# calculation on GPU is slower than CPU for cuda

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);

for(int z=0; z<iterationMax; z++)
{
if(z%100==0)
cout <<z/100 <<"\n";;
}
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.

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I would focus on correctness before speed here: you have changed the kernel compared to the last two times we have seen this same code and now you have a big correctness problem: in-situ updating of the array A introduces a read-after-write memory race. Further, your grid size calculations appear to be totally incorrect. If I am not mistaken you are launching 40000 times too many blocks! –  talonmies Aug 17 '12 at 13:57
@talonmies, I have checked code against standard results and it is working correctly. I was updating array A in situ because I thought if extra array is used to store old values it will be slower. I am not sure about grid sizes. that seems to be error. should it be dim3 numBlocks(n_x / threadsPerBlock.x, n_y / threadsPerBlock.y);? –  chatur Aug 17 '12 at 14:15
@talonmies, calculation was slow because to many kernel calls were made than necessary(in this case 40000) as you mentioned. If you can put it as answer I can mark it as the correct one. –  chatur Aug 17 '12 at 14:28
You start your kernel `iterationMax` times. Why not start it once using a different grid structure and indexing? –  djmj Aug 20 '12 at 12:10

The worst problem I see is that you are launching far too many blocks for the size of the input array. At the moment you are computing the grid size as:

``````dim3 numBlocks(n_x*n_y / threadsPerBlock.x, n_x*n_y / threadsPerBlock.y);
``````

which should yield a grid size of (400,4000) blocks for an input array of only 200x200. That is clearly incorrect. The calculation should be something like:

``````int nbx = (n_x / threadsPerBlock.x) + (((n_x % threadsPerBlock.x) == 0) ? 0 : 1);
int nby = (n_y / threadsPerBlock.y) + (((n_y % threadsPerBlock.y) == 0) ? 0 : 1);
dim3 numBlocks(nbx,nby);
``````

which would yield a grid size of (2,20) blocks, or 40000 times fewer than you are currently launching.

There are other optimisations which you could consider making to the kernel, but those pale into insignificance compared with mistakes of this magnitude.

-

You are doing a lot of integer multiplication and have a lot of global memory reads, both of which are slow in CUDA. I also imagine that there are not a lot of coalesced global memory reads.

The only way to speed up your kernel is to stage coalesced memory reads through shared memory and/or re-arrange your data so that you can index it without using lots of integer multiplication.

I don't have a great grasp of diffusion equations, but I don't think there is a lot of naive parallelism to be exploited. Take a look at the CUDA Programming Guide and the Best Practices Guide and maybe you'll get some ideas about how to improve your algorithm.

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thanks for the reply maxywb, I don't have any idea about coalesced memory, probably I need to read about best practises –  chatur Aug 17 '12 at 14:17