I'm trying to construct a parallel algorithm with CUDA that takes an array of integers and removes all of the `0`

's with or without keeping the order.

Example:

Global Memory: {0, 0, 0, 0, 14, 0, 0, 17, 0, 0, 0, 0, 13}

Host Memory Result: {17, 13, 14, 0, 0, ...}

The simplest way is to use the host to remove the `0`

's in `O(n)`

time. But considering I have around `1000`

elements, it probably will be faster to leave everything on the GPU and condense it first, before sending it.

The preferred method would be to create an on-device stack, such that each thread can pop and push (in any order) onto or off of the stack. However, I don't think CUDA has an implementation of this.

An equivalent (but much slower) method would be to keep attempting to write, until all threads have finished writing:

```
kernalRemoveSpacing(int * array, int * outArray, int arraySize) {
if (array[threadId.x] == 0)
return;
for (int i = 0; i < arraySize; i++) {
array = arr[threadId.x];
__threadfence();
// If we were the lucky thread we won!
// kill the thread and continue re-reincarnated in a different thread
if (array[i] == arr[threadId.x])
return;
}
}
```

This method has only benefit in that we would perform in `O(f(x))`

time, where `f(x)`

is the average number of non-zero values there are in an array (`f(x) ~= ln(n)`

for my implementation, thus `O(ln(n))`

time, but has a high `O`

constant)

Finally, a sort algorithm such as quicksort or mergesort would also solve the problem, and does in fact run in `O(ln(n))`

relative time. I think there might be an algorithm faster than this even, as we do not need to waste time ordering (swapping) zero-zero element pairs, and non-zero non-zero element pairs (the order does not need to be kept).

So I'm not quite sure which method would be the fastest, and I still think there's a better way of handling this. Any suggestions?