double mult_precomp(int eb,big x,big y,big a,big b,big p)
{
big e,c,d;
int iterations=0;
ebrick binst;
clock_t start;
double elapsed;
char *mem;
mem=(char *)memalloc(3);
e=mirvar_mem(mem,0);
c=mirvar_mem(mem,1);
d=mirvar_mem(mem,2);
ebrick_init(&binst,x,y,a,b,p,WINDOW,eb);
bigbits(eb,e);
start=clock();
do {
mul_brick(&binst,e,c,d);
iterations++;
elapsed=(clock()-start)/(double)CLOCKS_PER_SEC;
} while (elapsed<MIN_TIME || iterations<MIN_ITERS);
elapsed=1000.0*elapsed/iterations;
printf("EP - %8d iterations ",iterations);
printf(" %8.2lf ms per iteration\n",elapsed);
ebrick_end(&binst);
memkill(mem,3);
return elapsed;
}
int main()
{
FILE *fp;
big e,n,a,b,x,y,r;
epoint *g;
ebrick binst;
int i,d,ndig,nb,best,time,store,base,bits;
miracl *mip=mirsys(50,0);
n=mirvar(0);
e=mirvar(0);
a=mirvar(0);
b=mirvar(0);
x=mirvar(0);
y=mirvar(0);
r=mirvar(0);
fp=fopen("common.ecs","r");
fscanf(fp,"%d\n",&bits);
mip->IOBASE=16;
cinnum(n,fp);
cinnum(a,fp);
cinnum(b,fp);
cinnum(r,fp);
cinnum(x,fp);
cinnum(y,fp);
mip->IOBASE=10;
printf("modulus is %d bits in length\n",logb2(n));
printf("Enter size of exponent in bits = ");
scanf("%d",&nb);
getchar();
ebrick_init(&binst,x,y,a,b,n,nb);
printf("%d big numbers have been precomputed and stored\n",binst.store);
bigdig(nb,2,e); /* random exponent */
printf("naive method\n");
ecurve_init(a,b,n,MR_PROJECTIVE);
g=epoint_init();
epoint_set(x,y,0,g);
ecurve_mult(e,g,g);
epoint_get(g,x,y);
cotnum(x,stdout);
cotnum(y,stdout);
printf("Brickel et al method\n");
mul_brick(&binst,e,x,y);
ebrick_end(&binst);
cotnum(x,stdout);
cotnum(y,stdout);
return 0;
}
void BaseOT::Miracl_brickend(ebrick* bg)
{
ebrick_end(bg);
}
int main()
{
FILE *fp;
big e,n,a,b,x,y,r;
epoint *g;
ebrick binst;
int nb,bits,window,len,bptr,m,i,j;
miracl *mip=mirsys(50,0);
n=mirvar(0);
e=mirvar(0);
a=mirvar(0);
b=mirvar(0);
x=mirvar(0);
y=mirvar(0);
r=mirvar(0);
#ifndef MR_EDWARDS
fp=fopen("common.ecs","rt");
#else
fp=fopen("edwards.ecs","rt");
#endif
fscanf(fp,"%d\n",&bits);
mip->IOBASE=16;
cinnum(n,fp);
cinnum(a,fp);
cinnum(b,fp);
cinnum(r,fp);
cinnum(x,fp);
cinnum(y,fp);
mip->IOBASE=10;
printf("modulus is %d bits in length\n",logb2(n));
printf("Enter max. size of exponent in bits = ");
scanf("%d",&nb);
getchar();
printf("Enter window size in bits (1-10)= ");
scanf("%d",&window);
getchar();
ebrick_init(&binst,x,y,a,b,n,window,nb);
/* Print out the precomputed table (for use in ecdhp.c ?)
In which case make sure that MR_SPECIAL is defined and
active in the build of this program, so MR_COMBA must
also be defined as the number of words in the modulus *
len=MR_ROUNDUP(bits,MIRACL);
bptr=0;
for (i=0;i<2*(1<<window);i++)
{
for (j=0;j<len;j++)
{
printf("0x%x,",binst.table[bptr++]);
}
printf("\n");
}
*/
printf("%d elliptic curve points have been precomputed and stored\n",(1<< window));
bigbits(nb,e); /* random exponent */
printf("naive method\n");
ecurve_init(a,b,n,MR_PROJECTIVE);
g=epoint_init();
epoint_set(x,y,0,g);
ecurve_mult(e,g,g);
epoint_get(g,x,y);
cotnum(x,stdout);
cotnum(y,stdout);
printf("Comb method\n");
mul_brick(&binst,e,x,y);
ebrick_end(&binst);
cotnum(x,stdout);
cotnum(y,stdout);
return 0;
}
void Miraclbrickend(ebrick* bg)
{
ebrick_end(bg);
}
/*
* Class: edu_biu_scapi_primitives_dlog_miracl_MiraclDlogECFp
* Method: endFpExponentiateWithPreComputedValues
* Signature: (J)V
*
* This function cleans up used resources after performing exponentiation with precomputed values for a certain base.
* It should be used if the calling application has finished working with the specified base.
*/
JNIEXPORT void JNICALL Java_edu_biu_scapi_primitives_dlog_miracl_MiraclDlogECFp_endFpExponentiateWithPreComputedValues
(JNIEnv * env, jobject, jlong base){
//Call Miracl's function that cleans up after an application of the Comb method for GF(p) elliptic curves.
ebrick_end((ebrick *)base);
}
