In your convolution there are two things wrong that probably *aren't* causing the crash. The first is style: You're using `x`

to iterate over the rows of an image, something I picture more as a `y`

displacement, and vice-versa. The second is that when you're computing the sum, you're not resetting the variable `sum = 0`

prior to evaluating the kernel (the inner two loops) for each pixel. Instead you accumulate `sum`

over all pixels, probably eventually causing integer overflow. While strictly speaking this is UB and could cause a crash, it's not the issue you're facing.

If you would kindly confirm that the crash occurs on the first pixel (`x = ksize/2`

, `y = ksize/2`

), then since the crash occurs at the first coefficient read from the kernel, I suspect you may have passed the "wrong thing" as the `kernel`

. As presented, the `kernel`

is an `int**`

. For a kernel size of 3x3, this means that to call this function correctly, you must have allocated on the heap or stack an array of `int*`

, where you stored 3 pointers to `int`

arrays with 3 coefficients each. If you instead passed a `int[3][3]`

array, the convolution function will attempt to interpret the first one or two `int`

in the array as a pointer to an `int`

when it is not, and try to dereference it to pull in the coefficient. This will most likely cause a segfault.

I also don't know why you are returning the accumulated sum. This isn't a "traditional" output of convolution, but I surmise you were interested in the average brightness of the output image, which is legitimate; In this case you should use a separate and wider integer accumulator (`long`

or `long long`

) and, at the end, divide it by the number of pixels in the output.

You probably found the PGM data structure from the internet, say, here. Allow me to part with this best-practice advice. In my field (computer vision), the computer vision library of choice, OpenCV, does *not* express a matrix as an array of `row`

pointers to buffers of `col`

elements. Instead, a large slab of memory is allocated, in this case of size `image->row * image->col * sizeof(int)`

at a minimum, but often `image->row * image->step * sizeof(int)`

where `image->step`

is `image->col`

rounded up to the next multiple of 4 or 16. Then, only a single pointer is kept, a pointer to the base of the entire image, although an extra field (the step) has to be kept if images aren't continuous.

I would therefore rework your code thus:

```
/* Includes */
#include <stdlib.h>
/* Defines */
#define min(a, b) (((a) < (b)) ? (a) : (b))
#define max(a, b) (((a) < (b)) ? (a) : (b))
/* Structure */
/**
* Mat structure.
*
* Stores the number of rows and columns in the matrix, the step size
* (number of elements to jump from one row to the next; must be larger than or
* equal to the number of columns), and a pointer to the first element.
*/
typedef struct Mat{
int rows;
int cols;
int step;
int* data;
} Mat;
/* Functions */
/**
* Allocation. Allocates a matrix big enough to hold rows * cols elements.
*
* If a custom step size is wanted, it can be given. Otherwise, an invalid one
* can be given (such as 0 or -1), and the step size will be chosen
* automatically.
*
* If a pointer to existing data is provided, don't bother allocating fresh
* memory. However, in that case, rows, cols and step must all be provided and
* must be correct.
*
* @param [in] rows The number of rows of the new Mat.
* @param [in] cols The number of columns of the new Mat.
* @param [in] step The step size of the new Mat. For newly-allocated
* images (existingData == NULL), can be <= 0, in
* which case a default step size is chosen; For
* pre-existing data (existingData != NULL), must be
* provided.
* @param [in] existingData A pointer to existing data. If NULL, a fresh buffer
* is allocated; Otherwise the given data is used as
* the base pointer.
* @return An allocated Mat structure.
*/
Mat allocMat(int rows, int cols, int step, int* existingData){
Mat M;
M.rows = max(rows, 0);
M.cols = max(cols, 0);
M.step = max(step, M.cols);
if(rows <= 0 || cols <= 0){
M.data = 0;
}else if(existingData == 0){
M.data = malloc(M.rows * M.step * sizeof(*M.data));
}else{
M.data = existingData;
}
return M;
}
/**
* Convolution. Convolves input by the given kernel (centered) and stores
* to output. Does not handle boundaries (i.e., in locations near the border,
* leaves output unchanged).
*
* @param [in] input The input image.
* @param [in] kern The kernel. Both width and height must be odd.
* @param [out] output The output image.
* @return Average brightness of output.
*
* Note: None of the image buffers may overlap with each other.
*/
int convolution(const Mat* input, const Mat* kern, Mat* output){
int i, j, x, y;
int coeff, data;
int sum;
int avg;
long long acc = 0;
/* Short forms of the image dimensions */
const int iw = input ->cols, ih = input ->rows, is = input ->step;
const int kw = kern ->cols, kh = kern ->rows, ks = kern ->step;
const int ow = output->cols, oh = output->rows, os = output->step;
/* Kernel half-sizes and number of elements */
const int kw2 = kw/2, kh2 = kh/2;
const int kelem = kw*kh;
/* Left, right, top and bottom limits */
const int l = kw2,
r = max(min(iw-kw2, ow-kw2), l),
t = kh2,
b = max(min(ih-kh2, oh-kh2), t);
/* Total number of pixels */
const int totalPixels = (r-l)*(b-t);
/* Input, kernel and output base pointers */
const int* iPtr = input ->data;
const int* kPtr = kern ->data + kw2 + ks*kh2;
int* oPtr = output->data;
/* Iterate over pixels of image */
for(y=t; y<b; y++){
for(x=l; x<r; x++){
sum = 0;
/* Iterate over elements of kernel */
for(i=-kh2; i<=kh2; i++){
for(j=-kw2; j<=kw2; j++){
data = iPtr[j + is*i + x];
coeff = kPtr[j + ks*i ];
sum += data * coeff;
}
}
/* Compute average. Add to accumulator and store as output. */
avg = sum / kelem;
acc += avg;
oPtr[x] = avg;
}
/* Bump pointers by one row step. */
iPtr += is;
oPtr += os;
}
/* Compute average brightness over entire output */
if(totalPixels == 0){
avg = 0;
}else{
avg = acc/totalPixels;
}
/* Return average brightness */
return avg;
}
/**
* Main
*/
int main(int argc, char* argv[]){
/**
* Coefficients of K. Binomial 3x3, separable. Unnormalized (weight = 16).
* Step = 3.
*/
int Kcoeff[3][3] = {{1, 2, 1}, {2, 4, 2}, {1, 2, 1}};
Mat I = allocMat(1920, 1080, 0, 0);/* FullHD 1080p: 1920x1080 */
Mat O = allocMat(1920, 1080, 0, 0);/* FullHD 1080p: 1920x1080 */
Mat K = allocMat( 3, 3, 3, &Kcoeff[0][0]);
/* Fill Mat I with something.... */
/* Convolve with K... */
int avg = convolution(&I, &K, &O);
/* Do something with O... */
/* Return */
return 0;
}
```

Reference: Years of experience in computer vision.