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Hi I have a simple Calculation Using Texture Memory. But i am not able to save the right results. The result should be a interpolation. For example angle = 0.5 A[0] = 1, B[0] = 2, result[0] should be 1.5

I guess i am not saving the Data right. I want to use texture memory for fast calculations and save the result in a global Array. There is something i am doing wrong. Does anyone have an Idea what?

Here is my code inside the Kernel


texture<float, 1> tex1;
texture<float, 1> tex2;

__global__ void
transformKernel( float* g_odata, float f) 
    // calculate normalized texture coordinates
    unsigned int x = blockIdx.x*blockDim.x + threadIdx.x;
    int idx = threadIdx.x;

    float valA = tex1D(tex1,x);
    float valB = tex1D(tex2,x);

    // read from texture and write to global memory
    g_odata[x] = (f)*valA + (1-f)*valB;

Here the code i call

#include <stdio.h>
#include <iostream>
#include "cuda.h"
#include <stdlib.h>
#include "cuda_runtime.h"
#include "device_launch_parameters.h"
#include "HelloWorld.h"

#include "linearInterpolation_kernel.cu"

using namespace std;
using std::cout;

const int blocksize = 16; 
int main()
    int N = 1000; 
    float *A; 
    A = (float *) malloc(N*sizeof(float));
    float *B;
    B = (float *) malloc(N*sizeof(float));
    float *result;
    result = (float *) malloc(N*sizeof(float));
    float angle = 0.5f; 

    for(int i = 0; i < N; i++){
        A[i] = (float)rand();
        B[i] = (float)rand();
    cout << A[3] << endl;
    cout << B[3] << endl;


    float result2;

    result2 = (angle)*A[3] + (1-angle)*B[3]; 

    printf(" A %f B %f Result %f\n", A[3], B[3], result[3]);
    cout << result2 << endl;

    return 1;
void ipLinearTexture(float *A, float* B, float* result, float angle, int N)
    float cuTime;

    const cudaChannelFormatDesc channel_desc = cudaCreateChannelDesc<float>(); 
    cudaArray* cuda_A;
    cudaArray* cuda_B;
    float *dev_result;

    cudaMallocArray(&cuda_A, &channel_desc, 1, N * sizeof(float));
    cudaMallocArray(&cuda_B, &channel_desc, 1, N * sizeof(float));
    cudaMalloc(&dev_result, N * sizeof(float));

    cudaMemcpyToArray(cuda_A,0,0,A,N * sizeof(float),cudaMemcpyHostToDevice);
    cudaMemcpyToArray(cuda_B,0,0,B,N * sizeof(float),cudaMemcpyHostToDevice);

    tex1.filterMode = cudaFilterModePoint;
    tex1.addressMode[0] = cudaAddressModeWrap;

    tex2.filterMode = cudaFilterModePoint;
    tex2.addressMode[0] = cudaAddressModeWrap;

    cudaBindTextureToArray(tex1, cuda_A, channel_desc);
    cudaBindTextureToArray(tex2, cuda_B, channel_desc);

    cudaEvent_t start, stop;

    transformKernel<<< 16, 16, 0 >>>(dev_result,angle);

    cudaEventElapsedTime(&cuTime, start,stop);

    cudaMemcpy(result, dev_result, N * sizeof(float), cudaMemcpyKind::cudaMemcpyDeviceToHost);
    result[0] = (float)cuTime;


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Can you edit your question to explain what the "wrong results" and "right results" are/should be? –  talonmies Aug 27 '12 at 14:32
I don't see the code you are using to verify that the results are correct or not. I find it strange that you are overwriting result[0] with the measured time: result[0] = (float)cuTime;. To be honest, for this linear addressing pattern, using textures will not provide a performance advantage, and the code is more complex than just using regular device pointers. –  harrism Aug 29 '12 at 3:45

1 Answer 1

From the examples in the programming guide and the docs in this page, it seems that the declaration of the cudaMallocArray function is:

cudaError_t cudaMallocArray(struct cudaArray **array, 
                const struct cudaChannelFormatDesc *desc, 
                size_t width, 
                size_t height = 0, 
                unsigned int flags = 0)

In the code you posted, you pass the size in bytes. Try with N only, remove the sizeof(float)

At least last time I used a texture for linear interpolation, when I allocate the cudaArray I did not specifythe size in bytes and it works. Mind you that when you call cudaMemcpyToArray the size should be in bytes.

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