double F4::compute(double*x){
int i;
double result = 0.0;
if(Ovector == NULL) {
Ovector = readOvector();
Pvector = readPermVector();
r25 = readR(25);
r50 = readR(50);
r100 = readR(100);
s = readS(s_size);
w = readW(s_size);
}
for(i = 0; i < dimension; i++) {
anotherz[i] = x[i] - Ovector[i];
}
// for (int i = 0; i < dimension; ++i)
// {
// cout<<anotherz[i]<<endl;
// }
// cout<<endl;
// // T_{osz}
// transform_osz(anotherz);
// s_size non-separable part with rotation
int c = 0;
for (i = 0; i < s_size; i++)
{
// cout<<"c="<<c<<", i="<<i<<endl;
anotherz1 = rotateVector(i, c);
// cout<<"done rot"<<endl;
result += w[i] * elliptic(anotherz1, s[i]);
delete []anotherz1;
// cout<<result<<endl;
}
// one separable part without rotation
double* z = new double[dimension-c];
for (i = c; i < dimension; i++)
{
// cout<<i-c<<" "<<Pvector[i]<<" "<<anotherz[Pvector[i]]<<endl;
z[i-c] = anotherz[Pvector[i]];
}
// cout<<"sep\n"<<elliptic(z, dimension-c)<<endl;
result += elliptic(z, dimension-c);
delete[] z;
// printf("Rotated Part = %1.16E\n", rot_elliptic(anotherz1,nonSeparableGroupSize) * 1e6);
// printf("Separable Part = %1.16E\n", elliptic(anotherz2,dimension - nonSeparableGroupSize));
return(result);
}
double F9::compute(vector<double> x) {
int i,k;
double result=0.0;
if(Ovector==NULL) {
Ovector=createShiftVector(dimension,minX,maxX);
Pvector=createPermVector(dimension);
RotMatrix=createRotMatrix1D(nonSeparableGroupSize);
/*
* print the multi rotated matrix
printf("\n\n\n print the multi rotated matrix\n\n\n");
for (k = 0; k<dimension/(2*nonSeparableGroupSize); k++){
printf("\n matrix %d: \n", k+1);
for (i = 0; i<nonSeparableGroupSize*nonSeparableGroupSize; i++){
printf("%1.20E\t", MultiRotMatrix1D[k][i]);
}
}
*/
}
for(i=0; i<dimension; i++) {
anotherz[i]=x[i]-Ovector[i];
}
for(k=1; k<=dimension/(2*nonSeparableGroupSize); k++) {
result+=rot_elliptic(anotherz,nonSeparableGroupSize,k);
}
// printf("Rotated Part = %1.20E\n", result);
result+=elliptic(anotherz, dimension, 2);
return(result);
}
double F8::compute(double* x){
int i;
double result=0.0;
if(Ovector == NULL) {
Ovector = readOvector();
Pvector = readPermVector();
r25 = readR(25);
r50 = readR(50);
r100 = readR(100);
s = readS(s_size);
w = readW(s_size);
}
for(i = 0; i < dimension; i++) {
anotherz[i] = x[i] - Ovector[i];
}
// s_size non-separable part with rotation
int c = 0;
for (i = 0; i < s_size; i++)
{
// cout<<"c="<<c<<", i="<<i<<endl;
anotherz1 = rotateVector(i, c);
// cout<<"done rot"<<endl;
result += w[i] * elliptic(anotherz1, s[i]);
delete []anotherz1;
// cout<<result<<endl;
}
update(result);
return(result);
}
/*
* Elliptic multiply: x := n * {x, 1}
*/
void elliptic_simple(giant x, giant n, curveParams *par) {
giant ztmp = borrowGiant(par->maxDigits);
giant cur_n = borrowGiant(par->maxDigits);
START_ELL_MEASURE(n);
int_to_giant(1, ztmp);
elliptic(x, ztmp, n, par);
binvg_cp(par, ztmp);
mulg(ztmp, x);
feemod(par, x);
END_ELL_MEASURE;
returnGiant(cur_n);
returnGiant(ztmp);
}
double F1::compute(double* x) {
double result;
int i;
if(Ovector == NULL) {
// Ovector = createShiftVector(dimension,minX,maxX);
Ovector = readOvector();
}
for(i = dimension - 1; i >= 0; i--) {
anotherz[i] = x[i] - Ovector[i];
}
// T_{OSZ}
// transform_osz(anotherz,dimension);
// result = elliptic(anotherz,dimension);
result = elliptic(anotherz,dimension);
return(result);
}
double MyHCJob24::basic_func(int func_no, double *x,int length) {
double result = 0.0;
// This part is according to Matlab reference code
switch(func_no) {
case 0:
result = weierstrass(x,length);
break;
case 1:
result = EScafferF6(x,length);
break;
case 2:
result = F8F2(x,length);
break;
case 3:
result = ackley(x,length);
break;
case 4:
result = rastrigin(x,length);
break;
case 5:
result = griewank(x,length);
break;
case 6:
result = EScafferF6NonCont(x,length);
break;
case 7:
result = rastriginNonCont(x,length);
break;
case 8:
result = elliptic(x,length);
break;
case 9:
result = sphere_noise(x,length);
break;
default:
puts("func_no is out of range.");
exit(-1);
}
return (result);
}
