MastersThesis/TIIGER_TLS/PQ_TIIGER_TLS/sal/miracl-ubuntu22-11-04-24/includes/fp4.cpp

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2024-04-15 09:53:30 +00:00
/*
* Copyright (c) 2012-2020 MIRACL UK Ltd.
*
* This file is part of MIRACL Core
* (see https://github.com/miracl/core).
*
* Licensed under the Apache License, Version 2.0 (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.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
/* CORE Fp^4 functions */
/* SU=m, m is Stack Usage (no lazy )*/
/* FP4 elements are of the form a+ib, where i is sqrt(-1+sqrt(-1)) */
#include "fp4_YYY.h"
using namespace XXX;
/* test x==0 ? */
/* SU= 8 */
int YYY::FP4_iszilch(FP4 *x)
{
return (FP2_iszilch(&(x->a)) & FP2_iszilch(&(x->b)));
}
/* test x==1 ? */
/* SU= 8 */
int YYY::FP4_isunity(FP4 *x)
{
return (FP2_isunity(&(x->a)) & FP2_iszilch(&(x->b)));
}
/* test is w real? That is in a+ib test b is zero */
int YYY::FP4_isreal(FP4 *w)
{
return FP2_iszilch(&(w->b));
}
// Is x lexically larger than p-x?
// return -1 for no, 0 if x=0, 1 for yes
int YYY::FP4_islarger(FP4 *x)
{
int cmp;
if (FP4_iszilch(x)) return 0;
cmp=FP2_islarger(&(x->b));
if (cmp!=0) return cmp;
return FP2_islarger(&(x->a));
}
void YYY::FP4_toBytes(char *b,FP4 *x)
{
FP2_toBytes(b,&(x->b));
FP2_toBytes(&b[2*MODBYTES_XXX],&(x->a));
}
void YYY::FP4_fromBytes(FP4 *x,char *b)
{
FP2_fromBytes(&(x->b),b);
FP2_fromBytes(&(x->a),&b[2*MODBYTES_XXX]);
}
/* return 1 if x==y, else 0 */
/* SU= 16 */
int YYY::FP4_equals(FP4 *x, FP4 *y)
{
return (FP2_equals(&(x->a), &(y->a)) & FP2_equals(&(x->b), &(y->b)));
}
/* set FP4 from two FP2s */
/* SU= 16 */
void YYY::FP4_from_FP2s(FP4 *w, FP2 * x, FP2* y)
{
FP2_copy(&(w->a), x);
FP2_copy(&(w->b), y);
}
/* set FP4 from FP2 */
/* SU= 8 */
void YYY::FP4_from_FP2(FP4 *w, FP2 *x)
{
FP2_copy(&(w->a), x);
FP2_zero(&(w->b));
}
/* set high part of FP4 from FP2 */
/* SU= 8 */
void YYY::FP4_from_FP2H(FP4 *w, FP2 *x)
{
FP2_copy(&(w->b), x);
FP2_zero(&(w->a));
}
/* set FP4 from FP */
void YYY::FP4_from_FP(FP4 *w, FP *x)
{
FP2 t;
FP2_from_FP(&t, x);
FP4_from_FP2(w, &t);
}
/* FP4 copy w=x */
/* SU= 16 */
void YYY::FP4_copy(FP4 *w, FP4 *x)
{
if (w == x) return;
FP2_copy(&(w->a), &(x->a));
FP2_copy(&(w->b), &(x->b));
}
/* FP4 w=0 */
/* SU= 8 */
void YYY::FP4_zero(FP4 *w)
{
FP2_zero(&(w->a));
FP2_zero(&(w->b));
}
/* FP4 w=1 */
/* SU= 8 */
void YYY::FP4_one(FP4 *w)
{
FP2_one(&(w->a));
FP2_zero(&(w->b));
}
int YYY::FP4_sign(FP4 *w)
{
int p1,p2;
p1=FP2_sign(&(w->a));
p2=FP2_sign(&(w->b));
#ifdef BIG_ENDIAN_SIGN_YYY
p2 ^= (p1 ^ p2)&FP2_iszilch(&(w->b));
return p2;
#else
p1 ^= (p1 ^ p2)&FP2_iszilch(&(w->a));
return p1;
#endif
}
/* Set w=-x */
/* SU= 160 */
void YYY::FP4_neg(FP4 *w, FP4 *x)
{
/* Just one field neg */
FP2 m, t;
FP4_norm(x);
FP2_add(&m, &(x->a), &(x->b));
FP2_neg(&m, &m);
FP2_add(&t, &m, &(x->b));
FP2_add(&(w->b), &m, &(x->a));
FP2_copy(&(w->a), &t);
FP4_norm(w);
}
/* Set w=conj(x) */
/* SU= 16 */
void YYY::FP4_conj(FP4 *w, FP4 *x)
{
FP2_copy(&(w->a), &(x->a));
FP2_neg(&(w->b), &(x->b));
FP4_norm(w);
}
/* Set w=-conj(x) */
/* SU= 16 */
void YYY::FP4_nconj(FP4 *w, FP4 *x)
{
FP2_copy(&(w->b), &(x->b));
FP2_neg(&(w->a), &(x->a));
FP4_norm(w);
}
/* Set w=x+y */
/* SU= 16 */
void YYY::FP4_add(FP4 *w, FP4 *x, FP4 *y)
{
FP2_add(&(w->a), &(x->a), &(y->a));
FP2_add(&(w->b), &(x->b), &(y->b));
}
/* Set w=x-y */
/* Input y MUST be normed */
void YYY::FP4_sub(FP4 *w, FP4 *x, FP4 *y)
{
FP4 my;
FP4_neg(&my, y);
FP4_add(w, x, &my);
}
/* SU= 8 */
/* reduce all components of w mod Modulus */
void YYY::FP4_reduce(FP4 *w)
{
FP2_reduce(&(w->a));
FP2_reduce(&(w->b));
}
/* SU= 8 */
/* normalise all elements of w */
void YYY::FP4_norm(FP4 *w)
{
FP2_norm(&(w->a));
FP2_norm(&(w->b));
}
/* Set w=s*x, where s is FP2 */
/* SU= 16 */
void YYY::FP4_pmul(FP4 *w, FP4 *x, FP2 *s)
{
FP2_mul(&(w->a), &(x->a), s);
FP2_mul(&(w->b), &(x->b), s);
}
/* Set w=s*x, where s is FP */
void YYY::FP4_qmul(FP4 *w, FP4 *x, FP *s)
{
FP2_pmul(&(w->a), &(x->a), s);
FP2_pmul(&(w->b), &(x->b), s);
}
/* SU= 16 */
/* Set w=s*x, where s is int */
void YYY::FP4_imul(FP4 *w, FP4 *x, int s)
{
FP2_imul(&(w->a), &(x->a), s);
FP2_imul(&(w->b), &(x->b), s);
}
/* Set w=x^2 */
/* Input MUST be normed */
void YYY::FP4_sqr(FP4 *w, FP4 *x)
{
FP2 t1, t2, t3;
FP2_mul(&t3, &(x->a), &(x->b)); /* norms x */
FP2_copy(&t2, &(x->b));
FP2_add(&t1, &(x->a), &(x->b));
FP2_mul_ip(&t2);
FP2_add(&t2, &(x->a), &t2);
FP2_norm(&t1); // 2
FP2_norm(&t2); // 2
FP2_mul(&(w->a), &t1, &t2);
FP2_copy(&t2, &t3);
FP2_mul_ip(&t2);
FP2_add(&t2, &t2, &t3);
FP2_norm(&t2); // 2
FP2_neg(&t2, &t2);
FP2_add(&(w->a), &(w->a), &t2); /* a=(a+b)(a+i^2.b)-i^2.ab-ab = a*a+ib*ib */
FP2_add(&(w->b), &t3, &t3); /* b=2ab */
FP4_norm(w);
}
/* Set w=x*y */
/* Inputs MUST be normed */
void YYY::FP4_mul(FP4 *w, FP4 *x, FP4 *y)
{
FP2 t1, t2, t3, t4;
FP2_mul(&t1, &(x->a), &(y->a));
FP2_mul(&t2, &(x->b), &(y->b));
FP2_add(&t3, &(y->b), &(y->a));
FP2_add(&t4, &(x->b), &(x->a));
FP2_norm(&t4); // 2
FP2_norm(&t3); // 2
FP2_mul(&t4, &t4, &t3); /* (xa+xb)(ya+yb) */
FP2_neg(&t3, &t1); // 1
FP2_add(&t4, &t4, &t3); //t4E=3
FP2_norm(&t4);
FP2_neg(&t3, &t2); // 1
FP2_add(&(w->b), &t4, &t3); //wbE=3
FP2_mul_ip(&t2);
FP2_add(&(w->a), &t2, &t1);
FP4_norm(w);
}
/* output FP4 in format [a,b] */
/* SU= 8 */
void YYY::FP4_output(FP4 *w)
{
printf("[");
FP2_output(&(w->a));
printf(",");
FP2_output(&(w->b));
printf("]");
}
/* SU= 8 */
void YYY::FP4_rawoutput(FP4 *w)
{
printf("[");
FP2_rawoutput(&(w->a));
printf(",");
FP2_rawoutput(&(w->b));
printf("]");
}
/* Set w=1/x */
/* SU= 160 */
void YYY::FP4_inv(FP4 *w, FP4 *x, FP *h)
{
FP2 t1, t2;
FP2_sqr(&t1, &(x->a));
FP2_sqr(&t2, &(x->b));
FP2_mul_ip(&t2);
FP2_norm(&t2);
FP2_sub(&t1, &t1, &t2);
FP2_inv(&t1, &t1, h);
FP2_mul(&(w->a), &t1, &(x->a));
FP2_neg(&t1, &t1);
FP2_norm(&t1);
FP2_mul(&(w->b), &t1, &(x->b));
}
/* w*=i where i = sqrt(2^i+sqrt(-1)) */
/* SU= 200 */
void YYY::FP4_times_i(FP4 *w)
{
FP2 t;
FP2_copy(&t, &(w->b));
FP2_copy(&(w->b), &(w->a));
FP2_mul_ip(&t);
FP2_copy(&(w->a), &t);
FP4_norm(w);
#if TOWER_YYY == POSITOWER
FP4_neg(w, w); // ***
FP4_norm(w);
#endif
}
/* Set w=w^p using Frobenius */
/* SU= 16 */
void YYY::FP4_frob(FP4 *w, FP2 *f)
{
FP2_conj(&(w->a), &(w->a));
FP2_conj(&(w->b), &(w->b));
FP2_mul( &(w->b), f, &(w->b));
}
/* Set r=a^b mod m */
/* SU= 240 */
/*
void YYY::FP4_pow(FP4 *r, FP4* a, BIG b)
{
FP4 w;
BIG z, zilch;
int bt;
BIG_zero(zilch);
BIG_copy(z, b);
BIG_norm(z);
FP4_copy(&w, a);
FP4_norm(&w);
FP4_one(r);
while (1)
{
bt = BIG_parity(z);
BIG_shr(z, 1);
if (bt) FP4_mul(r, r, &w);
if (BIG_comp(z, zilch) == 0) break;
FP4_sqr(&w, &w);
}
FP4_reduce(r);
}
*/
#if CURVE_SECURITY_ZZZ == 128
/* SU= 304 */
/* XTR xtr_a function */
void YYY::FP4_xtr_A(FP4 *r, FP4 *w, FP4 *x, FP4 *y, FP4 *z)
{
FP4 t1, t2;
FP4_copy(r, x);
FP4_sub(&t1, w, y);
FP4_norm(&t1);
FP4_pmul(&t1, &t1, &(r->a));
FP4_add(&t2, w, y);
FP4_norm(&t2);
FP4_pmul(&t2, &t2, &(r->b));
FP4_times_i(&t2);
FP4_add(r, &t1, &t2);
FP4_add(r, r, z);
FP4_reduce(r);
}
/* SU= 152 */
/* XTR xtr_d function */
void YYY::FP4_xtr_D(FP4 *r, FP4 *x)
{
FP4 w;
FP4_copy(r, x);
FP4_conj(&w, r);
FP4_add(&w, &w, &w);
FP4_sqr(r, r);
FP4_norm(&w);
FP4_sub(r, r, &w);
FP4_reduce(r); /* reduce here as multiple calls trigger automatic reductions */
}
/* SU= 728 */
/* r=x^n using XTR method on traces of FP12s */
void YYY::FP4_xtr_pow(FP4 *r, FP4 *x, BIG n)
{
int i, par, nb;
BIG v;
FP2 w;
FP4 t, a, b, c, sf;
BIG_zero(v);
BIG_inc(v, 3);
BIG_norm(v);
FP2_from_BIG(&w, v);
FP4_from_FP2(&a, &w);
FP4_copy(&sf, x);
FP4_norm(&sf);
FP4_copy(&b, &sf);
FP4_xtr_D(&c, &sf);
par = BIG_parity(n);
BIG_copy(v, n);
BIG_norm(v);
BIG_shr(v, 1);
if (par == 0)
{
BIG_dec(v, 1);
BIG_norm(v);
}
nb = BIG_nbits(v);
for (i = nb - 1; i >= 0; i--)
{
if (!BIG_bit(v, i))
{
FP4_copy(&t, &b);
FP4_conj(&sf, &sf);
FP4_conj(&c, &c);
FP4_xtr_A(&b, &a, &b, &sf, &c);
FP4_conj(&sf, &sf);
FP4_xtr_D(&c, &t);
FP4_xtr_D(&a, &a);
}
else
{
FP4_conj(&t, &a);
FP4_xtr_D(&a, &b);
FP4_xtr_A(&b, &c, &b, &sf, &t);
FP4_xtr_D(&c, &c);
}
}
if (par == 0) FP4_copy(r, &c);
else FP4_copy(r, &b);
FP4_reduce(r);
}
/* SU= 872 */
/* r=ck^a.cl^n using XTR double exponentiation method on traces of FP12s. See Stam thesis. */
void YYY::FP4_xtr_pow2(FP4 *r, FP4 *ck, FP4 *cl, FP4 *ckml, FP4 *ckm2l, BIG a, BIG b)
{
int i, f2;
BIG d, e, w;
FP4 t, cu, cv, cumv, cum2v;
BIG_copy(e, a);
BIG_copy(d, b);
BIG_norm(e);
BIG_norm(d);
FP4_copy(&cu, ck);
FP4_copy(&cv, cl);
FP4_copy(&cumv, ckml);
FP4_copy(&cum2v, ckm2l);
f2 = 0;
while (BIG_parity(d) == 0 && BIG_parity(e) == 0)
{
BIG_shr(d, 1);
BIG_shr(e, 1);
f2++;
}
while (BIG_comp(d, e) != 0)
{
if (BIG_comp(d, e) > 0)
{
BIG_imul(w, e, 4);
BIG_norm(w);
if (BIG_comp(d, w) <= 0)
{
BIG_copy(w, d);
BIG_copy(d, e);
BIG_sub(e, w, e);
BIG_norm(e);
FP4_xtr_A(&t, &cu, &cv, &cumv, &cum2v);
FP4_conj(&cum2v, &cumv);
FP4_copy(&cumv, &cv);
FP4_copy(&cv, &cu);
FP4_copy(&cu, &t);
}
else if (BIG_parity(d) == 0)
{
BIG_shr(d, 1);
FP4_conj(r, &cum2v);
FP4_xtr_A(&t, &cu, &cumv, &cv, r);
FP4_xtr_D(&cum2v, &cumv);
FP4_copy(&cumv, &t);
FP4_xtr_D(&cu, &cu);
}
else if (BIG_parity(e) == 1)
{
BIG_sub(d, d, e);
BIG_norm(d);
BIG_shr(d, 1);
FP4_xtr_A(&t, &cu, &cv, &cumv, &cum2v);
FP4_xtr_D(&cu, &cu);
FP4_xtr_D(&cum2v, &cv);
FP4_conj(&cum2v, &cum2v);
FP4_copy(&cv, &t);
}
else
{
BIG_copy(w, d);
BIG_copy(d, e);
BIG_shr(d, 1);
BIG_copy(e, w);
FP4_xtr_D(&t, &cumv);
FP4_conj(&cumv, &cum2v);
FP4_conj(&cum2v, &t);
FP4_xtr_D(&t, &cv);
FP4_copy(&cv, &cu);
FP4_copy(&cu, &t);
}
}
if (BIG_comp(d, e) < 0)
{
BIG_imul(w, d, 4);
BIG_norm(w);
if (BIG_comp(e, w) <= 0)
{
BIG_sub(e, e, d);
BIG_norm(e);
FP4_xtr_A(&t, &cu, &cv, &cumv, &cum2v);
FP4_copy(&cum2v, &cumv);
FP4_copy(&cumv, &cu);
FP4_copy(&cu, &t);
}
else if (BIG_parity(e) == 0)
{
BIG_copy(w, d);
BIG_copy(d, e);
BIG_shr(d, 1);
BIG_copy(e, w);
FP4_xtr_D(&t, &cumv);
FP4_conj(&cumv, &cum2v);
FP4_conj(&cum2v, &t);
FP4_xtr_D(&t, &cv);
FP4_copy(&cv, &cu);
FP4_copy(&cu, &t);
}
else if (BIG_parity(d) == 1)
{
BIG_copy(w, e);
BIG_copy(e, d);
BIG_sub(w, w, d);
BIG_norm(w);
BIG_copy(d, w);
BIG_shr(d, 1);
FP4_xtr_A(&t, &cu, &cv, &cumv, &cum2v);
FP4_conj(&cumv, &cumv);
FP4_xtr_D(&cum2v, &cu);
FP4_conj(&cum2v, &cum2v);
FP4_xtr_D(&cu, &cv);
FP4_copy(&cv, &t);
}
else
{
BIG_shr(d, 1);
FP4_conj(r, &cum2v);
FP4_xtr_A(&t, &cu, &cumv, &cv, r);
FP4_xtr_D(&cum2v, &cumv);
FP4_copy(&cumv, &t);
FP4_xtr_D(&cu, &cu);
}
}
}
FP4_xtr_A(r, &cu, &cv, &cumv, &cum2v);
for (i = 0; i < f2; i++) FP4_xtr_D(r, r);
FP4_xtr_pow(r, r, d);
}
#endif
/* New stuff for ECp4 support */
/* Set w=x/2 */
void YYY::FP4_div2(FP4 *w, FP4 *x)
{
FP2_div2(&(w->a), &(x->a));
FP2_div2(&(w->b), &(x->b));
}
/* Move b to a if d=1 */
void YYY::FP4_cmove(FP4 *f, FP4 *g, int d)
{
FP2_cmove(&(f->a), &(g->a), d);
FP2_cmove(&(f->b), &(g->b), d);
}
void YYY::FP4_rand(FP4 *x,csprng *rng)
{
FP2_rand(&(x->a),rng);
FP2_rand(&(x->b),rng);
}
#if PAIRING_FRIENDLY_ZZZ >= BLS24_CURVE
/* test for x a QR */
int YYY::FP4_qr(FP4 *x, FP *h)
{ /* test x^(p^4-1)/2 = 1 */
FP4 c;
FP4_conj(&c,x);
FP4_mul(&c,&c,x);
return FP2_qr(&(c.a),h);
}
/* sqrt(a+xb) = sqrt((a+sqrt(a*a-n*b*b))/2)+x.b/(2*sqrt((a+sqrt(a*a-n*b*b))/2)) */
void YYY::FP4_sqrt(FP4 *r, FP4* x, FP *h)
{
FP2 a, b, s, t;
FP hint,twk;
FP4 nr;
int sgn,qr;
FP4_copy(r, x);
if (FP4_iszilch(x)) return;
FP2_copy(&a, &(x->a));
FP2_copy(&s, &(x->b));
FP2_sqr(&s, &s); // s*=s
FP2_sqr(&a, &a); // a*=a
FP2_mul_ip(&s);
FP2_norm(&s);
FP2_sub(&a, &a, &s); // a-=txx(s)
FP2_norm(&a); // **
FP2_sqrt(&s, &a, h); // Cost = +1
FP2_add(&a, &(r->a), &s);
FP2_norm(&a);
FP2_div2(&a, &a);
FP2_div2(&b,&(r->b)); // w1=b/2
qr=FP2_qr(&a,&hint); // only exp! Cost=+1
// tweak hint - multiply old hint by Norm(1/Beta)^e where Beta is irreducible polynomial
FP2_copy(&s,&a);
FP_rcopy(&twk,TWK);
FP_mul(&twk,&twk,&hint);
FP2_div_ip(&s); FP2_norm(&s); // switch to other candidate
FP2_cmove(&a,&s,1-qr);
FP_cmove(&hint,&twk,1-qr);
FP2_sqrt(&(r->a),&a,&hint); // a=sqrt(w2) Cost=+1
FP2_inv(&s,&a,&hint); // w3=1/w2
FP2_mul(&s,&s,&(r->a)); // w3=1/sqrt(w2)
FP2_mul(&(r->b),&s,&b); // b=(b/2)*1/sqrt(w2)
FP2_copy(&t,&(r->a));
FP2_cmove(&(r->a),&(r->b),1-qr);
FP2_cmove(&(r->b),&t,1-qr);
sgn=FP4_sign(r);
FP4_neg(&nr,r); FP4_norm(&nr);
FP4_cmove(r,&nr,sgn);
}
void YYY::FP4_div_i(FP4 *f)
{
FP2 u, v;
FP2_copy(&u, &(f->a));
FP2_copy(&v, &(f->b));
FP2_div_ip(&u);
FP2_copy(&(f->a), &v);
FP2_copy(&(f->b), &u);
#if TOWER_YYY == POSITOWER
FP4_neg(f, f); // ***
FP4_norm(f);
#endif
}
#endif