/* crypto/bn/bn_gf2m.c */ /* ==================================================================== * Copyright 2002 Sun Microsystems, Inc. ALL RIGHTS RESERVED. * * The Elliptic Curve Public-Key Crypto Library (ECC Code) included * herein is developed by SUN MICROSYSTEMS, INC., and is contributed * to the OpenSSL project. * * The ECC Code is licensed pursuant to the OpenSSL open source * license provided below. * * In addition, Sun covenants to all licensees who provide a reciprocal * covenant with respect to their own patents if any, not to sue under * current and future patent claims necessarily infringed by the making, * using, practicing, selling, offering for sale and/or otherwise * disposing of the ECC Code as delivered hereunder (or portions thereof), * provided that such covenant shall not apply: * 1) for code that a licensee deletes from the ECC Code; * 2) separates from the ECC Code; or * 3) for infringements caused by: * i) the modification of the ECC Code or * ii) the combination of the ECC Code with other software or * devices where such combination causes the infringement. * * The software is originally written by Sheueling Chang Shantz and * Douglas Stebila of Sun Microsystems Laboratories. * */ /* ==================================================================== * Copyright (c) 1998-2002 The OpenSSL Project. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * 3. All advertising materials mentioning features or use of this * software must display the following acknowledgment: * "This product includes software developed by the OpenSSL Project * for use in the OpenSSL Toolkit. (http://www.openssl.org/)" * * 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to * endorse or promote products derived from this software without * prior written permission. For written permission, please contact * openssl-core@openssl.org. * * 5. Products derived from this software may not be called "OpenSSL" * nor may "OpenSSL" appear in their names without prior written * permission of the OpenSSL Project. * * 6. Redistributions of any form whatsoever must retain the following * acknowledgment: * "This product includes software developed by the OpenSSL Project * for use in the OpenSSL Toolkit (http://www.openssl.org/)" * * THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ``AS IS'' AND ANY * EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE OpenSSL PROJECT OR * ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. * ==================================================================== * * This product includes cryptographic software written by Eric Young * (eay@cryptsoft.com). This product includes software written by Tim * Hudson (tjh@cryptsoft.com). * */ #include #include #include #include "cryptlib.h" #include "bn_lcl.h" /* Maximum number of iterations before BN_GF2m_mod_solve_quad_arr should fail. */ #define MAX_ITERATIONS 50 static const BN_ULONG SQR_tb[16] = { 0, 1, 4, 5, 16, 17, 20, 21, 64, 65, 68, 69, 80, 81, 84, 85 }; /* Platform-specific macros to accelerate squaring. */ #if defined(SIXTY_FOUR_BIT) || defined(SIXTY_FOUR_BIT_LONG) #define SQR1(w) \ SQR_tb[(w) >> 60 & 0xF] << 56 | SQR_tb[(w) >> 56 & 0xF] << 48 | \ SQR_tb[(w) >> 52 & 0xF] << 40 | SQR_tb[(w) >> 48 & 0xF] << 32 | \ SQR_tb[(w) >> 44 & 0xF] << 24 | SQR_tb[(w) >> 40 & 0xF] << 16 | \ SQR_tb[(w) >> 36 & 0xF] << 8 | SQR_tb[(w) >> 32 & 0xF] #define SQR0(w) \ SQR_tb[(w) >> 28 & 0xF] << 56 | SQR_tb[(w) >> 24 & 0xF] << 48 | \ SQR_tb[(w) >> 20 & 0xF] << 40 | SQR_tb[(w) >> 16 & 0xF] << 32 | \ SQR_tb[(w) >> 12 & 0xF] << 24 | SQR_tb[(w) >> 8 & 0xF] << 16 | \ SQR_tb[(w) >> 4 & 0xF] << 8 | SQR_tb[(w) & 0xF] #endif #ifdef THIRTY_TWO_BIT #define SQR1(w) \ SQR_tb[(w) >> 28 & 0xF] << 24 | SQR_tb[(w) >> 24 & 0xF] << 16 | \ SQR_tb[(w) >> 20 & 0xF] << 8 | SQR_tb[(w) >> 16 & 0xF] #define SQR0(w) \ SQR_tb[(w) >> 12 & 0xF] << 24 | SQR_tb[(w) >> 8 & 0xF] << 16 | \ SQR_tb[(w) >> 4 & 0xF] << 8 | SQR_tb[(w) & 0xF] #endif #ifdef SIXTEEN_BIT #define SQR1(w) \ SQR_tb[(w) >> 12 & 0xF] << 8 | SQR_tb[(w) >> 8 & 0xF] #define SQR0(w) \ SQR_tb[(w) >> 4 & 0xF] << 8 | SQR_tb[(w) & 0xF] #endif #ifdef EIGHT_BIT #define SQR1(w) \ SQR_tb[(w) >> 4 & 0xF] #define SQR0(w) \ SQR_tb[(w) & 15] #endif /* Product of two polynomials a, b each with degree < BN_BITS2 - 1, * result is a polynomial r with degree < 2 * BN_BITS - 1 * The caller MUST ensure that the variables have the right amount * of space allocated. */ #ifdef EIGHT_BIT static void bn_GF2m_mul_1x1(BN_ULONG *r1, BN_ULONG *r0, const BN_ULONG a, const BN_ULONG b) { register BN_ULONG h, l, s; BN_ULONG tab[4], top1b = a >> 7; register BN_ULONG a1, a2; a1 = a & (0x7F); a2 = a1 << 1; tab[0] = 0; tab[1] = a1; tab[2] = a2; tab[3] = a1^a2; s = tab[b & 0x3]; l = s; s = tab[b >> 2 & 0x3]; l ^= s << 2; h = s >> 6; s = tab[b >> 4 & 0x3]; l ^= s << 4; h ^= s >> 4; s = tab[b >> 6 ]; l ^= s << 6; h ^= s >> 2; /* compensate for the top bit of a */ if (top1b & 01) { l ^= b << 7; h ^= b >> 1; } *r1 = h; *r0 = l; } #endif #ifdef SIXTEEN_BIT static void bn_GF2m_mul_1x1(BN_ULONG *r1, BN_ULONG *r0, const BN_ULONG a, const BN_ULONG b) { register BN_ULONG h, l, s; BN_ULONG tab[4], top1b = a >> 15; register BN_ULONG a1, a2; a1 = a & (0x7FFF); a2 = a1 << 1; tab[0] = 0; tab[1] = a1; tab[2] = a2; tab[3] = a1^a2; s = tab[b & 0x3]; l = s; s = tab[b >> 2 & 0x3]; l ^= s << 2; h = s >> 14; s = tab[b >> 4 & 0x3]; l ^= s << 4; h ^= s >> 12; s = tab[b >> 6 & 0x3]; l ^= s << 6; h ^= s >> 10; s = tab[b >> 8 & 0x3]; l ^= s << 8; h ^= s >> 8; s = tab[b >>10 & 0x3]; l ^= s << 10; h ^= s >> 6; s = tab[b >>12 & 0x3]; l ^= s << 12; h ^= s >> 4; s = tab[b >>14 ]; l ^= s << 14; h ^= s >> 2; /* compensate for the top bit of a */ if (top1b & 01) { l ^= b << 15; h ^= b >> 1; } *r1 = h; *r0 = l; } #endif #ifdef THIRTY_TWO_BIT static void bn_GF2m_mul_1x1(BN_ULONG *r1, BN_ULONG *r0, const BN_ULONG a, const BN_ULONG b) { register BN_ULONG h, l, s; BN_ULONG tab[8], top2b = a >> 30; register BN_ULONG a1, a2, a4; a1 = a & (0x3FFFFFFF); a2 = a1 << 1; a4 = a2 << 1; tab[0] = 0; tab[1] = a1; tab[2] = a2; tab[3] = a1^a2; tab[4] = a4; tab[5] = a1^a4; tab[6] = a2^a4; tab[7] = a1^a2^a4; s = tab[b & 0x7]; l = s; s = tab[b >> 3 & 0x7]; l ^= s << 3; h = s >> 29; s = tab[b >> 6 & 0x7]; l ^= s << 6; h ^= s >> 26; s = tab[b >> 9 & 0x7]; l ^= s << 9; h ^= s >> 23; s = tab[b >> 12 & 0x7]; l ^= s << 12; h ^= s >> 20; s = tab[b >> 15 & 0x7]; l ^= s << 15; h ^= s >> 17; s = tab[b >> 18 & 0x7]; l ^= s << 18; h ^= s >> 14; s = tab[b >> 21 & 0x7]; l ^= s << 21; h ^= s >> 11; s = tab[b >> 24 & 0x7]; l ^= s << 24; h ^= s >> 8; s = tab[b >> 27 & 0x7]; l ^= s << 27; h ^= s >> 5; s = tab[b >> 30 ]; l ^= s << 30; h ^= s >> 2; /* compensate for the top two bits of a */ if (top2b & 01) { l ^= b << 30; h ^= b >> 2; } if (top2b & 02) { l ^= b << 31; h ^= b >> 1; } *r1 = h; *r0 = l; } #endif #if defined(SIXTY_FOUR_BIT) || defined(SIXTY_FOUR_BIT_LONG) static void bn_GF2m_mul_1x1(BN_ULONG *r1, BN_ULONG *r0, const BN_ULONG a, const BN_ULONG b) { register BN_ULONG h, l, s; BN_ULONG tab[16], top3b = a >> 61; register BN_ULONG a1, a2, a4, a8; a1 = a & (0x1FFFFFFFFFFFFFFF); a2 = a1 << 1; a4 = a2 << 1; a8 = a4 << 1; tab[ 0] = 0; tab[ 1] = a1; tab[ 2] = a2; tab[ 3] = a1^a2; tab[ 4] = a4; tab[ 5] = a1^a4; tab[ 6] = a2^a4; tab[ 7] = a1^a2^a4; tab[ 8] = a8; tab[ 9] = a1^a8; tab[10] = a2^a8; tab[11] = a1^a2^a8; tab[12] = a4^a8; tab[13] = a1^a4^a8; tab[14] = a2^a4^a8; tab[15] = a1^a2^a4^a8; s = tab[b & 0xF]; l = s; s = tab[b >> 4 & 0xF]; l ^= s << 4; h = s >> 60; s = tab[b >> 8 & 0xF]; l ^= s << 8; h ^= s >> 56; s = tab[b >> 12 & 0xF]; l ^= s << 12; h ^= s >> 52; s = tab[b >> 16 & 0xF]; l ^= s << 16; h ^= s >> 48; s = tab[b >> 20 & 0xF]; l ^= s << 20; h ^= s >> 44; s = tab[b >> 24 & 0xF]; l ^= s << 24; h ^= s >> 40; s = tab[b >> 28 & 0xF]; l ^= s << 28; h ^= s >> 36; s = tab[b >> 32 & 0xF]; l ^= s << 32; h ^= s >> 32; s = tab[b >> 36 & 0xF]; l ^= s << 36; h ^= s >> 28; s = tab[b >> 40 & 0xF]; l ^= s << 40; h ^= s >> 24; s = tab[b >> 44 & 0xF]; l ^= s << 44; h ^= s >> 20; s = tab[b >> 48 & 0xF]; l ^= s << 48; h ^= s >> 16; s = tab[b >> 52 & 0xF]; l ^= s << 52; h ^= s >> 12; s = tab[b >> 56 & 0xF]; l ^= s << 56; h ^= s >> 8; s = tab[b >> 60 ]; l ^= s << 60; h ^= s >> 4; /* compensate for the top three bits of a */ if (top3b & 01) { l ^= b << 61; h ^= b >> 3; } if (top3b & 02) { l ^= b << 62; h ^= b >> 2; } if (top3b & 04) { l ^= b << 63; h ^= b >> 1; } *r1 = h; *r0 = l; } #endif /* Product of two polynomials a, b each with degree < 2 * BN_BITS2 - 1, * result is a polynomial r with degree < 4 * BN_BITS2 - 1 * The caller MUST ensure that the variables have the right amount * of space allocated. */ static void bn_GF2m_mul_2x2(BN_ULONG *r, const BN_ULONG a1, const BN_ULONG a0, const BN_ULONG b1, const BN_ULONG b0) { BN_ULONG m1, m0; /* r[3] = h1, r[2] = h0; r[1] = l1; r[0] = l0 */ bn_GF2m_mul_1x1(r+3, r+2, a1, b1); bn_GF2m_mul_1x1(r+1, r, a0, b0); bn_GF2m_mul_1x1(&m1, &m0, a0 ^ a1, b0 ^ b1); /* Correction on m1 ^= l1 ^ h1; m0 ^= l0 ^ h0; */ r[2] ^= m1 ^ r[1] ^ r[3]; /* h0 ^= m1 ^ l1 ^ h1; */ r[1] = r[3] ^ r[2] ^ r[0] ^ m1 ^ m0; /* l1 ^= l0 ^ h0 ^ m0; */ } /* Add polynomials a and b and store result in r; r could be a or b, a and b * could be equal; r is the bitwise XOR of a and b. */ int BN_GF2m_add(BIGNUM *r, const BIGNUM *a, const BIGNUM *b) { int i; const BIGNUM *at, *bt; if (a->top < b->top) { at = b; bt = a; } else { at = a; bt = b; } bn_wexpand(r, at->top); for (i = 0; i < bt->top; i++) { r->d[i] = at->d[i] ^ bt->d[i]; } for (; i < at->top; i++) { r->d[i] = at->d[i]; } r->top = at->top; bn_fix_top(r); return 1; } /* Some functions allow for representation of the irreducible polynomials * as an int[], say p. The irreducible f(t) is then of the form: * t^p[0] + t^p[1] + ... + t^p[k] * where m = p[0] > p[1] > ... > p[k] = 0. */ /* Performs modular reduction of a and store result in r. r could be a. */ int BN_GF2m_mod_arr(BIGNUM *r, const BIGNUM *a, const unsigned int p[]) { int j, k; int n, dN, d0, d1; BN_ULONG zz, *z; /* Since the algorithm does reduction in place, if a == r, copy the * contents of a into r so we can do reduction in r. */ if ((a != NULL) && (a->d != r->d)) { if (!bn_wexpand(r, a->top)) return 0; for (j = 0; j < a->top; j++) { r->d[j] = a->d[j]; } r->top = a->top; } z = r->d; /* start reduction */ dN = p[0] / BN_BITS2; for (j = r->top - 1; j > dN;) { zz = z[j]; if (z[j] == 0) { j--; continue; } z[j] = 0; for (k = 1; p[k] > 0; k++) { /* reducing component t^p[k] */ n = p[0] - p[k]; d0 = n % BN_BITS2; d1 = BN_BITS2 - d0; n /= BN_BITS2; z[j-n] ^= (zz>>d0); if (d0) z[j-n-1] ^= (zz<> d0); if (d0) z[j-n-1] ^= (zz << d1); } /* final round of reduction */ while (j == dN) { d0 = p[0] % BN_BITS2; zz = z[dN] >> d0; if (zz == 0) break; d1 = BN_BITS2 - d0; if (d0) z[dN] = (z[dN] << d1) >> d1; /* clear up the top d1 bits */ z[0] ^= zz; /* reduction t^0 component */ for (k = 1; p[k] > 0; k++) { /* reducing component t^p[k]*/ n = p[k] / BN_BITS2; d0 = p[k] % BN_BITS2; d1 = BN_BITS2 - d0; z[n] ^= (zz << d0); if (d0) z[n+1] ^= (zz >> d1); } } bn_fix_top(r); return 1; } /* Performs modular reduction of a by p and store result in r. r could be a. * * This function calls down to the BN_GF2m_mod_arr implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_arr function. */ int BN_GF2m_mod(BIGNUM *r, const BIGNUM *a, const BIGNUM *p) { const int max = BN_num_bits(p); unsigned int *arr=NULL, ret = 0; if ((arr = (unsigned int *)OPENSSL_malloc(sizeof(unsigned int) * max)) == NULL) goto err; if (BN_GF2m_poly2arr(p, arr, max) > max) { BNerr(BN_F_BN_GF2M_MOD,BN_R_INVALID_LENGTH); goto err; } ret = BN_GF2m_mod_arr(r, a, arr); err: if (arr) OPENSSL_free(arr); return ret; } /* Compute the product of two polynomials a and b, reduce modulo p, and store * the result in r. r could be a or b; a could be b. */ int BN_GF2m_mod_mul_arr(BIGNUM *r, const BIGNUM *a, const BIGNUM *b, const unsigned int p[], BN_CTX *ctx) { int zlen, i, j, k, ret = 0; BIGNUM *s; BN_ULONG x1, x0, y1, y0, zz[4]; if (a == b) { return BN_GF2m_mod_sqr_arr(r, a, p, ctx); } BN_CTX_start(ctx); if ((s = BN_CTX_get(ctx)) == NULL) goto err; zlen = a->top + b->top; if (!bn_wexpand(s, zlen)) goto err; s->top = zlen; for (i = 0; i < zlen; i++) s->d[i] = 0; for (j = 0; j < b->top; j += 2) { y0 = b->d[j]; y1 = ((j+1) == b->top) ? 0 : b->d[j+1]; for (i = 0; i < a->top; i += 2) { x0 = a->d[i]; x1 = ((i+1) == a->top) ? 0 : a->d[i+1]; bn_GF2m_mul_2x2(zz, x1, x0, y1, y0); for (k = 0; k < 4; k++) s->d[i+j+k] ^= zz[k]; } } bn_fix_top(s); BN_GF2m_mod_arr(r, s, p); ret = 1; err: BN_CTX_end(ctx); return ret; } /* Compute the product of two polynomials a and b, reduce modulo p, and store * the result in r. r could be a or b; a could equal b. * * This function calls down to the BN_GF2m_mod_mul_arr implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_mul_arr function. */ int BN_GF2m_mod_mul(BIGNUM *r, const BIGNUM *a, const BIGNUM *b, const BIGNUM *p, BN_CTX *ctx) { const int max = BN_num_bits(p); unsigned int *arr=NULL, ret = 0; if ((arr = (unsigned int *)OPENSSL_malloc(sizeof(unsigned int) * max)) == NULL) goto err; if (BN_GF2m_poly2arr(p, arr, max) > max) { BNerr(BN_F_BN_GF2M_MOD_MUL,BN_R_INVALID_LENGTH); goto err; } ret = BN_GF2m_mod_mul_arr(r, a, b, arr, ctx); err: if (arr) OPENSSL_free(arr); return ret; } /* Square a, reduce the result mod p, and store it in a. r could be a. */ int BN_GF2m_mod_sqr_arr(BIGNUM *r, const BIGNUM *a, const unsigned int p[], BN_CTX *ctx) { int i, ret = 0; BIGNUM *s; BN_CTX_start(ctx); if ((s = BN_CTX_get(ctx)) == NULL) return 0; if (!bn_wexpand(s, 2 * a->top)) goto err; for (i = a->top - 1; i >= 0; i--) { s->d[2*i+1] = SQR1(a->d[i]); s->d[2*i ] = SQR0(a->d[i]); } s->top = 2 * a->top; bn_fix_top(s); if (!BN_GF2m_mod_arr(r, s, p)) goto err; ret = 1; err: BN_CTX_end(ctx); return ret; } /* Square a, reduce the result mod p, and store it in a. r could be a. * * This function calls down to the BN_GF2m_mod_sqr_arr implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_sqr_arr function. */ int BN_GF2m_mod_sqr(BIGNUM *r, const BIGNUM *a, const BIGNUM *p, BN_CTX *ctx) { const int max = BN_num_bits(p); unsigned int *arr=NULL, ret = 0; if ((arr = (unsigned int *)OPENSSL_malloc(sizeof(unsigned int) * max)) == NULL) goto err; if (BN_GF2m_poly2arr(p, arr, max) > max) { BNerr(BN_F_BN_GF2M_MOD_SQR,BN_R_INVALID_LENGTH); goto err; } ret = BN_GF2m_mod_sqr_arr(r, a, arr, ctx); err: if (arr) OPENSSL_free(arr); return ret; } /* Invert a, reduce modulo p, and store the result in r. r could be a. * Uses Modified Almost Inverse Algorithm (Algorithm 10) from * Hankerson, D., Hernandez, J.L., and Menezes, A. "Software Implementation * of Elliptic Curve Cryptography Over Binary Fields". */ int BN_GF2m_mod_inv(BIGNUM *r, const BIGNUM *a, const BIGNUM *p, BN_CTX *ctx) { BIGNUM *b, *c, *u, *v, *tmp; int ret = 0; BN_CTX_start(ctx); b = BN_CTX_get(ctx); c = BN_CTX_get(ctx); u = BN_CTX_get(ctx); v = BN_CTX_get(ctx); if (v == NULL) goto err; if (!BN_one(b)) goto err; if (!BN_zero(c)) goto err; if (!BN_GF2m_mod(u, a, p)) goto err; if (!BN_copy(v, p)) goto err; u->neg = 0; /* Need to set u->neg = 0 because BN_is_one(u) checks * the neg flag of the bignum. */ if (BN_is_zero(u)) goto err; while (1) { while (!BN_is_odd(u)) { if (!BN_rshift1(u, u)) goto err; if (BN_is_odd(b)) { if (!BN_GF2m_add(b, b, p)) goto err; } if (!BN_rshift1(b, b)) goto err; } if (BN_is_one(u)) break; if (BN_num_bits(u) < BN_num_bits(v)) { tmp = u; u = v; v = tmp; tmp = b; b = c; c = tmp; } if (!BN_GF2m_add(u, u, v)) goto err; if (!BN_GF2m_add(b, b, c)) goto err; } if (!BN_copy(r, b)) goto err; ret = 1; err: BN_CTX_end(ctx); return ret; } /* Invert xx, reduce modulo p, and store the result in r. r could be xx. * * This function calls down to the BN_GF2m_mod_inv implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_inv function. */ int BN_GF2m_mod_inv_arr(BIGNUM *r, const BIGNUM *xx, const unsigned int p[], BN_CTX *ctx) { BIGNUM *field; int ret = 0; BN_CTX_start(ctx); if ((field = BN_CTX_get(ctx)) == NULL) goto err; if (!BN_GF2m_arr2poly(p, field)) goto err; ret = BN_GF2m_mod_inv(r, xx, field, ctx); err: BN_CTX_end(ctx); return ret; } #ifndef OPENSSL_SUN_GF2M_DIV /* Divide y by x, reduce modulo p, and store the result in r. r could be x * or y, x could equal y. */ int BN_GF2m_mod_div(BIGNUM *r, const BIGNUM *y, const BIGNUM *x, const BIGNUM *p, BN_CTX *ctx) { BIGNUM *xinv = NULL; int ret = 0; BN_CTX_start(ctx); xinv = BN_CTX_get(ctx); if (xinv == NULL) goto err; if (!BN_GF2m_mod_inv(xinv, x, p, ctx)) goto err; if (!BN_GF2m_mod_mul(r, y, xinv, p, ctx)) goto err; ret = 1; err: BN_CTX_end(ctx); return ret; } #else /* Divide y by x, reduce modulo p, and store the result in r. r could be x * or y, x could equal y. * Uses algorithm Modular_Division_GF(2^m) from * Chang-Shantz, S. "From Euclid's GCD to Montgomery Multiplication to * the Great Divide". */ int BN_GF2m_mod_div(BIGNUM *r, const BIGNUM *y, const BIGNUM *x, const BIGNUM *p, BN_CTX *ctx) { BIGNUM *a, *b, *u, *v; int ret = 0; BN_CTX_start(ctx); a = BN_CTX_get(ctx); b = BN_CTX_get(ctx); u = BN_CTX_get(ctx); v = BN_CTX_get(ctx); if (v == NULL) goto err; /* reduce x and y mod p */ if (!BN_GF2m_mod(u, y, p)) goto err; if (!BN_GF2m_mod(a, x, p)) goto err; if (!BN_copy(b, p)) goto err; if (!BN_zero(v)) goto err; a->neg = 0; /* Need to set a->neg = 0 because BN_is_one(a) checks * the neg flag of the bignum. */ while (!BN_is_odd(a)) { if (!BN_rshift1(a, a)) goto err; if (BN_is_odd(u)) if (!BN_GF2m_add(u, u, p)) goto err; if (!BN_rshift1(u, u)) goto err; } do { if (BN_GF2m_cmp(b, a) > 0) { if (!BN_GF2m_add(b, b, a)) goto err; if (!BN_GF2m_add(v, v, u)) goto err; do { if (!BN_rshift1(b, b)) goto err; if (BN_is_odd(v)) if (!BN_GF2m_add(v, v, p)) goto err; if (!BN_rshift1(v, v)) goto err; } while (!BN_is_odd(b)); } else if (BN_is_one(a)) break; else { if (!BN_GF2m_add(a, a, b)) goto err; if (!BN_GF2m_add(u, u, v)) goto err; do { if (!BN_rshift1(a, a)) goto err; if (BN_is_odd(u)) if (!BN_GF2m_add(u, u, p)) goto err; if (!BN_rshift1(u, u)) goto err; } while (!BN_is_odd(a)); } } while (1); if (!BN_copy(r, u)) goto err; ret = 1; err: BN_CTX_end(ctx); return ret; } #endif /* Divide yy by xx, reduce modulo p, and store the result in r. r could be xx * or yy, xx could equal yy. * * This function calls down to the BN_GF2m_mod_div implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_div function. */ int BN_GF2m_mod_div_arr(BIGNUM *r, const BIGNUM *yy, const BIGNUM *xx, const unsigned int p[], BN_CTX *ctx) { BIGNUM *field; int ret = 0; BN_CTX_start(ctx); if ((field = BN_CTX_get(ctx)) == NULL) goto err; if (!BN_GF2m_arr2poly(p, field)) goto err; ret = BN_GF2m_mod_div(r, yy, xx, field, ctx); err: BN_CTX_end(ctx); return ret; } /* Compute the bth power of a, reduce modulo p, and store * the result in r. r could be a. * Uses simple square-and-multiply algorithm A.5.1 from IEEE P1363. */ int BN_GF2m_mod_exp_arr(BIGNUM *r, const BIGNUM *a, const BIGNUM *b, const unsigned int p[], BN_CTX *ctx) { int ret = 0, i, n; BIGNUM *u; if (BN_is_zero(b)) { return(BN_one(r)); } BN_CTX_start(ctx); if ((u = BN_CTX_get(ctx)) == NULL) goto err; if (!BN_GF2m_mod_arr(u, a, p)) goto err; n = BN_num_bits(b) - 1; for (i = n - 1; i >= 0; i--) { if (!BN_GF2m_mod_sqr_arr(u, u, p, ctx)) goto err; if (BN_is_bit_set(b, i)) { if (!BN_GF2m_mod_mul_arr(u, u, a, p, ctx)) goto err; } } if (!BN_copy(r, u)) goto err; ret = 1; err: BN_CTX_end(ctx); return ret; } /* Compute the bth power of a, reduce modulo p, and store * the result in r. r could be a. * * This function calls down to the BN_GF2m_mod_exp_arr implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_exp_arr function. */ int BN_GF2m_mod_exp(BIGNUM *r, const BIGNUM *a, const BIGNUM *b, const BIGNUM *p, BN_CTX *ctx) { const int max = BN_num_bits(p); unsigned int *arr=NULL, ret = 0; if ((arr = (unsigned int *)OPENSSL_malloc(sizeof(unsigned int) * max)) == NULL) goto err; if (BN_GF2m_poly2arr(p, arr, max) > max) { BNerr(BN_F_BN_GF2M_MOD_EXP,BN_R_INVALID_LENGTH); goto err; } ret = BN_GF2m_mod_exp_arr(r, a, b, arr, ctx); err: if (arr) OPENSSL_free(arr); return ret; } /* Compute the square root of a, reduce modulo p, and store * the result in r. r could be a. * Uses exponentiation as in algorithm A.4.1 from IEEE P1363. */ int BN_GF2m_mod_sqrt_arr(BIGNUM *r, const BIGNUM *a, const unsigned int p[], BN_CTX *ctx) { int ret = 0; BIGNUM *u; BN_CTX_start(ctx); if ((u = BN_CTX_get(ctx)) == NULL) goto err; if (!BN_zero(u)) goto err; if (!BN_set_bit(u, p[0] - 1)) goto err; ret = BN_GF2m_mod_exp_arr(r, a, u, p, ctx); err: BN_CTX_end(ctx); return ret; } /* Compute the square root of a, reduce modulo p, and store * the result in r. r could be a. * * This function calls down to the BN_GF2m_mod_sqrt_arr implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_sqrt_arr function. */ int BN_GF2m_mod_sqrt(BIGNUM *r, const BIGNUM *a, const BIGNUM *p, BN_CTX *ctx) { const int max = BN_num_bits(p); unsigned int *arr=NULL, ret = 0; if ((arr = (unsigned int *)OPENSSL_malloc(sizeof(unsigned int) * max)) == NULL) goto err; if (BN_GF2m_poly2arr(p, arr, max) > max) { BNerr(BN_F_BN_GF2M_MOD_EXP,BN_R_INVALID_LENGTH); goto err; } ret = BN_GF2m_mod_sqrt_arr(r, a, arr, ctx); err: if (arr) OPENSSL_free(arr); return ret; } /* Find r such that r^2 + r = a mod p. r could be a. If no r exists returns 0. * Uses algorithms A.4.7 and A.4.6 from IEEE P1363. */ int BN_GF2m_mod_solve_quad_arr(BIGNUM *r, const BIGNUM *a_, const unsigned int p[], BN_CTX *ctx) { int ret = 0, i, count = 0; BIGNUM *a, *z, *rho, *w, *w2, *tmp; BN_CTX_start(ctx); a = BN_CTX_get(ctx); z = BN_CTX_get(ctx); w = BN_CTX_get(ctx); if (w == NULL) goto err; if (!BN_GF2m_mod_arr(a, a_, p)) goto err; if (BN_is_zero(a)) { ret = BN_zero(r); goto err; } if (p[0] & 0x1) /* m is odd */ { /* compute half-trace of a */ if (!BN_copy(z, a)) goto err; for (i = 1; i <= (p[0] - 1) / 2; i++) { if (!BN_GF2m_mod_sqr_arr(z, z, p, ctx)) goto err; if (!BN_GF2m_mod_sqr_arr(z, z, p, ctx)) goto err; if (!BN_GF2m_add(z, z, a)) goto err; } } else /* m is even */ { rho = BN_CTX_get(ctx); w2 = BN_CTX_get(ctx); tmp = BN_CTX_get(ctx); if (tmp == NULL) goto err; do { if (!BN_rand(rho, p[0], 0, 0)) goto err; if (!BN_GF2m_mod_arr(rho, rho, p)) goto err; if (!BN_zero(z)) goto err; if (!BN_copy(w, rho)) goto err; for (i = 1; i <= p[0] - 1; i++) { if (!BN_GF2m_mod_sqr_arr(z, z, p, ctx)) goto err; if (!BN_GF2m_mod_sqr_arr(w2, w, p, ctx)) goto err; if (!BN_GF2m_mod_mul_arr(tmp, w2, a, p, ctx)) goto err; if (!BN_GF2m_add(z, z, tmp)) goto err; if (!BN_GF2m_add(w, w2, rho)) goto err; } count++; } while (BN_is_zero(w) && (count < MAX_ITERATIONS)); if (BN_is_zero(w)) { BNerr(BN_F_BN_GF2M_MOD_SOLVE_QUAD_ARR,BN_R_TOO_MANY_ITERATIONS); goto err; } } if (!BN_GF2m_mod_sqr_arr(w, z, p, ctx)) goto err; if (!BN_GF2m_add(w, z, w)) goto err; if (BN_GF2m_cmp(w, a)) goto err; if (!BN_copy(r, z)) goto err; ret = 1; err: BN_CTX_end(ctx); return ret; } /* Find r such that r^2 + r = a mod p. r could be a. If no r exists returns 0. * * This function calls down to the BN_GF2m_mod_solve_quad_arr implementation; this wrapper * function is only provided for convenience; for best performance, use the * BN_GF2m_mod_solve_quad_arr function. */ int BN_GF2m_mod_solve_quad(BIGNUM *r, const BIGNUM *a, const BIGNUM *p, BN_CTX *ctx) { const int max = BN_num_bits(p); unsigned int *arr=NULL, ret = 0; if ((arr = (unsigned int *)OPENSSL_malloc(sizeof(unsigned int) * max)) == NULL) goto err; if (BN_GF2m_poly2arr(p, arr, max) > max) { BNerr(BN_F_BN_GF2M_MOD_SOLVE_QUAD,BN_R_INVALID_LENGTH); goto err; } ret = BN_GF2m_mod_solve_quad_arr(r, a, arr, ctx); err: if (arr) OPENSSL_free(arr); return ret; } /* Convert the bit-string representation of a polynomial a into an array * of integers corresponding to the bits with non-zero coefficient. * Up to max elements of the array will be filled. Return value is total * number of coefficients that would be extracted if array was large enough. */ int BN_GF2m_poly2arr(const BIGNUM *a, unsigned int p[], int max) { int i, j, k; BN_ULONG mask; for (k = 0; k < max; k++) p[k] = 0; k = 0; for (i = a->top - 1; i >= 0; i--) { mask = BN_TBIT; for (j = BN_BITS2 - 1; j >= 0; j--) { if (a->d[i] & mask) { if (k < max) p[k] = BN_BITS2 * i + j; k++; } mask >>= 1; } } return k; } /* Convert the coefficient array representation of a polynomial to a * bit-string. The array must be terminated by 0. */ int BN_GF2m_arr2poly(const unsigned int p[], BIGNUM *a) { int i; BN_zero(a); for (i = 0; p[i] > 0; i++) { BN_set_bit(a, p[i]); } BN_set_bit(a, 0); return 1; }