RetroZilla/security/nss/lib/freebl/ecl/ecp_fp160.c

/* 
 * ***** 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 using floating point operations.
 *
 * 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):
 *   Stephen Fung <fungstep@hotmail.com>, Sun Microsystems Laboratories
 *
 * 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_fp.h"
#include <stdlib.h>

#define ECFP_BSIZE 160
#define ECFP_NUMDOUBLES 7

#include "ecp_fpinc.c"

/* Performs a single step of reduction, just on the uppermost float
 * (assumes already tidied), and then retidies. Note, this does not
 * guarantee that the result will be less than p, but truncates the number 
 * of bits. */
void
ecfp160_singleReduce(double *d, const EC_group_fp * group)
{
	double q;

	ECFP_ASSERT(group->doubleBitSize == 24);
	ECFP_ASSERT(group->primeBitSize == 160);
	ECFP_ASSERT(ECFP_NUMDOUBLES == 7);

	q = d[ECFP_NUMDOUBLES - 1] - ecfp_beta_160;
	q += group->bitSize_alpha;
	q -= group->bitSize_alpha;

	d[ECFP_NUMDOUBLES - 1] -= q;
	d[0] += q * ecfp_twom160;
	d[1] += q * ecfp_twom129;
	ecfp_positiveTidy(d, group);

	/* Assertions for the highest order term */
	ECFP_ASSERT(d[ECFP_NUMDOUBLES - 1] / ecfp_exp[ECFP_NUMDOUBLES - 1] ==
				(unsigned long long) (d[ECFP_NUMDOUBLES - 1] /
									  ecfp_exp[ECFP_NUMDOUBLES - 1]));
	ECFP_ASSERT(d[ECFP_NUMDOUBLES - 1] >= 0);
}

/* Performs imperfect reduction.  This might leave some negative terms,
 * and one more reduction might be required for the result to be between 0 
 * and p-1. x should not already be reduced, i.e. should have
 * 2*ECFP_NUMDOUBLES significant terms. x and r can be the same, but then
 * the upper parts of r are not zeroed */
void
ecfp160_reduce(double *r, double *x, const EC_group_fp * group)
{

	double x7, x8, q;

	ECFP_ASSERT(group->doubleBitSize == 24);
	ECFP_ASSERT(group->primeBitSize == 160);
	ECFP_ASSERT(ECFP_NUMDOUBLES == 7);

	/* Tidy just the upper bits, the lower bits can wait. */
	ecfp_tidyUpper(x, group);

	/* Assume that this is already tidied so that we have enough extra
	 * bits */
	x7 = x[7] + x[13] * ecfp_twom129;	/* adds bits 15-39 */

	/* Tidy x7, or we won't have enough bits later to add it in */
	q = x7 + group->alpha[8];
	q -= group->alpha[8];
	x7 -= q;					/* holds bits 0-24 */
	x8 = x[8] + q;				/* holds bits 0-25 */

	r[6] = x[6] + x[13] * ecfp_twom160 + x[12] * ecfp_twom129;	/* adds
																 * bits
																 * 8-39 */
	r[5] = x[5] + x[12] * ecfp_twom160 + x[11] * ecfp_twom129;
	r[4] = x[4] + x[11] * ecfp_twom160 + x[10] * ecfp_twom129;
	r[3] = x[3] + x[10] * ecfp_twom160 + x[9] * ecfp_twom129;
	r[2] = x[2] + x[9] * ecfp_twom160 + x8 * ecfp_twom129;	/* adds bits
															 * 8-40 */
	r[1] = x[1] + x8 * ecfp_twom160 + x7 * ecfp_twom129;	/* adds bits
															 * 8-39 */
	r[0] = x[0] + x7 * ecfp_twom160;

	/* Tidy up just r[ECFP_NUMDOUBLES-2] so that the number of reductions
	 * is accurate plus or minus one.  (Rather than tidy all to make it
	 * totally accurate, which is more costly.) */
	q = r[ECFP_NUMDOUBLES - 2] + group->alpha[ECFP_NUMDOUBLES - 1];
	q -= group->alpha[ECFP_NUMDOUBLES - 1];
	r[ECFP_NUMDOUBLES - 2] -= q;
	r[ECFP_NUMDOUBLES - 1] += q;

	/* Tidy up the excess bits on r[ECFP_NUMDOUBLES-1] using reduction */
	/* Use ecfp_beta so we get a positive result */
	q = r[ECFP_NUMDOUBLES - 1] - ecfp_beta_160;
	q += group->bitSize_alpha;
	q -= group->bitSize_alpha;

	r[ECFP_NUMDOUBLES - 1] -= q;
	r[0] += q * ecfp_twom160;
	r[1] += q * ecfp_twom129;

	/* Tidy the result */
	ecfp_tidyShort(r, group);
}

/* Sets group to use optimized calculations in this file */
mp_err
ec_group_set_secp160r1_fp(ECGroup *group)
{

	EC_group_fp *fpg = NULL;

	/* Allocate memory for floating point group data */
	fpg = (EC_group_fp *) malloc(sizeof(EC_group_fp));
	if (fpg == NULL) {
		return MP_MEM;
	}

	fpg->numDoubles = ECFP_NUMDOUBLES;
	fpg->primeBitSize = ECFP_BSIZE;
	fpg->orderBitSize = 161;
	fpg->doubleBitSize = 24;
	fpg->numInts = (ECFP_BSIZE + ECL_BITS - 1) / ECL_BITS;
	fpg->aIsM3 = 1;
	fpg->ecfp_singleReduce = &ecfp160_singleReduce;
	fpg->ecfp_reduce = &ecfp160_reduce;
	fpg->ecfp_tidy = &ecfp_tidy;

	fpg->pt_add_jac_aff = &ecfp160_pt_add_jac_aff;
	fpg->pt_add_jac = &ecfp160_pt_add_jac;
	fpg->pt_add_jm_chud = &ecfp160_pt_add_jm_chud;
	fpg->pt_add_chud = &ecfp160_pt_add_chud;
	fpg->pt_dbl_jac = &ecfp160_pt_dbl_jac;
	fpg->pt_dbl_jm = &ecfp160_pt_dbl_jm;
	fpg->pt_dbl_aff2chud = &ecfp160_pt_dbl_aff2chud;
	fpg->precompute_chud = &ecfp160_precompute_chud;
	fpg->precompute_jac = &ecfp160_precompute_jac;

	group->point_mul = &ec_GFp_point_mul_wNAF_fp;
	group->points_mul = &ec_pts_mul_basic;
	group->extra1 = fpg;
	group->extra_free = &ec_GFp_extra_free_fp;

	ec_set_fp_precision(fpg);
	fpg->bitSize_alpha = ECFP_TWO160 * fpg->alpha[0];
	return MP_OKAY;
}
first commit 2015-10-21 05:03:22 +02:00			`/*`
			`* *** 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 using floating point operations.`
			`*`
			`* 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):`
			`* Stephen Fung <fungstep@hotmail.com>, Sun Microsystems Laboratories`
			`*`
			`* 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_fp.h"`
			`#include <stdlib.h>`

			`#define ECFP_BSIZE 160`
			`#define ECFP_NUMDOUBLES 7`

			`#include "ecp_fpinc.c"`

			`/* Performs a single step of reduction, just on the uppermost float`
			`* (assumes already tidied), and then retidies. Note, this does not`
			`* guarantee that the result will be less than p, but truncates the number`
			`* of bits. */`
			`void`
			`ecfp160_singleReduce(double d, const EC_group_fp group)`
			`{`
			`double q;`

			`ECFP_ASSERT(group->doubleBitSize == 24);`
			`ECFP_ASSERT(group->primeBitSize == 160);`
			`ECFP_ASSERT(ECFP_NUMDOUBLES == 7);`

			`q = d[ECFP_NUMDOUBLES - 1] - ecfp_beta_160;`
			`q += group->bitSize_alpha;`
			`q -= group->bitSize_alpha;`

			`d[ECFP_NUMDOUBLES - 1] -= q;`
			`d[0] += q * ecfp_twom160;`
			`d[1] += q * ecfp_twom129;`
			`ecfp_positiveTidy(d, group);`

			`/* Assertions for the highest order term */`
			`ECFP_ASSERT(d[ECFP_NUMDOUBLES - 1] / ecfp_exp[ECFP_NUMDOUBLES - 1] ==`
			`(unsigned long long) (d[ECFP_NUMDOUBLES - 1] /`
			`ecfp_exp[ECFP_NUMDOUBLES - 1]));`
			`ECFP_ASSERT(d[ECFP_NUMDOUBLES - 1] >= 0);`
			`}`

			`/* Performs imperfect reduction. This might leave some negative terms,`
			`* and one more reduction might be required for the result to be between 0`
			`* and p-1. x should not already be reduced, i.e. should have`
			`* 2*ECFP_NUMDOUBLES significant terms. x and r can be the same, but then`
			`* the upper parts of r are not zeroed */`
			`void`
			`ecfp160_reduce(double r, double x, const EC_group_fp * group)`
			`{`

			`double x7, x8, q;`

			`ECFP_ASSERT(group->doubleBitSize == 24);`
			`ECFP_ASSERT(group->primeBitSize == 160);`
			`ECFP_ASSERT(ECFP_NUMDOUBLES == 7);`

			`/* Tidy just the upper bits, the lower bits can wait. */`
			`ecfp_tidyUpper(x, group);`

			`/* Assume that this is already tidied so that we have enough extra`
			`* bits */`
			`x7 = x[7] + x[13] * ecfp_twom129; /* adds bits 15-39 */`

			`/* Tidy x7, or we won't have enough bits later to add it in */`
			`q = x7 + group->alpha[8];`
			`q -= group->alpha[8];`
			`x7 -= q; /* holds bits 0-24 */`
			`x8 = x[8] + q; /* holds bits 0-25 */`

			`r[6] = x[6] + x[13] * ecfp_twom160 + x[12] * ecfp_twom129; /* adds`
			`* bits`
			`* 8-39 */`
			`r[5] = x[5] + x[12] * ecfp_twom160 + x[11] * ecfp_twom129;`
			`r[4] = x[4] + x[11] * ecfp_twom160 + x[10] * ecfp_twom129;`
			`r[3] = x[3] + x[10] * ecfp_twom160 + x[9] * ecfp_twom129;`
			`r[2] = x[2] + x[9] * ecfp_twom160 + x8 * ecfp_twom129; /* adds bits`
			`* 8-40 */`
			`r[1] = x[1] + x8 * ecfp_twom160 + x7 * ecfp_twom129; /* adds bits`
			`* 8-39 */`
			`r[0] = x[0] + x7 * ecfp_twom160;`

			`/* Tidy up just r[ECFP_NUMDOUBLES-2] so that the number of reductions`
			`* is accurate plus or minus one. (Rather than tidy all to make it`
			`* totally accurate, which is more costly.) */`
			`q = r[ECFP_NUMDOUBLES - 2] + group->alpha[ECFP_NUMDOUBLES - 1];`
			`q -= group->alpha[ECFP_NUMDOUBLES - 1];`
			`r[ECFP_NUMDOUBLES - 2] -= q;`
			`r[ECFP_NUMDOUBLES - 1] += q;`

			`/* Tidy up the excess bits on r[ECFP_NUMDOUBLES-1] using reduction */`
			`/* Use ecfp_beta so we get a positive result */`
			`q = r[ECFP_NUMDOUBLES - 1] - ecfp_beta_160;`
			`q += group->bitSize_alpha;`
			`q -= group->bitSize_alpha;`

			`r[ECFP_NUMDOUBLES - 1] -= q;`
			`r[0] += q * ecfp_twom160;`
			`r[1] += q * ecfp_twom129;`

			`/* Tidy the result */`
			`ecfp_tidyShort(r, group);`
			`}`

			`/* Sets group to use optimized calculations in this file */`
			`mp_err`
			`ec_group_set_secp160r1_fp(ECGroup *group)`
			`{`

			`EC_group_fp *fpg = NULL;`

			`/* Allocate memory for floating point group data */`
			`fpg = (EC_group_fp *) malloc(sizeof(EC_group_fp));`
			`if (fpg == NULL) {`
			`return MP_MEM;`
			`}`

			`fpg->numDoubles = ECFP_NUMDOUBLES;`
			`fpg->primeBitSize = ECFP_BSIZE;`
			`fpg->orderBitSize = 161;`
			`fpg->doubleBitSize = 24;`
			`fpg->numInts = (ECFP_BSIZE + ECL_BITS - 1) / ECL_BITS;`
			`fpg->aIsM3 = 1;`
			`fpg->ecfp_singleReduce = &ecfp160_singleReduce;`
			`fpg->ecfp_reduce = &ecfp160_reduce;`
			`fpg->ecfp_tidy = &ecfp_tidy;`

			`fpg->pt_add_jac_aff = &ecfp160_pt_add_jac_aff;`
			`fpg->pt_add_jac = &ecfp160_pt_add_jac;`
			`fpg->pt_add_jm_chud = &ecfp160_pt_add_jm_chud;`
			`fpg->pt_add_chud = &ecfp160_pt_add_chud;`
			`fpg->pt_dbl_jac = &ecfp160_pt_dbl_jac;`
			`fpg->pt_dbl_jm = &ecfp160_pt_dbl_jm;`
			`fpg->pt_dbl_aff2chud = &ecfp160_pt_dbl_aff2chud;`
			`fpg->precompute_chud = &ecfp160_precompute_chud;`
			`fpg->precompute_jac = &ecfp160_precompute_jac;`

			`group->point_mul = &ec_GFp_point_mul_wNAF_fp;`
			`group->points_mul = &ec_pts_mul_basic;`
			`group->extra1 = fpg;`
			`group->extra_free = &ec_GFp_extra_free_fp;`

			`ec_set_fp_precision(fpg);`
			`fpg->bitSize_alpha = ECFP_TWO160 * fpg->alpha[0];`
			`return MP_OKAY;`
			`}`