Pointer Math in C
C is a very confusing language.
The world is built on C, and some people are able to get very good at it, but I am not one of those people.
I pick it up for class, learn it, use it, appreciate it, and then forget it. Why would I want to write an application in C? I’m not a systems programmer, so I don’t touch it.
One side effect of this usage pattern is that I quickly forget how pointers and manual memory management work.
Pointers are the semantics of calloc and free are easy enough to refresh on. It takes me a little while to remember if I need to use *, &, ->, or . when working with pointers. That’s not a big deal though — again, I can refresh myself on the syntax rather easily.
One thing that does trip me up (and led to a very annoying bug in a barrier algorithm) is 2D arrays, or rather representing a 2D array as a pointer.
Here’s what I did.
int x;
int y;
int *array;
array = calloc(x * y, sizeof(int))
for (int i = 0; i < x; i++) {
for (int j = 0; j < y; j++>) {
item = array[i + j];
}
}
Now, this seems somewhat reasonable at first. The problem is that there is going to be a collision. x = 0, y = 1 and x = 1, y = 0 will refer to the same slots in the array, which shouldn’t happen!
My next attempted was to change the array access to array[i * j]. This also doesn’t work. Consider when i = 0 or j = 0. Any multiplication by zero is zero, so these will all refer to the same slot.
The correct solution is rather simple. The access should be array[(i * y) + j]. Let’s prove this with an example.
With x = 2 and y = 3. These are the possible values of i and j:
i = 0, j = 0
i = 0, j = 1
i = 0, j = 2
i = 1, j = 0
i = 1, j = 1
i = 1, j = 2
Now, lets see which slot in the array each pair will fit into.
i = 0, j = 0; (0 * 3) + 0 = 0
i = 0, j = 1; (0 * 3) + 1 = 1
i = 0, j = 2; (0 * 3) + 2 = 2
i = 1, j = 0; (1 * 3) + 0 = 3
i = 1, j = 1; (1 * 3) + 1 = 4
i = 1, j = 2; (1 * 3) + 2 = 5
A unique index for each item! This is exactly what we wanted.
You should perform these accesses based on the usage patterns of your data. The example above uses the x value as the column and the y value as the row. Accesses to sequential x values will be faster than accesses to sequential y values because of locality.