# CUDA - multiple kernels to compute a single value

Hey, I'm trying to write a kernel to essentially do the following in C

float sum = 0.0;
for(int i = 0; i < N; i++){
sum += valueArray[i]*valueArray[i];
}
sum += sum / N;

At the moment I have this inside my kernel, but it is not giving correct values.

int i0 = blockIdx.x * blockDim.x + threadIdx.x;

for(int i=i0; i<N; i += blockDim.x*gridDim.x){
*d_sum += d_valueArray[i]*d_valueArray[i];
}

*d_sum= __fdividef(*d_sum, N);

The code used to call the kernel is

kernelName<<<64,128>>>(N, d_valueArray, d_sum);
cudaMemcpy(&sum, d_sum, sizeof(float) , cudaMemcpyDeviceToHost);

I think that each kernel is calculating a partial sum, but the final divide statement is not taking into account the accumulated value from each of the threads. Every kernel is producing it's own final value for d_sum?

Does anyone know how could I go about doing this in an efficient way? Maybe using shared memory between threads? I'm very new to GPU programming. Cheers

-
I'm no expert, but is the change of valueArray[i+1] to d_valueArray[i] intentional? –  George Mar 13 '11 at 23:15
Indeed, he is doing *d_sum += d_valueArray[i]*d_valueArray[i]; instead of *d_sum += d_valueArray[i] * d_valueArray[i+1]; –  karlphillip Mar 13 '11 at 23:16
Apologies, it was a typo (on here not in my program). Thanks for pointing it out –  Roger Mar 13 '11 at 23:17
What you want to do, is to calculate the scalar product of a vector. There is already an example delivered with the nvidia computing sdk –  moggi Mar 13 '11 at 23:31
Your code still isn't right. s_sum isn't defined anywhere. –  Ade Miller Mar 14 '11 at 0:04

You're updating d_sum from multiple threads.

See the following SDK sample:

Here's the code from that sample. Note how it's a two step process. Sum each thread block and then __syncthreads before attempting to accumulate the final result.

#define ACCUM_N 1024
__global__ void scalarProdGPU(
float *d_C,
float *d_A,
float *d_B,
int vectorN,
int elementN
){
//Accumulators cache
__shared__ float accumResult[ACCUM_N];

////////////////////////////////////////////////////////////////////////////
// Cycle through every pair of vectors,
// taking into account that vector counts can be different
// from total number of thread blocks
////////////////////////////////////////////////////////////////////////////
for(int vec = blockIdx.x; vec < vectorN; vec += gridDim.x){
int vectorBase = IMUL(elementN, vec);
int vectorEnd  = vectorBase + elementN;

////////////////////////////////////////////////////////////////////////
// Each accumulator cycles through vectors with
// stride equal to number of total number of accumulators ACCUM_N
// At this stage ACCUM_N is only preferred be a multiple of warp size
// to meet memory coalescing alignment constraints.
////////////////////////////////////////////////////////////////////////
for(int iAccum = threadIdx.x; iAccum < ACCUM_N; iAccum += blockDim.x){
float sum = 0;

for(int pos = vectorBase + iAccum; pos < vectorEnd; pos += ACCUM_N)
sum += d_A[pos] * d_B[pos];

accumResult[iAccum] = sum;
}

////////////////////////////////////////////////////////////////////////
// Perform tree-like reduction of accumulators' results.
// ACCUM_N has to be power of two at this stage
////////////////////////////////////////////////////////////////////////
for(int stride = ACCUM_N / 2; stride > 0; stride >>= 1){