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I am beginner to cuda and working on one hobby project. I need some help on configuring the number of threads and block to launch on kernel. i read lot of posts and articles on cuda and tried to configure my kernel ,i was able to launch kernel but always i got the garbage values after computation, i guess i am doing something wrong in configuring my kernel and device code.

The loop i am trying to execute parallaly on GPU is

for (int k=0; k<VolDepth; k++)
{
    for (int j=0; j<VolWidth; j++)
{
    for (int i=0; i<VolHeight; i++)
    { 
                 // calculations...
}}}

Host Code :

VolHeight=256
VolWidth =256 
VolDepth =132

Kernel:

splatproj<<<1,(132,256)>>>(dSPLAT_out, dSPLAT_in,....);
copy dSPLAT_out back to host and Display dSPLAT_out 

Device code:

__global__ void splatproj(float * dSPLAT_out, float * dSPLAT_in ,....)
{
int x = threadIdx.x + blockIdx.x * blockDim.x;
int y = threadIdx.y + blockIdx.y * blockDim.y;

for(int z= 0 ;z<VolHeight ; z++)
{
    int indexofvoxel = VolHeight*VolWidth*x + VolHeight*y + z; 


    if (dVOL_in[indexofvoxel] > 0)
    {

                    //current voxel coordinates
                    float updatevoxel[3];
                    updatevoxel[0] =  (z+0.5)*VolWidthScale;   
                    updatevoxel[1] =  (y+0.5)*VolHeightScale; 
                    updatevoxel[2] =  (z+0.5)*VolDepthScale; 

                    float t = ((a*(dSRCPOS_in[0]-hDCNT_in[0])+b*(dSRCPOS_in[1]-hDCNT_in[1])+c*(dSRCPOS_in[2]-hDCNT_in[2]))/(a*(dSRCPOS_in[0]-updatevoxel[0])+b*(dSRCPOS_in[1]-updatevoxel[1])+c*(dSRCPOS_in[2]-updatevoxel[2])));


                    // compute the destination coordinates

                    //Vector3f detector_coord
                    float detector_coord[2];

                    detector_coord[0] =  dSRCPOS_in[0] + (updatevoxel[0]-dSRCPOS_in[0])*t;
                    detector_coord[1] =  dSRCPOS_in[1] + (updatevoxel[1]-dSRCPOS_in[1])*t;
                    detector_coord[2] =  dSRCPOS_in[2] + (updatevoxel[2]-dSRCPOS_in[2])*t;


                    // transform the 3D coordinates into 2D image coordinates
                    // calculate i---x
                    float detector_coord_i,detector_coord_j;
                    float temp1[3];
                    float temp2[3];
                    float temp3[3];
                    float temp4[4];

                    for(int a1=0;a1<3;a1++)
                    {
                    temp1[a1]= detector_coord[a1] - dDC1_in[a1];
                    temp2[a1]= dDC2_in[a1] - dDC1_in[a1];
                    temp4[a1]= dDC3_in[a1] - dDC1_in[a1];
                    }

                    //cross product computation
                    temp3[0]=(temp1[1]*temp2[2])-(temp1[2]*temp2[1]);
                    temp3[1]=(temp1[2]*temp2[0])-(temp1[0]*temp2[2]);
                    temp3[2]=(temp1[0]*temp2[1])-(temp1[1]*temp2[0]);

                    // normalization ( detector_coord_i = ((detector_coord[1][1][1]-dDC1_in));//.cross(dDC2_in-dDC1_in)).norm()/(dDC2_in-dDC1_in).norm();)
                    float norm1 ,norm2;
                    norm1= sqrt((temp3[0]*temp3[0])+(temp3[1]*temp3[1])+(temp3[2]*temp3[2]));
                    norm2= sqrt((temp2[0]*temp2[0])+(temp2[1]*temp2[1])+(temp2[2]*temp2[2]));

                    detector_coord_i = norm1 / norm2;


                    // calculate j---y
                    //  float detector_coord_j = ((detector_coord[1][1][1]-dDC1_in));//.cross(dDC3_in-dDC1_in)).norm()/(dDC3_in-dDC1_in).norm();

                    // cross product computation
                    temp4[0]=(temp1[1]*temp4[2])-(temp1[2]*temp4[1]);
                    temp4[1]=(temp1[2]*temp4[0])-(temp1[0]*temp4[2]);
                    temp4[2]=(temp1[0]*temp4[1])-(temp1[1]*temp4[0]);

                    //normalization
                    norm1= sqrt((temp4[0]*temp4[0])+(temp4[1]*temp4[1])+(temp4[2]*temp4[2]));

                    detector_coord_j = norm1 / norm2;



                // Project to nearest four pixels
                int cx = ceil(detector_coord_i/DetectorWidthScale);
                int cy = ceil(detector_coord_j/DetectorHeightScale);
                int fx = cx-1;
                int fy = cy-1;
                    if (cx<=DetectorWidth && cx >=0 && cy <= DetectorHeight && cy >=0 && fx<=DetectorWidth && fx >=0 && fy <= DetectorHeight && fy >=0)
                    {
                        // calculate the weights of four pixels
                        float square_area = DetectorHeightScale*DetectorWidthScale;
                        float bary_1 = abs(detector_coord_i-fx*DetectorWidthScale)*abs(detector_coord_j-fy*DetectorHeightScale)/square_area;
                        float bary_2 = abs(detector_coord_i-fx*DetectorWidthScale)*abs(detector_coord_j-cy*DetectorHeightScale)/square_area;
                        float bary_3 = abs(detector_coord_i-cx*DetectorWidthScale)*abs(detector_coord_j-cy*DetectorHeightScale)/square_area;
                        float bary_4 = abs(detector_coord_i-cx*DetectorWidthScale)*abs(detector_coord_j-fy*DetectorHeightScale)/square_area;

                        int indx1 = fy*DetectorWidth+fx;
                        int indx2 = cy*DetectorWidth+fx;
                        int indx3 = cy*DetectorWidth+cx;
                        int indx4 = fy*DetectorWidth+cx;


                        // accumulate the same pixel's intensity(weights)
                        dSPLAT_out[indx1] = dSPLAT_in[indx1] + dVOL_in[indexofvoxel]*bary_3;
                        dSPLAT_out[indx2] = dSPLAT_in[indx2] + dVOL_in[indexofvoxel]*bary_4;
                        dSPLAT_out[indx3] = dSPLAT_in[indx3] + dVOL_in[indexofvoxel]*bary_1;
                        dSPLAT_out[indx4] = dSPLAT_in[indx4] + dVOL_in[indexofvoxel]*bary_2;
                    }

    }

}


}
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3  
The launch configuration is invalid. The maximum number of threads per thread block is 512 for compute capability 1.* devices and 1024 for compute capability 2.* and 3.* devices. For more information see Compute Capabilities. You have not provided sufficient details on the calculations to determine a more optimal launch configuration. In all cases you want the number of blocks to be much greater than the number of multiprocessors. –  Greg Smith Apr 14 '13 at 23:17
    
Add cuda error checking to all cuda calls and after you have fixed any errors reported (the one greg is referring to will certainly show up) run your code through cuda-memcheck. –  Robert Crovella Apr 14 '13 at 23:22
    
@GregSmith I have CC 3.0 card and i can launch 1024 threads per block, i misunderstood the concept of x ,y and z dimenision i.e. i thought i could launch 1024 *1024*64 threads in x y and z dimension per block. my bad. ,also the kernel ran and never throwed any compile time error so i thought its working as correctly. –  NxC Apr 15 '13 at 16:18
    
@GregSmith i have updated the code above ,i need to run the device code as mentioned in post 256*256*132 times . i am reading more on cuda but this simple block and thread configuration is not explained clearly anywhere when it comes to implementation of thoudands of threads –  NxC Apr 15 '13 at 16:32
    
@NeileshC why not have say, 256 blocks of 256 threads each, with each thread performing 132 calculations? Also, an invalid launch configuration is a runtime error, hence Robert's suggestion to add error checking. If you had error checking on your kernel invocation, you would of caught the error the 1st time. –  alrikai Apr 15 '13 at 18:16

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