mirror of
https://github.com/rn10950/RetroZilla.git
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370 lines
12 KiB
C
370 lines
12 KiB
C
/*
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* ***** BEGIN LICENSE BLOCK *****
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* Version: MPL 1.1/GPL 2.0/LGPL 2.1
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*
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* The contents of this file are subject to the Mozilla Public License Version
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* 1.1 (the "License"); you may not use this file except in compliance with
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* the License. You may obtain a copy of the License at
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* http://www.mozilla.org/MPL/
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*
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* Software distributed under the License is distributed on an "AS IS" basis,
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* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
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* for the specific language governing rights and limitations under the
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* License.
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*
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* The Original Code is the elliptic curve math library for binary polynomial field curves.
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*
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* The Initial Developer of the Original Code is
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* Sun Microsystems, Inc.
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* Portions created by the Initial Developer are Copyright (C) 2003
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* the Initial Developer. All Rights Reserved.
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*
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* Contributor(s):
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* Sheueling Chang-Shantz <sheueling.chang@sun.com>,
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* Stephen Fung <fungstep@hotmail.com>, and
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* Douglas Stebila <douglas@stebila.ca>, Sun Microsystems Laboratories.
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*
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* Alternatively, the contents of this file may be used under the terms of
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* either the GNU General Public License Version 2 or later (the "GPL"), or
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* the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
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* in which case the provisions of the GPL or the LGPL are applicable instead
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* of those above. If you wish to allow use of your version of this file only
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* under the terms of either the GPL or the LGPL, and not to allow others to
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* use your version of this file under the terms of the MPL, indicate your
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* decision by deleting the provisions above and replace them with the notice
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* and other provisions required by the GPL or the LGPL. If you do not delete
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* the provisions above, a recipient may use your version of this file under
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* the terms of any one of the MPL, the GPL or the LGPL.
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*
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* ***** END LICENSE BLOCK ***** */
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#include "ec2.h"
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#include "mplogic.h"
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#include "mp_gf2m.h"
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#include <stdlib.h>
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#ifdef ECL_DEBUG
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#include <assert.h>
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#endif
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/* by default, these routines are unused and thus don't need to be compiled */
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#ifdef ECL_ENABLE_GF2M_PROJ
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/* Converts a point P(px, py) from affine coordinates to projective
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* coordinates R(rx, ry, rz). Assumes input is already field-encoded using
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* field_enc, and returns output that is still field-encoded. */
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mp_err
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ec_GF2m_pt_aff2proj(const mp_int *px, const mp_int *py, mp_int *rx,
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mp_int *ry, mp_int *rz, const ECGroup *group)
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{
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mp_err res = MP_OKAY;
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MP_CHECKOK(mp_copy(px, rx));
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MP_CHECKOK(mp_copy(py, ry));
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MP_CHECKOK(mp_set_int(rz, 1));
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if (group->meth->field_enc) {
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MP_CHECKOK(group->meth->field_enc(rz, rz, group->meth));
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}
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CLEANUP:
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return res;
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}
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/* Converts a point P(px, py, pz) from projective coordinates to affine
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* coordinates R(rx, ry). P and R can share x and y coordinates. Assumes
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* input is already field-encoded using field_enc, and returns output that
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* is still field-encoded. */
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mp_err
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ec_GF2m_pt_proj2aff(const mp_int *px, const mp_int *py, const mp_int *pz,
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mp_int *rx, mp_int *ry, const ECGroup *group)
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{
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mp_err res = MP_OKAY;
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mp_int z1, z2;
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MP_DIGITS(&z1) = 0;
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MP_DIGITS(&z2) = 0;
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MP_CHECKOK(mp_init(&z1));
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MP_CHECKOK(mp_init(&z2));
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/* if point at infinity, then set point at infinity and exit */
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if (ec_GF2m_pt_is_inf_proj(px, py, pz) == MP_YES) {
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MP_CHECKOK(ec_GF2m_pt_set_inf_aff(rx, ry));
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goto CLEANUP;
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}
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/* transform (px, py, pz) into (px / pz, py / pz^2) */
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if (mp_cmp_d(pz, 1) == 0) {
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MP_CHECKOK(mp_copy(px, rx));
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MP_CHECKOK(mp_copy(py, ry));
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} else {
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MP_CHECKOK(group->meth->field_div(NULL, pz, &z1, group->meth));
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MP_CHECKOK(group->meth->field_sqr(&z1, &z2, group->meth));
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MP_CHECKOK(group->meth->field_mul(px, &z1, rx, group->meth));
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MP_CHECKOK(group->meth->field_mul(py, &z2, ry, group->meth));
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}
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CLEANUP:
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mp_clear(&z1);
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mp_clear(&z2);
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return res;
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}
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/* Checks if point P(px, py, pz) is at infinity. Uses projective
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* coordinates. */
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mp_err
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ec_GF2m_pt_is_inf_proj(const mp_int *px, const mp_int *py,
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const mp_int *pz)
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{
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return mp_cmp_z(pz);
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}
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/* Sets P(px, py, pz) to be the point at infinity. Uses projective
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* coordinates. */
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mp_err
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ec_GF2m_pt_set_inf_proj(mp_int *px, mp_int *py, mp_int *pz)
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{
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mp_zero(pz);
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return MP_OKAY;
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}
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/* Computes R = P + Q where R is (rx, ry, rz), P is (px, py, pz) and Q is
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* (qx, qy, 1). Elliptic curve points P, Q, and R can all be identical.
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* Uses mixed projective-affine coordinates. Assumes input is already
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* field-encoded using field_enc, and returns output that is still
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* field-encoded. Uses equation (3) from Hankerson, Hernandez, Menezes.
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* Software Implementation of Elliptic Curve Cryptography Over Binary
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* Fields. */
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mp_err
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ec_GF2m_pt_add_proj(const mp_int *px, const mp_int *py, const mp_int *pz,
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const mp_int *qx, const mp_int *qy, mp_int *rx,
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mp_int *ry, mp_int *rz, const ECGroup *group)
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{
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mp_err res = MP_OKAY;
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mp_int A, B, C, D, E, F, G;
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/* If either P or Q is the point at infinity, then return the other
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* point */
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if (ec_GF2m_pt_is_inf_proj(px, py, pz) == MP_YES) {
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return ec_GF2m_pt_aff2proj(qx, qy, rx, ry, rz, group);
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}
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if (ec_GF2m_pt_is_inf_aff(qx, qy) == MP_YES) {
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MP_CHECKOK(mp_copy(px, rx));
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MP_CHECKOK(mp_copy(py, ry));
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return mp_copy(pz, rz);
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}
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MP_DIGITS(&A) = 0;
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MP_DIGITS(&B) = 0;
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MP_DIGITS(&C) = 0;
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MP_DIGITS(&D) = 0;
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MP_DIGITS(&E) = 0;
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MP_DIGITS(&F) = 0;
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MP_DIGITS(&G) = 0;
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MP_CHECKOK(mp_init(&A));
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MP_CHECKOK(mp_init(&B));
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MP_CHECKOK(mp_init(&C));
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MP_CHECKOK(mp_init(&D));
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MP_CHECKOK(mp_init(&E));
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MP_CHECKOK(mp_init(&F));
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MP_CHECKOK(mp_init(&G));
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/* D = pz^2 */
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MP_CHECKOK(group->meth->field_sqr(pz, &D, group->meth));
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/* A = qy * pz^2 + py */
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MP_CHECKOK(group->meth->field_mul(qy, &D, &A, group->meth));
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MP_CHECKOK(group->meth->field_add(&A, py, &A, group->meth));
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/* B = qx * pz + px */
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MP_CHECKOK(group->meth->field_mul(qx, pz, &B, group->meth));
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MP_CHECKOK(group->meth->field_add(&B, px, &B, group->meth));
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/* C = pz * B */
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MP_CHECKOK(group->meth->field_mul(pz, &B, &C, group->meth));
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/* D = B^2 * (C + a * pz^2) (using E as a temporary variable) */
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MP_CHECKOK(group->meth->
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field_mul(&group->curvea, &D, &D, group->meth));
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MP_CHECKOK(group->meth->field_add(&C, &D, &D, group->meth));
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MP_CHECKOK(group->meth->field_sqr(&B, &E, group->meth));
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MP_CHECKOK(group->meth->field_mul(&E, &D, &D, group->meth));
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/* rz = C^2 */
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MP_CHECKOK(group->meth->field_sqr(&C, rz, group->meth));
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/* E = A * C */
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MP_CHECKOK(group->meth->field_mul(&A, &C, &E, group->meth));
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/* rx = A^2 + D + E */
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MP_CHECKOK(group->meth->field_sqr(&A, rx, group->meth));
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MP_CHECKOK(group->meth->field_add(rx, &D, rx, group->meth));
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MP_CHECKOK(group->meth->field_add(rx, &E, rx, group->meth));
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/* F = rx + qx * rz */
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MP_CHECKOK(group->meth->field_mul(qx, rz, &F, group->meth));
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MP_CHECKOK(group->meth->field_add(rx, &F, &F, group->meth));
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/* G = rx + qy * rz */
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MP_CHECKOK(group->meth->field_mul(qy, rz, &G, group->meth));
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MP_CHECKOK(group->meth->field_add(rx, &G, &G, group->meth));
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/* ry = E * F + rz * G (using G as a temporary variable) */
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MP_CHECKOK(group->meth->field_mul(rz, &G, &G, group->meth));
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MP_CHECKOK(group->meth->field_mul(&E, &F, ry, group->meth));
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MP_CHECKOK(group->meth->field_add(ry, &G, ry, group->meth));
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CLEANUP:
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mp_clear(&A);
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mp_clear(&B);
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mp_clear(&C);
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mp_clear(&D);
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mp_clear(&E);
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mp_clear(&F);
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mp_clear(&G);
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return res;
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}
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/* Computes R = 2P. Elliptic curve points P and R can be identical. Uses
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* projective coordinates.
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*
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* Assumes input is already field-encoded using field_enc, and returns
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* output that is still field-encoded.
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*
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* Uses equation (3) from Hankerson, Hernandez, Menezes. Software
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* Implementation of Elliptic Curve Cryptography Over Binary Fields.
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*/
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mp_err
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ec_GF2m_pt_dbl_proj(const mp_int *px, const mp_int *py, const mp_int *pz,
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mp_int *rx, mp_int *ry, mp_int *rz,
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const ECGroup *group)
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{
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mp_err res = MP_OKAY;
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mp_int t0, t1;
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if (ec_GF2m_pt_is_inf_proj(px, py, pz) == MP_YES) {
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return ec_GF2m_pt_set_inf_proj(rx, ry, rz);
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}
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MP_DIGITS(&t0) = 0;
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MP_DIGITS(&t1) = 0;
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MP_CHECKOK(mp_init(&t0));
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MP_CHECKOK(mp_init(&t1));
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/* t0 = px^2 */
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/* t1 = pz^2 */
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MP_CHECKOK(group->meth->field_sqr(px, &t0, group->meth));
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MP_CHECKOK(group->meth->field_sqr(pz, &t1, group->meth));
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/* rz = px^2 * pz^2 */
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MP_CHECKOK(group->meth->field_mul(&t0, &t1, rz, group->meth));
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/* t0 = px^4 */
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/* t1 = b * pz^4 */
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MP_CHECKOK(group->meth->field_sqr(&t0, &t0, group->meth));
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MP_CHECKOK(group->meth->field_sqr(&t1, &t1, group->meth));
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MP_CHECKOK(group->meth->
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field_mul(&group->curveb, &t1, &t1, group->meth));
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/* rx = px^4 + b * pz^4 */
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MP_CHECKOK(group->meth->field_add(&t0, &t1, rx, group->meth));
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/* ry = b * pz^4 * rz + rx * (a * rz + py^2 + b * pz^4) */
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MP_CHECKOK(group->meth->field_sqr(py, ry, group->meth));
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MP_CHECKOK(group->meth->field_add(ry, &t1, ry, group->meth));
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/* t0 = a * rz */
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MP_CHECKOK(group->meth->
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field_mul(&group->curvea, rz, &t0, group->meth));
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MP_CHECKOK(group->meth->field_add(&t0, ry, ry, group->meth));
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MP_CHECKOK(group->meth->field_mul(rx, ry, ry, group->meth));
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/* t1 = b * pz^4 * rz */
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MP_CHECKOK(group->meth->field_mul(&t1, rz, &t1, group->meth));
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MP_CHECKOK(group->meth->field_add(&t1, ry, ry, group->meth));
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CLEANUP:
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mp_clear(&t0);
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mp_clear(&t1);
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return res;
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}
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/* Computes R = nP where R is (rx, ry) and P is (px, py). The parameters
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* a, b and p are the elliptic curve coefficients and the prime that
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* determines the field GF2m. Elliptic curve points P and R can be
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* identical. Uses mixed projective-affine coordinates. Assumes input is
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* already field-encoded using field_enc, and returns output that is still
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* field-encoded. Uses 4-bit window method. */
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mp_err
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ec_GF2m_pt_mul_proj(const mp_int *n, const mp_int *px, const mp_int *py,
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mp_int *rx, mp_int *ry, const ECGroup *group)
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{
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mp_err res = MP_OKAY;
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mp_int precomp[16][2], rz;
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mp_digit precomp_arr[ECL_MAX_FIELD_SIZE_DIGITS * 16 * 2], *t;
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int i, ni, d;
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ARGCHK(group != NULL, MP_BADARG);
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ARGCHK((n != NULL) && (px != NULL) && (py != NULL), MP_BADARG);
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/* initialize precomputation table */
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t = precomp_arr;
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for (i = 0; i < 16; i++) {
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/* x co-ord */
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MP_SIGN(&precomp[i][0]) = MP_ZPOS;
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MP_ALLOC(&precomp[i][0]) = ECL_MAX_FIELD_SIZE_DIGITS;
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MP_USED(&precomp[i][0]) = 1;
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*t = 0;
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MP_DIGITS(&precomp[i][0]) = t;
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t += ECL_MAX_FIELD_SIZE_DIGITS;
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/* y co-ord */
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MP_SIGN(&precomp[i][1]) = MP_ZPOS;
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MP_ALLOC(&precomp[i][1]) = ECL_MAX_FIELD_SIZE_DIGITS;
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MP_USED(&precomp[i][1]) = 1;
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*t = 0;
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MP_DIGITS(&precomp[i][1]) = t;
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t += ECL_MAX_FIELD_SIZE_DIGITS;
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}
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/* fill precomputation table */
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mp_zero(&precomp[0][0]);
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mp_zero(&precomp[0][1]);
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MP_CHECKOK(mp_copy(px, &precomp[1][0]));
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MP_CHECKOK(mp_copy(py, &precomp[1][1]));
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for (i = 2; i < 16; i++) {
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MP_CHECKOK(group->
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point_add(&precomp[1][0], &precomp[1][1],
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&precomp[i - 1][0], &precomp[i - 1][1],
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&precomp[i][0], &precomp[i][1], group));
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}
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d = (mpl_significant_bits(n) + 3) / 4;
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/* R = inf */
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MP_DIGITS(&rz) = 0;
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MP_CHECKOK(mp_init(&rz));
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MP_CHECKOK(ec_GF2m_pt_set_inf_proj(rx, ry, &rz));
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for (i = d - 1; i >= 0; i--) {
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/* compute window ni */
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ni = MP_GET_BIT(n, 4 * i + 3);
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ni <<= 1;
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ni |= MP_GET_BIT(n, 4 * i + 2);
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ni <<= 1;
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ni |= MP_GET_BIT(n, 4 * i + 1);
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ni <<= 1;
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ni |= MP_GET_BIT(n, 4 * i);
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/* R = 2^4 * R */
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MP_CHECKOK(ec_GF2m_pt_dbl_proj(rx, ry, &rz, rx, ry, &rz, group));
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MP_CHECKOK(ec_GF2m_pt_dbl_proj(rx, ry, &rz, rx, ry, &rz, group));
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MP_CHECKOK(ec_GF2m_pt_dbl_proj(rx, ry, &rz, rx, ry, &rz, group));
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MP_CHECKOK(ec_GF2m_pt_dbl_proj(rx, ry, &rz, rx, ry, &rz, group));
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/* R = R + (ni * P) */
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MP_CHECKOK(ec_GF2m_pt_add_proj
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(rx, ry, &rz, &precomp[ni][0], &precomp[ni][1], rx, ry,
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&rz, group));
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}
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/* convert result S to affine coordinates */
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MP_CHECKOK(ec_GF2m_pt_proj2aff(rx, ry, &rz, rx, ry, group));
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CLEANUP:
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mp_clear(&rz);
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return res;
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}
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#endif
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