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I am pretty new to CUDA. I need to use a thread id in a computation but it doesn't work. rem is always 0. I need the index of the thread to computes indices in arrays so I can't convert them to floats to do the computations.

the kernel is as follows :

_global__ void initializationCubes(float* dVer, float* dCub, int gridSize, float* test)
{   
    int index=blockIdx.x*blockDim.x+threadIdx.x;

    if(index<(gridSize*gridSize*gridSize))
    {

        // conversion index -> i,j,k

        int rem=index;
        int qot=(rem/gridSize);

        int i=rem-(qot*gridSize);

        rem=(rem)/(gridSize);
        qot=(rem/gridSize);

        int j=rem-(qot*gridSize);

        rem=(rem)/(gridSize);
        qot=(rem/gridSize);

        int k=rem-(qot*gridSize);

            for(int x=0;x<7;x++){

             // these first three are used to test
              dCub[index*56+0+x] =index;
              dCub[index*56+7+x] =rem;
              dCub[index*56+14+x]=k;
              dCub[index*56+21+x]=dVer[((i*(gridSize+1)+(j+1))*(gridSize+1)+k)*7+x];
              dCub[index*56+28+x]=dVer[(((i+1)*(gridSize+1)+(j))*(gridSize+1)+k)*7+x];
              dCub[index*56+35+x]=dVer[(((i+1)*(gridSize+1)+(j))*(gridSize+1)+k+1)*7+x];
              dCub[index*56+42+x]=dVer[(((i+1)*(gridSize+1)+(j+1))*(gridSize+1)+k+1)*7+x];
              dCub[index*56+49+x]=dVer[(((i+1)*(gridSize+1)+(j+1))*(gridSize+1)+k)*7+x];

             }

    }   

}


__global__ void initializationVertices(float* dVer, int gridSize){


   int currentVertex=0;

   for(int i=0; i<gridSize+1; i++)
   {
       for(int j=0; j<gridSize+1; j++)
       {
          for(int k=0; k<gridSize+1; k++)
          {

               dVer[currentVertex+0]=((i*2.0f)/(gridSize)-1.0f)*2.0f;
               dVer[currentVertex+1]=((j*2.0f)/(gridSize)-1.0f)*2.0f;
               dVer[currentVertex+2]=((k*2.0f)/(gridSize)-1.0f)*2.0f;

               currentVertex+=7;
          }
       }
 }



extern "C"
void initializationCUDA1( const int verticesAtEndsOfEdges[24], const int eTable[256], int gSize, int numberParticles ) {

 numParticles=numberParticles;

 gridSize=gSize;

 numVertices=(gridSize+1)*(gridSize+1)*(gridSize+1);
 numCubes=(gridSize)*(gridSize)*(gridSize);

 size_t pitchv=7;
 cudaMallocPitch((void**)&dVer, &pitchv, 7 * sizeof(float), (gridSize+1)*(gridSize+1)*(gridSize+1));

 size_t pitchc=7;
 cudaMallocPitch((void**)&dCub, &pitchc, 7 * sizeof(float), (gridSize)*(gridSize)*(gridSize)*8);

 cudaMalloc((void **)&verticesAtEnds, 24*sizeof(int));

 cudaMalloc((void **)&dedgeTable, 256*sizeof(int));

 cudaMalloc((void **)&dtriTable, 256*16*sizeof(int));

 cudaMalloc((void **)&ballPoint, 3*sizeof(float));

 cudaMalloc((void **)&dpositions, 3*numberParticles*sizeof(float));

 cudaMalloc((void **)&dedgeVertices, numCubes*6*12*sizeof(float));

 cudaMalloc((void **)&result, numCubes*18*sizeof(float));

 output=(float*)malloc(numCubes*18*sizeof(float));

 cudaMalloc((void **)&numFaces, 10*sizeof(int));

 cudaMalloc((void **)&test, sizeof(float));




 initializationVertices<<<1,1>>>(dVer, gridSize);

 initializationCubes<<<128,256>>>( dVer, dCub, gridSize, test);

 float* tmp =(float*)malloc(numCubes*56*(sizeof(float)));

 cudaMemcpy(tmp, dCub, numCubes*56*sizeof(float), cudaMemcpyDeviceToHost);
 for(int a=0;a<100;a++){
   printf("%f\n",tmp[a]);
 }
}

EDIT

gridSize is 40 -> the iteration of the threads go from 0 to 64000

and when I print the values outside of my function, rem, i, j and k are all equal to 0.

size_t pitchv=7; cudaMallocPitch((void**)&dVer, &pitchv, 7 * sizeof(float), (gridSize+1)(gridSize+1)(gridSize+1));

size_t pitchc=7; cudaMallocPitch((void**)&dCub, &pitchc, 7 * sizeof(float), (gridSize)(gridSize)(gridSize)*8);

initializationCubes<<<1,1>>>( dVer, dCub, gridSize, test);

share|improve this question
    
If gridSize is size of size of kernel grid you may try using predefined constant gridDim.{x,y,z}. It won't help with problem, but it might increase performance. –  Oleg Titov Dec 7 '12 at 11:51
    
gridSize has nothing to do with the cuda part. It's a parameter of my algorithm –  Devious Dec 7 '12 at 12:07
    
How do you know that rem is always 0? What are the kernel launch parameters and value of gridSize when you see the problem? –  talonmies Dec 7 '12 at 12:24
1  
You are only running your kernel with a single thread! Thus index is only ever 0, and you are only writing out the results computed with index set to 0 from that 1 thread... –  talonmies Dec 7 '12 at 13:39
1  
It's also a good idea also to do error checking on all cuda calls (cudaMalloc, cudaMemcpy, kernel calls, etc.) –  Robert Crovella Dec 7 '12 at 13:57

1 Answer 1

up vote 3 down vote accepted

If gridSize is the size of the grid, as the name suggests, both rem and qot will always be zero after execution of your code because they get divided by a value larger than themselves.

If you are looking for indices into a three-dimensional grid, that is exactly why threadIdx and blockIdx have three components. No expensive division is required at all, just use this standard code snippet:

int i = blockIdx.x * blockDim.x + threadIdx.x;
int j = blockIdx.y * blockDim.y + threadIdx.y;
int k = blockIdx.z * blockDim.z + threadIdx.z;

if (i < myBlockSize.x && j < myBlockSize.y && k<myBlockSize.z) {
    // your kernel code...
}

and launch your kernel with appropriate values for the y and z components of block- and gridsize, as well as a parameter or global variable myBlockSize set to the desired grid size (in case it cannot be factored into integer block- and grid dimensions).

share|improve this answer
    
Thanks, but that not what I need. I go through my array in a linear way and I need this to compute indices in another array. I tested my indices computation in c++ and it works perfect. It just need a valid int to begin with –  Devious Dec 7 '12 at 10:59
    
Sorry but I don't understand your question. What is wrong with the int index you already have? Please show full code. And by the way you can still do without expensive division - just calculate the linear index from the three components instead of the other way round. –  tera Dec 7 '12 at 13:26
    
That's what I was doing but it didn't work. That's my attempt at flattening the initialization of my big array to simplify it. –  Devious Dec 7 '12 at 13:40

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