📄 ake4mntt.c
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/* C version of ake4mntt.cpp
*
* No matter where you got this code from, be aware that MIRACL is NOT
* free software. For commercial use a license is required.
* See www.shamus.ie
*
Example for embedded implementation.
Should build immediately with standard mirdef.h file on a PC. For example using MS C
cl /O2 ake4mntt.c ms32.lib
To simulate performance on a PC of an 8-bit computer use
#define MR_LITTLE_ENDIAN
#define MIRACL 8
#define mr_utype char
#define MR_IBITS 32
#define MR_LBITS 32
#define mr_unsign32 unsigned int
#define mr_dltype short
#define MR_STATIC 20
#define MR_ALWAYS_BINARY
#define MR_STRIPPED_DOWN
#define MR_GENERIC_MT
#define MAXBASE ((mr_small)1<<(MIRACL-1))
#define MR_COMBA 20
#define MR_NOASM
#define MR_BITSINCHAR 8
#define MR_NOSUPPORT_COMPRESSION
rem Compile MIRACL modules
mex 20 c mrcomba
cl /c /O2 /W3 mrzzn2.c
cl /c /O2 /W3 mrcore.c
cl /c /O2 /W3 mrarth0.c
cl /c /O2 /W3 mrarth1.c
cl /c /O2 /W3 mrarth2.c
cl /c /O2 /W3 mrxgcd.c
cl /c /O2 /W3 mrbits.c
cl /c /O2 /W3 mrmonty.c
cl /c /O2 /W3 mrcurve.c
cl /c /O2 /W3 mrcomba.c
cl /c /O2 /W3 mrio1.c
cl /c /O2 /W3 mrpower.c
rem
rem Create library 'miracl.lib'
del miracl.lib
lib /OUT:miracl.lib mrxgcd.obj mrarth2.obj mrio1.obj mrcomba.obj
lib /OUT:miracl.lib miracl.lib mrmonty.obj mrarth1.obj mrarth0.obj mrcore.obj
lib /OUT:miracl.lib miracl.lib mrcurve.obj mrbits.obj mrzzn2.obj mrpower.obj
del mr*.obj
cl /O2 ake4mntt.c miracl.lib
For Atmel AVR (atmega128) use
#define MR_LITTLE_ENDIAN
#define MIRACL 8
#define mr_utype char
#define MR_IBITS 16
#define MR_LBITS 32
#define mr_unsign32 unsigned long
#define mr_dltype int
#define mr_qltype long
#define MR_STATIC 20
#define MR_ALWAYS_BINARY
#define MR_STRIPPED_DOWN
#define MR_GENERIC_MT
#define MAXBASE ((mr_small)1<<(MIRACL-1))
#define MR_COMBA 20
#define MR_NOASM
#define MR_BITSINCHAR 8
#define MR_NO_STANDARD_IO
#define MR_NO_FILE_IO
#define MR_NOSUPPORT_COMPRESSION
#define MR_AVR
This last line must be added manually - config.c will not do it automatically
and execute
mex 20 avr4 mrcomba
On an ARM use a header like
#define MR_LITTLE_ENDIAN
#define MIRACL 32
#define mr_utype int
#define MR_IBITS 32
#define MR_LBITS 32
#define mr_unsign32 unsigned int
#define mr_dltype long long
#define MR_STATIC 5
#define MR_ALWAYS_BINARY
#define MR_STRIPPED_DOWN
#define MR_GENERIC_MT
#define MAXBASE ((mr_small)1<<(MIRACL-1))
#define MR_COMBA 5
#define MR_BITSINCHAR 8
#define MR_NOSUPPORT_COMPRESSION
and possible
#define MR_NO_STANDARD_IO
#define MR_NO_FILE_IO
and execute
mex 5 arm mrcomba
*/
#include <stdio.h>
#include <stdlib.h>
#include "miracl.h"
#ifdef MR_COUNT_OPS
int fpm2,fpi2,fpc,fpa,fpx;
#endif
/* Fix the contents of k4mnt.ecs */
#if MIRACL==32
#define WORDS 5
#define NPW 8 /* Nibbles per Word */
#define ROMSZ 25
static const mr_small romp[]={
0x76A5755D,0x245769E6,0xF33DC5F3,0x42C82027,0xE3F367D5,
0x866BA034,0x14DB64EB,0xDF4CF677,0xE45200C4,0xDABC0397,
0x58290FC5,0x0BD4BB42,0x0EAEF730,0xA014F1E3,0x6B455E0,
0xC1315D34,0x92168B16,0xF191,0x0,0x0,
0xB79C2B47,0x10BEC9C5,0xE0BF4D14,0x67B5A4AC,0xB3657D09};
/* Points - in n-residue form */
#define PROMSZ 30
static const mr_small Prom[]={
0x1E6EA84F,0xE7CE6B23,0x7B6AC239,0x805022A9,0x260BF17B,
0x90898C7E,0x9D8C9BC9,0xD482E11C,0x2D4D3F68,0x1D1DA150,
0x0,0x0,0x0,0x0,0x0,
0xFC6F2323,0x4F909200,0x3CA3C030,0x162C2DE5,0x64E3CD65,
0x83EF6EA2,0x3AD75EB7,0x995AF708,0x20ED6DAA,0x6C8A7C3B,
0xE6CB7028,0x41A0F382,0x41C677A4,0x67F9C577,0x5F28122A};
#endif
#if MIRACL==8
#define WORDS 20
#define NPW 2 /* Nibbles per Word */
#define ROMSZ 100
#ifdef MR_AVR
__attribute__((__progmem__))
#endif
static const mr_small romp[]={
0x5D,0x75,0xA5,0x76,0xE6,0x69,0x57,0x24,0xF3,0xC5,0x3D,0xF3,0x27,0x20,0xC8,0x42,0xD5,0x67,0xF3,0xE3,
0x34,0xA0,0x6B,0x86,0xEB,0x64,0xDB,0x14,0x77,0xF6,0x4C,0xDF,0xC4,0x00,0x52,0xE4,0x97,0x03,0xBC,0xDA,
0xC5,0x0F,0x29,0x58,0x42,0xBB,0xD4,0x0B,0x30,0xF7,0xAE,0x0E,0xE3,0xF1,0x14,0xA0,0xE0,0x55,0xB4,0x06,
0x34,0x5D,0x31,0xC1,0x16,0x8B,0x16,0x92,0x91,0xF1,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x47,0x2B,0x9C,0xB7,0xC5,0xC9,0xBE,0x10,0x14,0x4D,0xBF,0xE0,0xAC,0xA4,0xB5,0x67,0x09,0x7D,0x65,0xB3};
#define PROMSZ 120
#ifdef MR_AVR
__attribute__((__progmem__))
#endif
static const mr_small Prom[]={
0x4F,0xA8,0x6E,0x1E,0x23,0x6B,0xCE,0xE7,0x39,0xC2,0x6A,0x7B,0xA9,0x22,0x50,0x80,0x7B,0xF1,0xB,0x26,
0x7E,0x8C,0x89,0x90,0xC9,0x9B,0x8C,0x9D,0x1C,0xE1,0x82,0xD4,0x68,0x3F,0x4D,0x2D,0x50,0xA1,0x1D,0x1D,
0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00,
0x23,0x23,0x6F,0xFC,0x0,0x92,0x90,0x4F,0x30,0xC0,0xA3,0x3C,0xE5,0x2D,0x2C,0x16,0x65,0xCD,0xE3,0x64,
0xA2,0x6E,0xEF,0x83,0xB7,0x5E,0xD7,0x3A,0x8,0xF7,0x5A,0x99,0xAA,0x6D,0xED,0x20,0x3B,0x7C,0x8A,0x6C,
0x28,0x70,0xCB,0xE6,0x82,0xF3,0xA0,0x41,0xA4,0x77,0xC6,0x41,0x77,0xC5,0xF9,0x67,0x2A,0x12,0x28,0x5F};
#endif
#define CF 34
/* Fp4 support functions */
typedef struct
{
zzn2 x;
zzn2 y;
BOOL unitary;
} zzn4;
#ifndef MR_NO_STANDARD_IO
void zzn2_out(_MIPD_ char *p,zzn2 *x)
{
printf(p); printf("\n");
redc(_MIPP_ x->a,x->a);
redc(_MIPP_ x->b,x->b);
otnum(_MIPP_ x->a,stdout);
otnum(_MIPP_ x->b,stdout);
nres(_MIPP_ x->a,x->a);
nres(_MIPP_ x->b,x->b);
}
#endif
/* Irreducible over zzn2 is x^2+n */
/* zzn4 is towered on top of this with irreducible X^2+sqrt(n) p=5 mod 8, or X^2+(1+sqrt(n)) p=3,7 mod 8 */
/* same as txx(.) function in C++ */
void zzn2_times_irp(_MIPD_ zzn2 *u)
{
zzn2 t;
switch (mr_mip->pmod8)
{
case 5: /* times sqrt(n) */
zzn2_timesi(_MIPP_ u);
break;
case 3: /* times 1+sqrt(n) */
case 7:
t.a=mr_mip->w5;
t.b=mr_mip->w6;
zzn2_copy(u,&t);
zzn2_timesi(_MIPP_ &t);
zzn2_add(_MIPP_ u,&t,u);
break;
default:
break;
}
}
void zzn4_copy(zzn4 *u,zzn4 *w)
{
if (u==w) return;
zzn2_copy(&(u->x),&(w->x));
zzn2_copy(&(u->y),&(w->y));
w->unitary=u->unitary;
}
void zzn4_from_int(_MIPD_ int i,zzn4 *w)
{
zzn2_from_int(_MIPP_ i,&(w->x));
zzn2_zero(&(w->y));
if (i==1) w->unitary=TRUE;
else w->unitary=FALSE;
}
void zzn4_conj(_MIPD_ zzn4 *u,zzn4 *w)
{
zzn4_copy(u,w);
zzn2_negate(_MIPP_ &(w->y),&(w->y));
}
void zzn4_mul(_MIPD_ zzn4 *u,zzn4 *v,zzn4 *w)
{
zzn2 t1,t2,t3;
t1.a=mr_mip->w3;
t1.b=mr_mip->w4;
t2.a=mr_mip->w8;
t2.b=mr_mip->w9;
if (u==v)
{
if (u->unitary)
{ /* this is a lot faster.. - see Lenstra & Stam */
zzn4_copy(u,w);
zzn2_mul(_MIPP_ &(w->y),&(w->y),&t1);
zzn2_add(_MIPP_ &(w->y),&(w->x),&(w->y));
zzn2_mul(_MIPP_ &(w->y),&(w->y),&(w->y));
zzn2_sub(_MIPP_ &(w->y),&t1,&(w->y));
zzn2_timesi(_MIPP_ &t1);
zzn2_copy(&t1,&(w->x));
zzn2_sub(_MIPP_ &(w->y),&(w->x),&(w->y));
zzn2_add(_MIPP_ &(w->x),&(w->x),&(w->x));
zzn2_sadd(_MIPP_ &(w->x),mr_mip->one,&(w->x));
zzn2_ssub(_MIPP_ &(w->y),mr_mip->one,&(w->y));
}
else
{
zzn4_copy(u,w);
zzn2_copy(&(w->y),&t2); // t2=b;
zzn2_add(_MIPP_ &(w->x),&t2,&t1); // t1=a+b
zzn2_times_irp(_MIPP_ &t2); // t2=txx(b);
zzn2_add(_MIPP_ &t2,&(w->x),&t2); // t2=a+txx(b)
zzn2_mul(_MIPP_ &(w->y),&(w->x),&(w->y)); // b*=a
zzn2_mul(_MIPP_ &t1,&t2,&(w->x)); // a=t1*t2
zzn2_copy(&(w->y),&t2); //t2=b
zzn2_sub(_MIPP_ &(w->x),&t2,&(w->x)); //a-=b
zzn2_times_irp(_MIPP_ &t2); // t2=txx(b)
zzn2_sub(_MIPP_ &(w->x),&t2,&(w->x)); // a-=txx(b);
zzn2_add(_MIPP_ &(w->y),&(w->y),&(w->y)); // b+=b;
}
}
else
{
t3.a=mr_mip->w10;
t3.b=mr_mip->w11;
zzn2_copy(&(u->x),&t1);
zzn2_copy(&(u->y),&t2);
zzn2_mul(_MIPP_ &t1,&(v->x),&t1);
zzn2_mul(_MIPP_ &t2,&(v->y),&t2);
zzn2_copy(&(v->x),&t3);
zzn2_add(_MIPP_ &t3,&(v->y),&t3);
zzn2_add(_MIPP_ &(u->y),&(u->x),&(w->y));
zzn2_mul(_MIPP_ &(w->y),&t3,&(w->y));
zzn2_sub(_MIPP_ &(w->y),&t1,&(w->y));
zzn2_sub(_MIPP_ &(w->y),&t2,&(w->y));
zzn2_copy(&t1,&(w->x));
zzn2_times_irp(_MIPP_ &t2);
zzn2_add(_MIPP_ &(w->x),&t2,&(w->x));
if (u->unitary && v->unitary) w->unitary=TRUE;
else w->unitary=FALSE;
}
}
/* zzn4 powering of unitary elements */
void zzn4_powu(_MIPD_ zzn4 *x,big k,zzn4 *u)
{
zzn4 t[5],u2;
big k3;
int i,j,n,nb,nbw,nzs;
#ifndef MR_STATIC
char *mem=memalloc(_MIPP_ 25);
#else
char mem[MR_BIG_RESERVE(25)];
memset(mem,0,MR_BIG_RESERVE(25));
#endif
if (size(k)==0)
{
zzn4_from_int(_MIPP_ 1,u);
return;
}
zzn4_copy(x,u);
if (size(k)==1) return;
for (j=i=0;i<5;i++)
{
t[i].x.a=mirvar_mem(_MIPP_ mem,j++);
t[i].x.b=mirvar_mem(_MIPP_ mem,j++);
t[i].y.a=mirvar_mem(_MIPP_ mem,j++);
t[i].y.b=mirvar_mem(_MIPP_ mem,j++);
t[i].unitary=FALSE;
}
u2.x.a=mirvar_mem(_MIPP_ mem,j++);
u2.x.b=mirvar_mem(_MIPP_ mem,j++);
u2.y.a=mirvar_mem(_MIPP_ mem,j++);
u2.y.b=mirvar_mem(_MIPP_ mem,j++);
u2.unitary=FALSE;
k3=mirvar_mem(_MIPP_ mem,j);
premult(_MIPP_ k,3,k3);
zzn4_mul(_MIPP_ u,u,&u2);
zzn4_copy(u,&t[0]);
for (i=1;i<=4;i++)
zzn4_mul(_MIPP_ &u2,&t[i-1],&t[i]);
nb=logb2(_MIPP_ k3);
for (i=nb-2;i>=1;)
{
n=mr_naf_window(_MIPP_ k,k3,i,&nbw,&nzs,5);
for (j=0;j<nbw;j++) zzn4_mul(_MIPP_ u,u,u);
if (n>0) zzn4_mul(_MIPP_ u,&t[n/2],u);
if (n<0)
{
zzn4_conj(_MIPP_ &t[-n/2],&u2);
zzn4_mul(_MIPP_ u,&u2,u);
}
i-=nbw;
if (nzs)
{
for (j=0;j<nzs;j++) zzn4_mul(_MIPP_ u,u,u);
i-=nzs;
}
}
#ifndef MR_STATIC
memkill(_MIPP_ mem,25);
#else
memset(mem,0,MR_BIG_RESERVE(25));
#endif
}
/* Lucas-style ladder exponentiation */
void zzn2_powl(_MIPD_ zzn2 *x,big e,zzn2 *w)
{
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