[1], e2 = e->v[2], e3 = e->v[3], e4 = e->v[4];
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const int64_t u = t->u, v = t->v, q = t->q, r = t->r;
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int64_t md, me, sd, se;
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int128_t cd, ce;
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#ifdef VERIFY
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(d, 5, &modinfo->modulus, -2) > 0); /* d > -2*modulus */
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(d, 5, &modinfo->modulus, 1) < 0); /* d < modulus */
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(e, 5, &modinfo->modulus, -2) > 0); /* e > -2*modulus */
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VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(e, 5, &modinfo->modulus, 1) < 0); /* e < modulus */
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VERIFY_CHECK((rustsecp256k1_v0_4_1_modinv64_abs(u) + rustsecp256k1_v0_4_1_modinv64_abs(v)) >= 0); /* |u|+|v| doesn't overflow */
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VERIFY_CHECK((rustsecp256k1_v0_4_1_modinv64_abs(q) + rustsecp256k1_v0_4_1_modinv64_abs(r)) >= 0); /* |q|+|r| doesn't overflow */
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VERIFY_CHECK((rustsecp256k1_v0_4_1_modinv64_abs(u) + rustsecp256k1_v0_4_1_modinv64_abs(v)) <= M62 + 1); /* |u|+|v| <= 2^62 */
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VERIFY_CHECK((rustsecp256k1_v0_4_1_modinv64_abs(q) + rustsecp256k1_v0_4_1_modinv64_abs(r)) <= M62 + 1); /* |q|+|r| <= 2^62 */
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#endif
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/* [md,me] start as zero; plus [u,q] if d is negative; plus [v,r] if e is negative. */
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sd = d4 >> 63;
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se = e4 >> 63;
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md = (u & sd) + (v & se);
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me = (q & sd) + (r & se);
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/* Begin computing t*[d,e]. */
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cd = (int128_t)u * d0 + (int128_t)v * e0;
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ce = (int128_t)q * d0 + (int128_t)r * e0;
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/* Correct md,me so that t*[d,e]+modulus*[md,me] has 62 zero bottom bits. */
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md -= (modinfo->modulus_inv62 * (uint64_t)cd + md) & M62;
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me -= (modinfo->modulus_inv62 * (uint64_t)ce + me) & M62;
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/* Update the beginning of computation for t*[d,e]+modulus*[md,me] now md,me are known. */
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cd += (int128_t)modinfo->modulus.v[0] * md;
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ce += (int128_t)modinfo->modulus.v[0] * me;
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/* Verify that the low 62 bits of the computation are indeed zero, and then throw them away. */
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VERIFY_CHECK(((int64_t)cd & M62) == 0); cd >>= 62;
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VERIFY_CHECK(((int64_t)ce & M62) == 0); ce >>= 62;
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/* Compute limb 1 of t*[d,e]+modulus*[md,me], and store it as output limb 0 (= down shift). */
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cd += (int128_t)u * d1 + (int128_t)v * e1;
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ce += (int128_t)q * d1 + (int128_t)r * e1;
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if (modinfo->modulus.v[1]) { /* Optimize for the case where limb of modulus is zero. */
|
|
cd += (int128_t)modinfo->modulus.v[1] * md;
|
|
ce += (int128_t)modinfo->modulus.v[1] * me;
|
|
}
|
|
d->v[0] = (int64_t)cd & M62; cd >>= 62;
|
|
e->v[0] = (int64_t)ce & M62; ce >>= 62;
|
|
/* Compute limb 2 of t*[d,e]+modulus*[md,me], and store it as output limb 1. */
|
|
cd += (int128_t)u * d2 + (int128_t)v * e2;
|
|
ce += (int128_t)q * d2 + (int128_t)r * e2;
|
|
if (modinfo->modulus.v[2]) { /* Optimize for the case where limb of modulus is zero. */
|
|
cd += (int128_t)modinfo->modulus.v[2] * md;
|
|
ce += (int128_t)modinfo->modulus.v[2] * me;
|
|
}
|
|
d->v[1] = (int64_t)cd & M62; cd >>= 62;
|
|
e->v[1] = (int64_t)ce & M62; ce >>= 62;
|
|
/* Compute limb 3 of t*[d,e]+modulus*[md,me], and store it as output limb 2. */
|
|
cd += (int128_t)u * d3 + (int128_t)v * e3;
|
|
ce += (int128_t)q * d3 + (int128_t)r * e3;
|
|
if (modinfo->modulus.v[3]) { /* Optimize for the case where limb of modulus is zero. */
|
|
cd += (int128_t)modinfo->modulus.v[3] * md;
|
|
ce += (int128_t)modinfo->modulus.v[3] * me;
|
|
}
|
|
d->v[2] = (int64_t)cd & M62; cd >>= 62;
|
|
e->v[2] = (int64_t)ce & M62; ce >>= 62;
|
|
/* Compute limb 4 of t*[d,e]+modulus*[md,me], and store it as output limb 3. */
|
|
cd += (int128_t)u * d4 + (int128_t)v * e4;
|
|
ce += (int128_t)q * d4 + (int128_t)r * e4;
|
|
cd += (int128_t)modinfo->modulus.v[4] * md;
|
|
ce += (int128_t)modinfo->modulus.v[4] * me;
|
|
d->v[3] = (int64_t)cd & M62; cd >>= 62;
|
|
e->v[3] = (int64_t)ce & M62; ce >>= 62;
|
|
/* What remains is limb 5 of t*[d,e]+modulus*[md,me]; store it as output limb 4. */
|
|
d->v[4] = (int64_t)cd;
|
|
e->v[4] = (int64_t)ce;
|
|
#ifdef VERIFY
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(d, 5, &modinfo->modulus, -2) > 0); /* d > -2*modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(d, 5, &modinfo->modulus, 1) < 0); /* d < modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(e, 5, &modinfo->modulus, -2) > 0); /* e > -2*modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(e, 5, &modinfo->modulus, 1) < 0); /* e < modulus */
|
|
#endif
|
|
}
|
|
|
|
/* Compute (t/2^62) * [f, g], where t is a transition matrix scaled by 2^62.
|
|
*
|
|
* This implements the update_fg function from the explanation.
|
|
*/
|
|
static void rustsecp256k1_v0_4_1_modinv64_update_fg_62(rustsecp256k1_v0_4_1_modinv64_signed62 *f, rustsecp256k1_v0_4_1_modinv64_signed62 *g, const rustsecp256k1_v0_4_1_modinv64_trans2x2 *t) {
|
|
const int64_t M62 = (int64_t)(UINT64_MAX >> 2);
|
|
const int64_t f0 = f->v[0], f1 = f->v[1], f2 = f->v[2], f3 = f->v[3], f4 = f->v[4];
|
|
const int64_t g0 = g->v[0], g1 = g->v[1], g2 = g->v[2], g3 = g->v[3], g4 = g->v[4];
|
|
const int64_t u = t->u, v = t->v, q = t->q, r = t->r;
|
|
int128_t cf, cg;
|
|
/* Start computing t*[f,g]. */
|
|
cf = (int128_t)u * f0 + (int128_t)v * g0;
|
|
cg = (int128_t)q * f0 + (int128_t)r * g0;
|
|
/* Verify that the bottom 62 bits of the result are zero, and then throw them away. */
|
|
VERIFY_CHECK(((int64_t)cf & M62) == 0); cf >>= 62;
|
|
VERIFY_CHECK(((int64_t)cg & M62) == 0); cg >>= 62;
|
|
/* Compute limb 1 of t*[f,g], and store it as output limb 0 (= down shift). */
|
|
cf += (int128_t)u * f1 + (int128_t)v * g1;
|
|
cg += (int128_t)q * f1 + (int128_t)r * g1;
|
|
f->v[0] = (int64_t)cf & M62; cf >>= 62;
|
|
g->v[0] = (int64_t)cg & M62; cg >>= 62;
|
|
/* Compute limb 2 of t*[f,g], and store it as output limb 1. */
|
|
cf += (int128_t)u * f2 + (int128_t)v * g2;
|
|
cg += (int128_t)q * f2 + (int128_t)r * g2;
|
|
f->v[1] = (int64_t)cf & M62; cf >>= 62;
|
|
g->v[1] = (int64_t)cg & M62; cg >>= 62;
|
|
/* Compute limb 3 of t*[f,g], and store it as output limb 2. */
|
|
cf += (int128_t)u * f3 + (int128_t)v * g3;
|
|
cg += (int128_t)q * f3 + (int128_t)r * g3;
|
|
f->v[2] = (int64_t)cf & M62; cf >>= 62;
|
|
g->v[2] = (int64_t)cg & M62; cg >>= 62;
|
|
/* Compute limb 4 of t*[f,g], and store it as output limb 3. */
|
|
cf += (int128_t)u * f4 + (int128_t)v * g4;
|
|
cg += (int128_t)q * f4 + (int128_t)r * g4;
|
|
f->v[3] = (int64_t)cf & M62; cf >>= 62;
|
|
g->v[3] = (int64_t)cg & M62; cg >>= 62;
|
|
/* What remains is limb 5 of t*[f,g]; store it as output limb 4. */
|
|
f->v[4] = (int64_t)cf;
|
|
g->v[4] = (int64_t)cg;
|
|
}
|
|
|
|
/* Compute (t/2^62) * [f, g], where t is a transition matrix for 62 divsteps.
|
|
*
|
|
* Version that operates on a variable number of limbs in f and g.
|
|
*
|
|
* This implements the update_fg function from the explanation.
|
|
*/
|
|
static void rustsecp256k1_v0_4_1_modinv64_update_fg_62_var(int len, rustsecp256k1_v0_4_1_modinv64_signed62 *f, rustsecp256k1_v0_4_1_modinv64_signed62 *g, const rustsecp256k1_v0_4_1_modinv64_trans2x2 *t) {
|
|
const int64_t M62 = (int64_t)(UINT64_MAX >> 2);
|
|
const int64_t u = t->u, v = t->v, q = t->q, r = t->r;
|
|
int64_t fi, gi;
|
|
int128_t cf, cg;
|
|
int i;
|
|
VERIFY_CHECK(len > 0);
|
|
/* Start computing t*[f,g]. */
|
|
fi = f->v[0];
|
|
gi = g->v[0];
|
|
cf = (int128_t)u * fi + (int128_t)v * gi;
|
|
cg = (int128_t)q * fi + (int128_t)r * gi;
|
|
/* Verify that the bottom 62 bits of the result are zero, and then throw them away. */
|
|
VERIFY_CHECK(((int64_t)cf & M62) == 0); cf >>= 62;
|
|
VERIFY_CHECK(((int64_t)cg & M62) == 0); cg >>= 62;
|
|
/* Now iteratively compute limb i=1..len of t*[f,g], and store them in output limb i-1 (shifting
|
|
* down by 62 bits). */
|
|
for (i = 1; i < len; ++i) {
|
|
fi = f->v[i];
|
|
gi = g->v[i];
|
|
cf += (int128_t)u * fi + (int128_t)v * gi;
|
|
cg += (int128_t)q * fi + (int128_t)r * gi;
|
|
f->v[i - 1] = (int64_t)cf & M62; cf >>= 62;
|
|
g->v[i - 1] = (int64_t)cg & M62; cg >>= 62;
|
|
}
|
|
/* What remains is limb (len) of t*[f,g]; store it as output limb (len-1). */
|
|
f->v[len - 1] = (int64_t)cf;
|
|
g->v[len - 1] = (int64_t)cg;
|
|
}
|
|
|
|
/* Compute the inverse of x modulo modinfo->modulus, and replace x with it (constant time in x). */
|
|
static void rustsecp256k1_v0_4_1_modinv64(rustsecp256k1_v0_4_1_modinv64_signed62 *x, const rustsecp256k1_v0_4_1_modinv64_modinfo *modinfo) {
|
|
/* Start with d=0, e=1, f=modulus, g=x, zeta=-1. */
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 d = {{0, 0, 0, 0, 0}};
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 e = {{1, 0, 0, 0, 0}};
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 f = modinfo->modulus;
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 g = *x;
|
|
int i;
|
|
int64_t zeta = -1; /* zeta = -(delta+1/2); delta starts at 1/2. */
|
|
|
|
/* Do 10 iterations of 59 divsteps each = 590 divsteps. This suffices for 256-bit inputs. */
|
|
for (i = 0; i < 10; ++i) {
|
|
/* Compute transition matrix and new zeta after 59 divsteps. */
|
|
rustsecp256k1_v0_4_1_modinv64_trans2x2 t;
|
|
zeta = rustsecp256k1_v0_4_1_modinv64_divsteps_59(zeta, f.v[0], g.v[0], &t);
|
|
/* Update d,e using that transition matrix. */
|
|
rustsecp256k1_v0_4_1_modinv64_update_de_62(&d, &e, &t, modinfo);
|
|
/* Update f,g using that transition matrix. */
|
|
#ifdef VERIFY
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &modinfo->modulus, -1) > 0); /* f > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &modinfo->modulus, 1) <= 0); /* f <= modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, 5, &modinfo->modulus, -1) > 0); /* g > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, 5, &modinfo->modulus, 1) < 0); /* g < modulus */
|
|
#endif
|
|
rustsecp256k1_v0_4_1_modinv64_update_fg_62(&f, &g, &t);
|
|
#ifdef VERIFY
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &modinfo->modulus, -1) > 0); /* f > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &modinfo->modulus, 1) <= 0); /* f <= modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, 5, &modinfo->modulus, -1) > 0); /* g > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, 5, &modinfo->modulus, 1) < 0); /* g < modulus */
|
|
#endif
|
|
}
|
|
|
|
/* At this point sufficient iterations have been performed that g must have reached 0
|
|
* and (if g was not originally 0) f must now equal +/- GCD of the initial f, g
|
|
* values i.e. +/- 1, and d now contains +/- the modular inverse. */
|
|
#ifdef VERIFY
|
|
/* g == 0 */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, 5, &SECP256K1_SIGNED62_ONE, 0) == 0);
|
|
/* |f| == 1, or (x == 0 and d == 0 and |f|=modulus) */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &SECP256K1_SIGNED62_ONE, -1) == 0 ||
|
|
rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &SECP256K1_SIGNED62_ONE, 1) == 0 ||
|
|
(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(x, 5, &SECP256K1_SIGNED62_ONE, 0) == 0 &&
|
|
rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&d, 5, &SECP256K1_SIGNED62_ONE, 0) == 0 &&
|
|
(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &modinfo->modulus, 1) == 0 ||
|
|
rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, 5, &modinfo->modulus, -1) == 0)));
|
|
#endif
|
|
|
|
/* Optionally negate d, normalize to [0,modulus), and return it. */
|
|
rustsecp256k1_v0_4_1_modinv64_normalize_62(&d, f.v[4], modinfo);
|
|
*x = d;
|
|
}
|
|
|
|
/* Compute the inverse of x modulo modinfo->modulus, and replace x with it (variable time). */
|
|
static void rustsecp256k1_v0_4_1_modinv64_var(rustsecp256k1_v0_4_1_modinv64_signed62 *x, const rustsecp256k1_v0_4_1_modinv64_modinfo *modinfo) {
|
|
/* Start with d=0, e=1, f=modulus, g=x, eta=-1. */
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 d = {{0, 0, 0, 0, 0}};
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 e = {{1, 0, 0, 0, 0}};
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 f = modinfo->modulus;
|
|
rustsecp256k1_v0_4_1_modinv64_signed62 g = *x;
|
|
#ifdef VERIFY
|
|
int i = 0;
|
|
#endif
|
|
int j, len = 5;
|
|
int64_t eta = -1; /* eta = -delta; delta is initially 1 */
|
|
int64_t cond, fn, gn;
|
|
|
|
/* Do iterations of 62 divsteps each until g=0. */
|
|
while (1) {
|
|
/* Compute transition matrix and new eta after 62 divsteps. */
|
|
rustsecp256k1_v0_4_1_modinv64_trans2x2 t;
|
|
eta = rustsecp256k1_v0_4_1_modinv64_divsteps_62_var(eta, f.v[0], g.v[0], &t);
|
|
/* Update d,e using that transition matrix. */
|
|
rustsecp256k1_v0_4_1_modinv64_update_de_62(&d, &e, &t, modinfo);
|
|
/* Update f,g using that transition matrix. */
|
|
#ifdef VERIFY
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &modinfo->modulus, -1) > 0); /* f > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &modinfo->modulus, 1) <= 0); /* f <= modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, len, &modinfo->modulus, -1) > 0); /* g > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, len, &modinfo->modulus, 1) < 0); /* g < modulus */
|
|
#endif
|
|
rustsecp256k1_v0_4_1_modinv64_update_fg_62_var(len, &f, &g, &t);
|
|
/* If the bottom limb of g is zero, there is a chance that g=0. */
|
|
if (g.v[0] == 0) {
|
|
cond = 0;
|
|
/* Check if the other limbs are also 0. */
|
|
for (j = 1; j < len; ++j) {
|
|
cond |= g.v[j];
|
|
}
|
|
/* If so, we're done. */
|
|
if (cond == 0) break;
|
|
}
|
|
|
|
/* Determine if len>1 and limb (len-1) of both f and g is 0 or -1. */
|
|
fn = f.v[len - 1];
|
|
gn = g.v[len - 1];
|
|
cond = ((int64_t)len - 2) >> 63;
|
|
cond |= fn ^ (fn >> 63);
|
|
cond |= gn ^ (gn >> 63);
|
|
/* If so, reduce length, propagating the sign of f and g's top limb into the one below. */
|
|
if (cond == 0) {
|
|
f.v[len - 2] |= (uint64_t)fn << 62;
|
|
g.v[len - 2] |= (uint64_t)gn << 62;
|
|
--len;
|
|
}
|
|
#ifdef VERIFY
|
|
VERIFY_CHECK(++i < 12); /* We should never need more than 12*62 = 744 divsteps */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &modinfo->modulus, -1) > 0); /* f > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &modinfo->modulus, 1) <= 0); /* f <= modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, len, &modinfo->modulus, -1) > 0); /* g > -modulus */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, len, &modinfo->modulus, 1) < 0); /* g < modulus */
|
|
#endif
|
|
}
|
|
|
|
/* At this point g is 0 and (if g was not originally 0) f must now equal +/- GCD of
|
|
* the initial f, g values i.e. +/- 1, and d now contains +/- the modular inverse. */
|
|
#ifdef VERIFY
|
|
/* g == 0 */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&g, len, &SECP256K1_SIGNED62_ONE, 0) == 0);
|
|
/* |f| == 1, or (x == 0 and d == 0 and |f|=modulus) */
|
|
VERIFY_CHECK(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &SECP256K1_SIGNED62_ONE, -1) == 0 ||
|
|
rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &SECP256K1_SIGNED62_ONE, 1) == 0 ||
|
|
(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(x, 5, &SECP256K1_SIGNED62_ONE, 0) == 0 &&
|
|
rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&d, 5, &SECP256K1_SIGNED62_ONE, 0) == 0 &&
|
|
(rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &modinfo->modulus, 1) == 0 ||
|
|
rustsecp256k1_v0_4_1_modinv64_mul_cmp_62(&f, len, &modinfo->modulus, -1) == 0)));
|
|
#endif
|
|
|
|
/* Optionally negate d, normalize to [0,modulus), and return it. */
|
|
rustsecp256k1_v0_4_1_modinv64_normalize_62(&d, f.v[len - 1], modinfo);
|
|
*x = d;
|
|
}
|
|
|
|
#endif /* SECP256K1_MODINV64_IMPL_H */
|