# Summation over one dimension of a three dimensional array using shared memory

I need to do calculation like: A[x][y] = sum{from z=0 till z=n}{B[x][y][z]+C[x][y][z]}, where matrix A has dimensions [height][width] and matrix B,C has dimensions [height][width][n].

Values are mapped to memory with something like:

``````index = 0;
for (z = 0; z<n; ++z)
for(y = 0; y<width; ++y)
for(x = 0; x<height; ++x) {
matrix[index] = value;
index++;
}
``````

I would like to each block calculate one sum since each block has own shared memory. To avoid data racing I use atomicAdd, something like this:

Part of code in global memory:

``````dim3 block (n, 1, 1);
dim grid (height, width, 1);
``````

Kernel:

``````atomicAdd( &(A[blockIdx.x + blockIdx.y*gridDim.y]),
``````

I would like to use shared memory for calculating the sum and then copy this result to global memory.

I am not sure how to do the part with shared memory. In each block´s shared memory will be stored just one number ( sum result ). How should I copy this number to right place in A matrix in global memory?

-

You probably don't need shared memory or atomic memory access to do the summation you are asking about. If I have understood this correctly, your data is in column major order, so the logical operation is to have one thread per matrix entry in the output matrix, and have each thread traverse the z axis of the input matrices, summing as they go. The kernel for this could look something like:

``````__global__ void kernel(float *A, const float *B, const float *C,
const int width, const int height, const int n)
{
int tidx = threadIdx.x + blockDim.x * blockIdx.x;
int tidy = threadIdx.y + blockDim.y * blockIdx.y;

if ( (tidx < height) && (tidy < width) ) {
int stride = width * height;
int ipos = tidx + tidy * height;

float * oval = A + ipos;
float sum = 0.f;
for(int z=0; z<n; z++, ipos+=stride) {
sum += B[ipos] + C[ipos];
}
*oval = sum;
}
}
``````

This approach should be optimal for column-major data with `width * height >= n`. There are no performance advantages to using shared memory for this, and there is no need to use atomic memory operations either. If you had a problem where `width * height << n` it might make sense to try a block wise parallel reduction per summation. But you have not indicated what the typical dimensions of the problem are. Leave a comment if your problem is more like the latter, and I can add a reduction based sample kernel to the answer.

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but when each thread traverse the z axis of the input matrices the calculation is serialized, isn´t it? –  user1281071 Apr 1 '12 at 13:46
each thread compute value in z=0 then move to z=1 and so on. this is serialized. and for each z there has to by acces to global memory. I´d like to aviod it. –  user1281071 Apr 1 '12 at 14:06
In the kernel, there is only one global memory write per output entry in `A`. Each thread performs `n` reads from both `B` and `C`. Every entry in `B` and `C` is read exactly once. There is no more efficient way to do this operation. –  talonmies Apr 1 '12 at 14:44
if you have `512x512xn` inputs, then the code in my answer is the best way to go. if you had `8x8x10^6`, then a reduction based strategy would make sense. –  talonmies Apr 1 '12 at 16:21
`float * oval = A + ipos; ... ; *oval=sum` has the same effect as `A[ipos]=sum`, except that we don't need the initial value of ipos to do it - the code just is pre-calculating the address where the sum will need to be stored so `ipos` can be changed in the loop. –  talonmies Apr 1 '12 at 17:01