I'm trying to get the fft of a 2D array. The input is a NxM real matrix, therefore the output matrix is also a NxM matrix (2xNxM output matrix which is complex is saved in a NxM matrix using the property Hermitian symmetry).

So i want to know whether there is method to extract in cuda to extract real and complex matrices separately ? In opencv split function does the duty. So I'm looking for a similar function in cuda, but I couldn't find it yet.

Given below is my complete code

#define NRANK 2
#define BATCH 10

#include "cuda_runtime.h"
#include "device_launch_parameters.h"
#include <cufft.h>
#include <stdio.h> 

#include <iostream>
#include <vector>

using namespace std;

int main()

    const size_t NX = 4;
    const size_t NY = 5;

    // Input array - host side
     float b[NX][NY] ={ 
        {0.7943 ,   0.6020 ,   0.7482  ,  0.9133  ,  0.9961},
        {0.3112 ,   0.2630 ,   0.4505  ,  0.1524  ,  0.0782},
        {0.5285 ,   0.6541 ,   0.0838  ,  0.8258  ,  0.4427},
        {0.1656 ,   0.6892 ,   0.2290  ,  0.5383  ,  0.1067}

    // Output array - host side
    float c[NX][NY] = { 0 };

    cufftHandle plan;
    cufftComplex *data; // Holds both the input and the output - device side
    int n[NRANK] = {NX, NY};

    // Allocated memory and copy from host to device
    cudaMalloc((void**)&data, sizeof(cufftComplex)*NX*(NY/2+1));
    for(int i=0; i<NX; ++i){
        // Uses this because my actual array is a dynamically allocated. 
        // but here I've replaced it with a static 2D array to make it simple.
        cudaMemcpy(reinterpret_cast<float*>(data) + i*NY, b[i], sizeof(float)*NY, cudaMemcpyHostToDevice);

    // Performe the fft
    cufftPlanMany(&plan, NRANK, n,NULL, 1, 0,NULL, 1, 0,CUFFT_R2C,BATCH);
    cufftSetCompatibilityMode(plan, CUFFT_COMPATIBILITY_NATIVE);
    cufftExecR2C(plan, (cufftReal*)data, data);
    cudaMemcpy(c, data, sizeof(float)*NX*NY, cudaMemcpyDeviceToHost);

    // Here c is a NxM matrix. I want to split it to 2 seperate NxM matrices with each   
    // having the complex and real component of the output

    // Here c is in 

    return 0;


As suggested by JackOLanter, I modified the code as below. But still the problem is not solved.

 float  real_vec[NX][NY] = {0};       // host vector, real part
 float  imag_vec[NX][NY] = {0};       // host vector, imaginary part
cudaError  cudaStat1 = cudaMemcpy2D (real_vec, sizeof(real_vec[0]), data,  sizeof(data[0]),NY*sizeof(float2), NX, cudaMemcpyDeviceToHost);
cudaError  cudaStat2 = cudaMemcpy2D (imag_vec, sizeof(imag_vec[0]),data + 1,  sizeof(data[0]),NY*sizeof(float2), NX, cudaMemcpyDeviceToHost);

The error i get is 'invalid pitch argument error'. But i can't understand why. For the destination I use a pitch size of 'float' while for the source i use size of 'float2'


Your question and your code do not make much sense to me.

  1. You are performing a batched FFT, but it seems you are not foreseeing enough memory space neither for the input, nor for the output data;
  2. The output of cufftExecR2C is a NX*(NY/2+1) float2 matrix, which can be interpreted as a NX*(NY+2) float matrix. Accordingly, you are not allocating enough space for c (which is only NX*NY float) for the last cudaMemcpy. You would need still one complex memory location for the continuous component of the output;
  3. Your question does not seem to be related to the cufftExecR2C command, but is much more general: how can I split a complex NX*NY matrix into 2 NX*NY real matrices containing the real and imaginary parts, respectively.

If I correctly interpret your question, then the solution proposed by @njuffa at

Copying data to “cufftComplex” data struct?

could be a good clue to you.


In the following, a small example on how "assembling" and "disassembling" the real and imaginary parts of complex vectors when copying them from/to host to/from device. Please, add your own CUDA error checking.

#include <stdio.h>

#define N 16

int main() { 

    // Declaring, allocating and initializing a complex host vector
    float2* b = (float2*)malloc(N*sizeof(float2));
    printf("ORIGINAL DATA\n");
    for (int i=0; i<N; i++) {
        b[i].x = (float)i;
        b[i].y = 2.f*(float)i;
        printf("%f %f\n",b[i].x,b[i].y);

    // Declaring and allocating a complex device vector
    float2 *data; cudaMalloc((void**)&data, sizeof(float2)*N);

    // Copying the complex host vector to device
    cudaMemcpy(data, b, N*sizeof(float2), cudaMemcpyHostToDevice);

    // Declaring and allocating space on the host for the real and imaginary parts of the complex vector
    float* cr = (float*)malloc(N*sizeof(float));       
    float* ci = (float*)malloc(N*sizeof(float));       

    float* tmp_d = (float*)data;

    cudaMemcpy2D(cr,        sizeof(float), tmp_d,    2*sizeof(float), sizeof(float), N, cudaMemcpyDeviceToHost);
    cudaMemcpy2D(ci,        sizeof(float), tmp_d+1,  2*sizeof(float), sizeof(float), N, cudaMemcpyDeviceToHost);

    for (int i=0; i<N; i++)
        printf("cr[%i] = %f; ci[%i] = %f\n",i,cr[i],i,ci[i]);

    cudaMemcpy2D(tmp_d,     2*sizeof(float), cr, sizeof(float), sizeof(float), N, cudaMemcpyHostToDevice);
    cudaMemcpy2D(tmp_d + 1, 2*sizeof(float), ci, sizeof(float), sizeof(float), N, cudaMemcpyHostToDevice);

    // Copying the complex device vector to host
    cudaMemcpy(b, data, N*sizeof(float2), cudaMemcpyHostToDevice);
    printf("REASSEMBLED DATA\n");
    for (int i=0; i<N; i++) 
        printf("%f %f\n",b[i].x,b[i].y);


    return 0;
| improve this answer | |
  • As you suggested I tried the method suggested by the link you have given. I replaced the device to host cudamemcpy. I have entered as an EDIT to my question. But once I do it, i get 'Invalid Pitch Argument Error'..... – Optimus Dec 28 '13 at 10:23
  • Your number 1 claim : Is the input data size wrong ? Input is NX x NY float matrix. So sizeof(cufftComplex)*NX*(NY/2+1) will give sufficient memory since sizeof(cufftComplex) = 2*sizeof(float). Isn't it ? I accept that the output memory allocation is wrong. – Optimus Dec 28 '13 at 10:34
  • @Optimus I have added a small example on how "assembling" and "disassembling" complex data when copying them from/to host to/from device. I hope it will be useful to you. – JackOLantern Dec 29 '13 at 8:22
  • My question was regarding a 2D array. But still, with slide modification, this could be used for 2D arrays as well. So I marked it as the correct answer. – Optimus Dec 30 '13 at 5:32
  • 1
    @Optimus You may wish to note that a 2D array is flattened when stored to memory. So, I think you should be able to apply the same scheme in the answer above worked out for 1D arrays by considering N=NX*(NY/2+1). – JackOLantern Dec 30 '13 at 8:13

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.