```
Windows 7, NVidia GeForce 425M.
```

I wrote a simple CUDA code which calculates the row sums of a matrix. The matrix has uni-dimensional representation (pointer to a float).

The serial version of code is below (it has 2 loops, as expected):

```
void serial_rowSum (float* m, float* output, int nrow, int ncol) {
float sum;
for (int i = 0 ; i < nrow ; i++) {
sum = 0;
for (int j = 0 ; j < ncol ; j++)
sum += m[i*ncol+j];
output[i] = sum;
}
}
```

Inside CUDA code I call the kernel function sweeping the matrix by row. Below, the kernel call snippet:

```
dim3 threadsPerBlock((unsigned int) nThreadsPerBlock); // has to be multiple of 32
dim3 blocksPerGrid((unsigned int) ceil(nrow/(float) nThreadsPerBlock));
kernel_rowSum<<<blocksPerGrid, threadsPerBlock>>>(d_m, d_output, nrow, ncol);
```

and the kernel function which performs the parallel sum of rows (still has 1 loop):

```
__global__ void kernel_rowSum(float *m, float *s, int nrow, int ncol) {
int rowIdx = threadIdx.x + blockIdx.x * blockDim.x;
if (rowIdx < nrow) {
float sum=0;
for (int k = 0 ; k < ncol ; k++)
sum+=m[rowIdx*ncol+k];
s[rowIdx] = sum;
}
}
```

So far so good. The serial and parallel (CUDA) results are equal.

The whole point is that the CUDA version takes almost double the time of serial one to compute. Even if I change the `nThreadsPerBlock`

parameter.

I tested from 32 to 1024 (maximum number of treads per block allowed for my card).
IMO, the matrix dimension is big enough to justify parallelization: `90,000 x 1,000`

Below, I report the time elapsed for serial and parallel version using different `nThreadsPerBlock`

. Time reported in msec, average of 100 samples:

Matrix: nrow = 90000 x ncol = 1000 Serial: Average Time Elapsed per Sample in msec (100 samples): 289.18 CUDA (32 ThreadsPerBlock): Average Time Elapsed per Sample in msec (100 samples): 497.11 CUDA (1024 ThreadsPerBlock): Average Time Elapsed per Sample in msec (100 samples): 699.66

Just in case, the version with 32/1024 `nThreadsPerBlock`

is the fastest/slowest one.

I understand that there is a kind of overhead when copying from Host to Device and the other way around, but maybe the slowness is because I am not implementing the fastest code.

Since I am far from being a CUDA expert:

**Am I coding a fastest version of this task?
How could I improve my code?
Can I get rid of the loop in the kernel function?**

Any thoughts appreciated.

**EDIT 1**

Although I describe a standard `rowSum`

, I am interested in the `AND`

/`OR`

operation of rows which have (0;1} values, like `rowAND`

/`rowOR`

. That said, it doesn't allow me to implement `cuBLAS`

multiply by 1's COL matrix trick, as suggested by some commentators.

**EDIT 2**

As suggest by users other users and here endorsed:

**FORGET ABOUT TRYING TO WRITE YOUR OWN FUNCTIONS**, use Thrust library instead and the magic comes.