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I'm trying to use texture memory to solve an interpolation problem, hopefully in a faster way than using global memory. Being the very first time for me to use texture memory, I'm oversimplifying my interpolation problem to a linear interpolation one. So, I'm already aware there are smarter and faster ways to make linear interpolation than the one reported below. Here is the file Kernels_Interpolation.cuh. The __device__ function linear_kernel_GPU is omitted for simplicity, but is correct.

texture<cuFloatComplex,1> data_d_texture;

__global__ void linear_interpolation_kernel_function_GPU_texture(cuComplex* result_d, float* x_in_d, float* x_out_d, int M, int N)
{    
   int j = threadIdx.x + blockDim.x * blockIdx.x;

   cuComplex datum;

   if(j<N)
   {
       result_d[j] = make_cuComplex(0.,0.);
       for(int k=0; k<M; k++)
       {
           datum = tex1Dfetch(data_d_texture,k);
           if (fabs(x_out_d[j]-x_in_d[k])<1.) result_d[j] = cuCaddf(result_d[j],cuCmulf(make_cuComplex(linear_kernel_GPU(x_out_d[j]-x_in_d[k]),0.),datum));
       }  
   } 
}

Here is the Kernels_Interpolation.cu function

extern "C" void linear_interpolation_function_GPU_texture(cuComplex* result_d, cuComplex* data_d, float* x_in_d, float* x_out_d, int M, int N){

   cudaBindTexture(NULL, data_d_texture, data_d, M);

   dim3 dimBlock(BLOCK_SIZE,1); dim3 dimGrid(N/BLOCK_SIZE + (N%BLOCK_SIZE == 0 ? 0:1),1);
   linear_interpolation_kernel_function_GPU_texture<<<dimGrid,dimBlock>>>(result_d, x_in_d, x_out_d, M, N);

}

Finally, in the main program, the data_d array is allocated and initialized as follows

cuComplex* data_d;      cudaMalloc((void**)&data_d,sizeof(cuComplex)*M);
cudaMemcpy(data_d,data,sizeof(cuComplex)*M,cudaMemcpyHostToDevice);

The result_d array has length N.

The strange thing is that the output is correctly computed only on the first 16 locations, although N>16, the others being 0s e.g.

result.r[0] 0.563585 result.i[0] 0.001251 
result.r[1] 0.481203 result.i[1] 0.584259
result.r[2] 0.746924 result.i[2] 0.820994
result.r[3] 0.510477 result.i[3] 0.708008
result.r[4] 0.362980 result.i[4] 0.091818
result.r[5] 0.443626 result.i[5] 0.984452
result.r[6] 0.378992 result.i[6] 0.011919
result.r[7] 0.607517 result.i[7] 0.599023
result.r[8] 0.353575 result.i[8] 0.448551
result.r[9] 0.798026 result.i[9] 0.780909
result.r[10] 0.728561 result.i[10] 0.876729
result.r[11] 0.143276 result.i[11] 0.538575
result.r[12] 0.216170 result.i[12] 0.861384
result.r[13] 0.994566 result.i[13] 0.993541
result.r[14] 0.295192 result.i[14] 0.270596
result.r[15] 0.092388 result.i[15] 0.377816
result.r[16] 0.000000 result.i[16] 0.000000
result.r[17] 0.000000 result.i[17] 0.000000
result.r[18] 0.000000 result.i[18] 0.000000
result.r[19] 0.000000 result.i[19] 0.000000

The rest of the code is correct, namely, if I replace linear_interpolation_kernel_function_GPU_texture and linear_interpolation_function_GPU_texture with functions using global memory everything is fine.

I have verified that I can correctly access texture memory until a certain location (which depends on M and N), for example 64, after which it returns 0s.

I have the same problem if I replace the cuComplex texture to a float one (forcing the data to be real).

Any ideas?

  • What is BLOCK_SIZE? What is M? What is N? It would be much simpler if you just posted code which reproduces the problem as a small, self contained example including API call error checking so others could study, compile and run it if they were so inclined. – talonmies Dec 25 '12 at 21:08
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I can see one logical error in the following line of your program.

cudaBindTexture(NULL, data_d_texture, data_d, M);

The last argument of cudaBindTexture takes the size of data in bytes and you are specifying the number of elements.

You should try the following:

cudaBindTexture(NULL, data_d_texture, data_d, M * sizeof(cuComplex));
| improve this answer | |
  • That definitely solved the problem. Many thanks. Now I could use this working simple example as a starting point for a more complex interpolation problem. – JackOLantern Dec 25 '12 at 21:25
  • 3
    As a matter of robust programming practice, I would advise never to pass NULL as the first argument of cudaBindTexture. Instead, pass a pointer to a size_t object, so the code can handle a non-zero value for the texture offset should it ever occur. Passing NULL invites silent failure down the road. – njuffa Dec 25 '12 at 22:03
  • @njuffa, the only exception I would name is if you are passing in the return value of cudaMalloc() or cudaMallocPitch(), which always should return pointers that comply with the alignment requirement for a texture's base address. – ArchaeaSoftware Dec 26 '12 at 7:55
  • The cudaMalloc() may not be in close textural proximity to the cudaBindTexture() that consumes the pointer, or the two calls may be separated in the future during a re-structuring of the source code. Then the next programmer may come along and introduce an offset for the pointer returned by cudaMalloc(), and all of a sudden the call to cudaBindTexture() could fail silently. – njuffa Dec 26 '12 at 20:42

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