# Issues with getting an index of an array [C]

I'm writing a program that sends an array through a function (upperhess) that will turn it from a square nxn matrix into an upper hessenberg matrix. This is running fine, but then i need to send the array through another function, which I am having an issue with. I need to make a double equal to the first element of the array. However, instead it is setting the double (mu) equal to zero. I included my code below

``````#include <stdio.h>
#include <math.h>

int idx(int r, int c, int n)
{
return r * n + c;
}

void transpose(double *a, int n, double *at)
{
for (int i = 0; i < n; i++) {
for (int j = 0; j < n; j++) {
at[(idx (i, j, n))] = a[(idx (j, i, n))];
}
}
}

void matrix_multiplication(double *a, double *b, int n, double *combo)
{

for (int i = 0; i < n; i++) {
for (int j = 0; j < n; j++) {
combo[(idx(i, j, n))] = 0;
for (int k = 0; k < n; k++) {
combo[(idx(i, j, n))] +=  a[(idx(i, k, n))] * b[(idx(k, j, n))];
}
}
}

}

void identity(double *a, int n)
{
for (int i = 0; i < n; i++) {
for (int j = 0; j < n; j++) {
if (i == j) {
a[(idx(i, j, n))] = 1;
}
else {
a[(idx(i, j, n))] = 0;
}
}
}
}

void upperhes(double *a, int n, double *u, double *b)
{

//Sets b equal to a
for (int i = 0; i < (n*n); i++) {
b[i] = a[i];
}

//Sets u equal to the identity matrix
identity(u, n);

int times = 0;
for (int i = 0; i < (n-2); i++) {
for (int j = n-1; j > (1 + times); j--) {
double c, s, r;

r = sqrt((b[(idx(j-1,i,n))] * b[(idx(j-1,i,n))]) + (b[(idx(j,i,n))] * b[(idx(j,i,n))]));
if (r < 0) {
r = (-1 * r);
}
if (r < pow(10,-50)) {
c = 1;
s = 0;
}
else {
c = b[(idx(j-1, i, n))] / r;
s = (-1 * b[(idx(j, i, n))]) / r;
}

//store takes the original values of specific points in matrix b and stores them, so the values of b can be manipulated
double store[6];

store[0] = b[(idx(j-1, i,n))];
store[1] = b[(idx(j,i,n))];
store[4] = b[(idx(i,j-1,n))];
store[5] = b[(idx(i,j,n))];

b[(idx (j,i,n))] = (s * store[0]) + (c * store[1]);
b[(idx(j-1,i,n))] = (c * store[0]) + (-s * store[1]);

for (int k= i+1; k<n; k++) {

store[2] = b[(idx(j-1,k,n))];
store[3] = b[(idx(j,k,n))];

b[(idx(j-1,k,n))] = (c * store[2]) - (s * store[3]);
b[(idx(j,k,n))] = (s * store[2]) + (c * store[3]);
}

b[(idx (i, j, n))] = (s * store[4]) + (c * store[5]);
b[(idx (i, j-1, n))] = (c * store[4]) - (s * store[5]);

for (int k = i + 1; k < n; k++) {

store[2] = b[(idx(k, j-1, n))];
store[3] = b[(idx(k, j, n))];

b[idx(k, j-1, n)] = (c * store[2]) - (s * store[3]);
b[idx(k, j, n)] = (s * store[2]) + (c * store[3]);
}

store[0] = u[(idx(j-1, 0, n))];
store[1] = u[(idx(j, 0, n))];

u[idx (j, 0, n)] = (s * store[0]) + (c * store[1]);
u[idx(j-1, 0, n)] = (c * store[0]) + (-s * store[1]);

for (int k= 1; k<n; k++) {

store[2] = u[idx(j-1, k, n)];
store[3] = u[idx(j, k, n)];

u[idx(j-1, k, n)] = (c * store[2]) - (s * store[3]);
u[idx(j, k, n)] = (s * store[2]) + (c * store[3]);
}
}

times++;

}

//Sets ut equal to the transpose of u
double ut[n*n];
transpose(u, n, ut);

//Multiplies u and a together.
double ua[(n*n)];
matrix_multiplication(u, a, n, ua);

double b_check[(n*n)];
matrix_multiplication(ua, ut, n, b_check);

//Prints out the matrix!
for(int i=0; i<n; i++){
for(int j =0; j<n; j++){
printf("(%+.3f)\t", b[(idx (i,j,n))]);
}
printf("\n\n");
}
printf("\n");

}

void two_through_five(double *b, int n, double *eigenvalues, int total)
{

for (int times = 0; times < 100; times++){

double mu = b[0];

..........
}
}

void qr_symmetric(double *a, int n, double *b)
{

//Creates a tridiagonal matrix by using a method that creates upper Hessenberg matrices on a symmetrical matrix a.
double u[n * n];
upperhes(a, n, u, b);

//Creates an array to store the eigenvalues
double eigenvalues[n];

two_through_five(b, n, eigenvalues, n);
for (int i = 0; i < n; i++) {
printf("%d\t", eigenvalues[n]);
}
printf("\n");

}

int main(void)
{
int n;
n = 4;
double a[(n*n)];
a[0] = 1;
a[1] = 2;
a[2] = 3;
a[3] = 4;
a[4] = 2;
a[5] = 6;
a[6] = 7;
a[7] = 8;
a[8] = 3;
a[9] = 7;
a[10] = 11;
a[11] = 15;
a[12] = 4;
a[13] = 8;
a[14] = 15;
a[15] = 16;
double b[n * n];
qr_symmetric(a, n, b);
return 0;
}
``````
-
The code you have posted is not the cause of why you are getting zero in mu. Chances are it's something in your upperhes() function, but you need to post a short, compilable, complete example of the problem you are having. – tinman Mar 29 '12 at 21:20
@tinman I posted the rest of my code so my problem might make more sense. upperhess has some bugs, but seems to work fine with a symmetric matrix, which I'm assured my input will be. – GoodLuckGanesh Mar 29 '12 at 21:29

Your code shoud work. For instance, this works for me:

``````void two_through_five(double *b, int n, double *eigenvalues, int total)
{
int times;
for (times = 0; times < 100; times++)
{
double mu = b[0];
printf("%f\n", mu);
}
}

int main()
{

int n = 18;
int i =0;

double * b = malloc(n*sizeof(double));

for( i=0; i<n;i++) b[i] = 15.0;

double eigenvalues[n];

two_through_five(b, n, eigenvalues, n);

return 0;
}
``````

Outupts:

``````15.000000
15.000000
15.000000
15.000000
15.000000
15.000000
15.000000
15.000000
15.000000
...
``````

So my quedtion is, are you sure b[0] is not 0?

-
I posted the rest of my code. When I run it this way, b[0] should equal 1.000. – GoodLuckGanesh Mar 29 '12 at 21:27
try to print the value of b[0] just before you call two_through_five() and then printf("%f\n", mu); inside two_through_five. Maybe there is somethink that changes it's value. Because if my piece of code works then yours should too. Keep us posted! – nay Mar 29 '12 at 21:29
I just realized my problem. Whenever I've been printing out things to test it, I've been using printf("%d" , b[0]) or printf("%d", mu), which wouldn't work. It definitely does work! Thanks! – GoodLuckGanesh Mar 29 '12 at 21:34