I am trying to implement the dot product in CUDA and compare the result with what MATLAB returns. My CUDA code (based on this tutorial) is the following:

```
#include <stdio.h>
#define N (2048 * 8)
#define THREADS_PER_BLOCK 512
#define num_t float
// The kernel - DOT PRODUCT
__global__ void dot(num_t *a, num_t *b, num_t *c)
{
__shared__ num_t temp[THREADS_PER_BLOCK];
int index = threadIdx.x + blockIdx.x * blockDim.x;
temp[threadIdx.x] = a[index] * b[index];
__syncthreads(); //Synchronize!
*c = 0.00;
// Does it need to be tid==0 that
// undertakes this task?
if (0 == threadIdx.x) {
num_t sum = 0.00;
int i;
for (i=0; i<THREADS_PER_BLOCK; i++)
sum += temp[i];
atomicAdd(c, sum);
//WRONG: *c += sum; This read-write operation must be atomic!
}
}
// Initialize the vectors:
void init_vector(num_t *x)
{
int i;
for (i=0 ; i<N ; i++){
x[i] = 0.001 * i;
}
}
// MAIN
int main(void)
{
num_t *a, *b, *c;
num_t *dev_a, *dev_b, *dev_c;
size_t size = N * sizeof(num_t);
cudaMalloc((void**)&dev_a, size);
cudaMalloc((void**)&dev_b, size);
cudaMalloc((void**)&dev_c, size);
a = (num_t*)malloc(size);
b = (num_t*)malloc(size);
c = (num_t*)malloc(size);
init_vector(a);
init_vector(b);
cudaMemcpy(dev_a, a, size, cudaMemcpyHostToDevice);
cudaMemcpy(dev_b, b, size, cudaMemcpyHostToDevice);
dot<<<N/THREADS_PER_BLOCK, THREADS_PER_BLOCK>>>(dev_a, dev_b, dev_c);
cudaMemcpy(c, dev_c, sizeof(num_t), cudaMemcpyDeviceToHost);
printf("a = [\n");
int i;
for (i=0;i<10;i++){
printf("%g\n",a[i]);
}
printf("...\n");
for (i=N-10;i<N;i++){
printf("%g\n",a[i]);
}
printf("]\n\n");
printf("a*b = %g.\n", *c);
free(a); free(b); free(c);
cudaFree(dev_a);
cudaFree(dev_b);
cudaFree(dev_c);
}
```

and I compile it with:

```
/usr/local/cuda-5.0/bin/nvcc -m64 -I/usr/local/cuda-5.0/include -gencode arch=compute_20,code=sm_20 -o multi_dot_product.o -c multi_dot_product.cu
g++ -m64 -o multi_dot_product multi_dot_product.o -L/usr/local/cuda-5.0/lib64 -lcudart
```

Information about my NVIDIA cards can be found at http://pastebin.com/8yTzXUuK. I tried to verify the result in MATLAB using the following simple code:

```
N = 2048 * 8;
a = zeros(N,1);
for i=1:N
a(i) = 0.001*(i-1);
end
dot_product = a'*a;
```

But as N increases, I'm getting significantly different results (For instance, for N=2048*32 CUDA reutrns 6.73066e+07 while MATLAB returns 9.3823e+07. For N=2048*64 CUDA gives 3.28033e+08 while MATLAB gives 7.5059e+08). I incline to believe that the discrepancy stems from the use of `float`

in my C code, but if I replace it with `double`

the compiler complains that `atomicAdd`

does not support double parameters. How should I fix this problem?

**Update:** Also, for high values of `N`

(e.g. 2048*64), I noticed that the result returned by CUDA changes at every run. This does not happen if `N`

is low (e.g. 2048*8).

At the same time I have a more fundamental question: The variable `temp`

is an array of size `THREADS_PER_BLOCK`

and is shared between threads in the same block. Is it also shared between blocks or every block operates on a different copy of this variable? Should I think of the method `dot`

as instructions to every block? Can someone elaborate on how exactly the jobs are split and how the variables are shared in this example

`__shared__`

variable, including your`temp`

. You can do`double`

atomicAdd using the method outlined here. – Robert Crovella Apr 4 '13 at 22:10`*c = 0.00;`

unprotected by any synchronization in your kernel code is messing you up. Initialize`c`

to zero before you call your kernel, and eliminate that line from your kernel. Every thread of every block, whenever they happen to execute, is zeroing out`c`

as you have written it. – Robert Crovella Apr 4 '13 at 22:27