I have already checked earlier questions on SO about this issue but not able to see how it relates here.

I am solving 2d diffusion equation with CUDA and it turns out that code is slower than a simple CPU only code for same purpose.

here is my code

```
//kernel definition
__global__ void diffusionSolver(double* A, int n_x,int n_y)
{
int i = blockIdx.x * blockDim.x + threadIdx.x;
int j = blockIdx.y * blockDim.y + threadIdx.y;
if(i<n_x && j <n_y && i*(n_x-i-1)*j*(n_y-j-1)!=0)
A[i+n_y*j] = A[i+n_y*j] + (A[i-1+n_y*j]+A[i+1+n_y*j]+A[i+(j-1)*n_y]+A[i+(j+1)*n_y] -4.0*A[i+n_y*j])/40.0;
}
```

int main function

```
int main()
{
int n_x = 200 ;
int n_y = 200 ;
double *phi;
double *dummy;
double *phi_old;
int i,j ;
phi = (double *) malloc( n_x*n_y* sizeof(double));
phi_old = (double *) malloc( n_x*n_y* sizeof(double));
dummy = (double *) malloc( n_x*n_y* sizeof(double));
int iterationMax =200;
for(j=0;j<n_y ;j++)
{
for(i=0;i<n_x;i++)
{
if((.4*n_x-i)*(.6*n_x-i)<0)
phi[i+n_y*j] = -1;
else
phi[i+n_y*j] = 1;
}
}
double *dev_phi;
cudaMalloc((void **) &dev_phi, n_x*n_y*sizeof(double));
cudaMemcpy(dev_phi, phi, n_x*n_y*sizeof(double),
cudaMemcpyHostToDevice);
dim3 threadsPerBlock(10,100);
dim3 numBlocks(n_x*n_y / threadsPerBlock.x, n_x*n_y / threadsPerBlock.y);
for(int z=0; z<iterationMax; z++)
{
if(z%100==0)
cout <<z/100 <<"\n";;
diffusionSolver<<<numBlocks, threadsPerBlock>>>(dev_phi, n_x,n_y);
}
cudaMemcpy(phi, dev_phi,n_x*n_y*sizeof(double), cudaMemcpyDeviceToHost);
cudaFree(dev_phi);
return 0;
}
```

Problem with this code is it runs slower than simple CPU only iterative method. I don't know much about profiler and until now I tried with `cuda-memcheck`

which gives 0 errors.
How can I know which portion of code is performing slowly and speed up that? I am working on Linux environment. Thanks in advance for any help.

`iterationMax`

times. Why not start it once using a different grid structure and indexing? – djmj Aug 20 '12 at 12:10