pjs/security/nss/lib/freebl/ecl/ecp_384.c

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2008-06-06 16:40:11 +04:00
/*
* ***** BEGIN LICENSE BLOCK *****
* Version: MPL 1.1/GPL 2.0/LGPL 2.1
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
* http://www.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is the elliptic curve math library for prime field curves.
*
* The Initial Developer of the Original Code is
* Sun Microsystems, Inc.
* Portions created by the Initial Developer are Copyright (C) 2003
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
* Douglas Stebila <douglas@stebila.ca>
*
* Alternatively, the contents of this file may be used under the terms of
* either the GNU General Public License Version 2 or later (the "GPL"), or
* the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
* in which case the provisions of the GPL or the LGPL are applicable instead
* of those above. If you wish to allow use of your version of this file only
* under the terms of either the GPL or the LGPL, and not to allow others to
* use your version of this file under the terms of the MPL, indicate your
* decision by deleting the provisions above and replace them with the notice
* and other provisions required by the GPL or the LGPL. If you do not delete
* the provisions above, a recipient may use your version of this file under
* the terms of any one of the MPL, the GPL or the LGPL.
*
* ***** END LICENSE BLOCK ***** */
#include "ecp.h"
#include "mpi.h"
#include "mplogic.h"
#include "mpi-priv.h"
#include <stdlib.h>
/* Fast modular reduction for p384 = 2^384 - 2^128 - 2^96 + 2^32 - 1. a can be r.
* Uses algorithm 2.30 from Hankerson, Menezes, Vanstone. Guide to
* Elliptic Curve Cryptography. */
mp_err
ec_GFp_nistp384_mod(const mp_int *a, mp_int *r, const GFMethod *meth)
{
mp_err res = MP_OKAY;
int a_bits = mpl_significant_bits(a);
int i;
/* m1, m2 are statically-allocated mp_int of exactly the size we need */
mp_int m[10];
#ifdef ECL_THIRTY_TWO_BIT
mp_digit s[10][12];
for (i = 0; i < 10; i++) {
MP_SIGN(&m[i]) = MP_ZPOS;
MP_ALLOC(&m[i]) = 12;
MP_USED(&m[i]) = 12;
MP_DIGITS(&m[i]) = s[i];
}
#else
mp_digit s[10][6];
for (i = 0; i < 10; i++) {
MP_SIGN(&m[i]) = MP_ZPOS;
MP_ALLOC(&m[i]) = 6;
MP_USED(&m[i]) = 6;
MP_DIGITS(&m[i]) = s[i];
}
#endif
#ifdef ECL_THIRTY_TWO_BIT
/* for polynomials larger than twice the field size or polynomials
* not using all words, use regular reduction */
if ((a_bits > 768) || (a_bits <= 736)) {
MP_CHECKOK(mp_mod(a, &meth->irr, r));
} else {
for (i = 0; i < 12; i++) {
s[0][i] = MP_DIGIT(a, i);
}
s[1][0] = 0;
s[1][1] = 0;
s[1][2] = 0;
s[1][3] = 0;
s[1][4] = MP_DIGIT(a, 21);
s[1][5] = MP_DIGIT(a, 22);
s[1][6] = MP_DIGIT(a, 23);
s[1][7] = 0;
s[1][8] = 0;
s[1][9] = 0;
s[1][10] = 0;
s[1][11] = 0;
for (i = 0; i < 12; i++) {
s[2][i] = MP_DIGIT(a, i+12);
}
s[3][0] = MP_DIGIT(a, 21);
s[3][1] = MP_DIGIT(a, 22);
s[3][2] = MP_DIGIT(a, 23);
for (i = 3; i < 12; i++) {
s[3][i] = MP_DIGIT(a, i+9);
}
s[4][0] = 0;
s[4][1] = MP_DIGIT(a, 23);
s[4][2] = 0;
s[4][3] = MP_DIGIT(a, 20);
for (i = 4; i < 12; i++) {
s[4][i] = MP_DIGIT(a, i+8);
}
s[5][0] = 0;
s[5][1] = 0;
s[5][2] = 0;
s[5][3] = 0;
s[5][4] = MP_DIGIT(a, 20);
s[5][5] = MP_DIGIT(a, 21);
s[5][6] = MP_DIGIT(a, 22);
s[5][7] = MP_DIGIT(a, 23);
s[5][8] = 0;
s[5][9] = 0;
s[5][10] = 0;
s[5][11] = 0;
s[6][0] = MP_DIGIT(a, 20);
s[6][1] = 0;
s[6][2] = 0;
s[6][3] = MP_DIGIT(a, 21);
s[6][4] = MP_DIGIT(a, 22);
s[6][5] = MP_DIGIT(a, 23);
s[6][6] = 0;
s[6][7] = 0;
s[6][8] = 0;
s[6][9] = 0;
s[6][10] = 0;
s[6][11] = 0;
s[7][0] = MP_DIGIT(a, 23);
for (i = 1; i < 12; i++) {
s[7][i] = MP_DIGIT(a, i+11);
}
s[8][0] = 0;
s[8][1] = MP_DIGIT(a, 20);
s[8][2] = MP_DIGIT(a, 21);
s[8][3] = MP_DIGIT(a, 22);
s[8][4] = MP_DIGIT(a, 23);
s[8][5] = 0;
s[8][6] = 0;
s[8][7] = 0;
s[8][8] = 0;
s[8][9] = 0;
s[8][10] = 0;
s[8][11] = 0;
s[9][0] = 0;
s[9][1] = 0;
s[9][2] = 0;
s[9][3] = MP_DIGIT(a, 23);
s[9][4] = MP_DIGIT(a, 23);
s[9][5] = 0;
s[9][6] = 0;
s[9][7] = 0;
s[9][8] = 0;
s[9][9] = 0;
s[9][10] = 0;
s[9][11] = 0;
MP_CHECKOK(mp_add(&m[0], &m[1], r));
MP_CHECKOK(mp_add(r, &m[1], r));
MP_CHECKOK(mp_add(r, &m[2], r));
MP_CHECKOK(mp_add(r, &m[3], r));
MP_CHECKOK(mp_add(r, &m[4], r));
MP_CHECKOK(mp_add(r, &m[5], r));
MP_CHECKOK(mp_add(r, &m[6], r));
MP_CHECKOK(mp_sub(r, &m[7], r));
MP_CHECKOK(mp_sub(r, &m[8], r));
MP_CHECKOK(mp_submod(r, &m[9], &meth->irr, r));
s_mp_clamp(r);
}
#else
/* for polynomials larger than twice the field size or polynomials
* not using all words, use regular reduction */
if ((a_bits > 768) || (a_bits <= 736)) {
MP_CHECKOK(mp_mod(a, &meth->irr, r));
} else {
for (i = 0; i < 6; i++) {
s[0][i] = MP_DIGIT(a, i);
}
s[1][0] = 0;
s[1][1] = 0;
s[1][2] = (MP_DIGIT(a, 10) >> 32) | (MP_DIGIT(a, 11) << 32);
s[1][3] = MP_DIGIT(a, 11) >> 32;
s[1][4] = 0;
s[1][5] = 0;
for (i = 0; i < 6; i++) {
s[2][i] = MP_DIGIT(a, i+6);
}
s[3][0] = (MP_DIGIT(a, 10) >> 32) | (MP_DIGIT(a, 11) << 32);
s[3][1] = (MP_DIGIT(a, 11) >> 32) | (MP_DIGIT(a, 6) << 32);
for (i = 2; i < 6; i++) {
s[3][i] = (MP_DIGIT(a, i+4) >> 32) | (MP_DIGIT(a, i+5) << 32);
}
s[4][0] = (MP_DIGIT(a, 11) >> 32) << 32;
s[4][1] = MP_DIGIT(a, 10) << 32;
for (i = 2; i < 6; i++) {
s[4][i] = MP_DIGIT(a, i+4);
}
s[5][0] = 0;
s[5][1] = 0;
s[5][2] = MP_DIGIT(a, 10);
s[5][3] = MP_DIGIT(a, 11);
s[5][4] = 0;
s[5][5] = 0;
s[6][0] = (MP_DIGIT(a, 10) << 32) >> 32;
s[6][1] = (MP_DIGIT(a, 10) >> 32) << 32;
s[6][2] = MP_DIGIT(a, 11);
s[6][3] = 0;
s[6][4] = 0;
s[6][5] = 0;
s[7][0] = (MP_DIGIT(a, 11) >> 32) | (MP_DIGIT(a, 6) << 32);
for (i = 1; i < 6; i++) {
s[7][i] = (MP_DIGIT(a, i+5) >> 32) | (MP_DIGIT(a, i+6) << 32);
}
s[8][0] = MP_DIGIT(a, 10) << 32;
s[8][1] = (MP_DIGIT(a, 10) >> 32) | (MP_DIGIT(a, 11) << 32);
s[8][2] = MP_DIGIT(a, 11) >> 32;
s[8][3] = 0;
s[8][4] = 0;
s[8][5] = 0;
s[9][0] = 0;
s[9][1] = (MP_DIGIT(a, 11) >> 32) << 32;
s[9][2] = MP_DIGIT(a, 11) >> 32;
s[9][3] = 0;
s[9][4] = 0;
s[9][5] = 0;
MP_CHECKOK(mp_add(&m[0], &m[1], r));
MP_CHECKOK(mp_add(r, &m[1], r));
MP_CHECKOK(mp_add(r, &m[2], r));
MP_CHECKOK(mp_add(r, &m[3], r));
MP_CHECKOK(mp_add(r, &m[4], r));
MP_CHECKOK(mp_add(r, &m[5], r));
MP_CHECKOK(mp_add(r, &m[6], r));
MP_CHECKOK(mp_sub(r, &m[7], r));
MP_CHECKOK(mp_sub(r, &m[8], r));
MP_CHECKOK(mp_submod(r, &m[9], &meth->irr, r));
s_mp_clamp(r);
}
#endif
CLEANUP:
return res;
}
/* Compute the square of polynomial a, reduce modulo p384. Store the
* result in r. r could be a. Uses optimized modular reduction for p384.
*/
mp_err
ec_GFp_nistp384_sqr(const mp_int *a, mp_int *r, const GFMethod *meth)
{
mp_err res = MP_OKAY;
MP_CHECKOK(mp_sqr(a, r));
MP_CHECKOK(ec_GFp_nistp384_mod(r, r, meth));
CLEANUP:
return res;
}
/* Compute the product of two polynomials a and b, reduce modulo p384.
* Store the result in r. r could be a or b; a could be b. Uses
* optimized modular reduction for p384. */
mp_err
ec_GFp_nistp384_mul(const mp_int *a, const mp_int *b, mp_int *r,
const GFMethod *meth)
{
mp_err res = MP_OKAY;
MP_CHECKOK(mp_mul(a, b, r));
MP_CHECKOK(ec_GFp_nistp384_mod(r, r, meth));
CLEANUP:
return res;
}
/* Wire in fast field arithmetic and precomputation of base point for
* named curves. */
mp_err
ec_group_set_gfp384(ECGroup *group, ECCurveName name)
{
if (name == ECCurve_NIST_P384) {
group->meth->field_mod = &ec_GFp_nistp384_mod;
group->meth->field_mul = &ec_GFp_nistp384_mul;
group->meth->field_sqr = &ec_GFp_nistp384_sqr;
}
return MP_OKAY;
}