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Whenever I'm plotting the values obtained by a programme using the cuFFT and comparing the results with that of Matlab, I'm getting the same shape of graphs and the values of maxima and minima are getting at the same points. However, the values resulting by the cuFFT are much greater than those resulting from Matlab. The Matlab code is

fs = 1000;                              % sample freq
D = [0:1:4]';                           % pulse delay times
t = 0 : 1/fs : 4000/fs;                 % signal evaluation time
w = 0.5;                                % width of each pulse
yp = pulstran(t,D,'rectpuls',w);
filt = conj(fliplr(yp));
xx = fft(yp,1024).*fft(filt,1024);
xx = (abs(ifft(xx)));    

and the CUDA code with the same input is like:

cufftExecC2C(plan, (cufftComplex *)d_signal, (cufftComplex *)d_signal, CUFFT_FORWARD);
cufftExecC2C(plan, (cufftComplex *)d_filter_signal, (cufftComplex *)d_filter_signal,     CUFFT_FORWARD);
ComplexPointwiseMul<<<blocksPerGrid, threadsPerBlock>>>(d_signal, d_filter_signal, NX);
cufftExecC2C(plan, (cufftComplex *)d_signal, (cufftComplex *)d_signal, CUFFT_INVERSE);

The cuFFT performs also a 1024 points FFT with batch size of 2.

With the scaling factor of NX=1024, the values are not coming correct. Please tell what to do.

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I don't think there is any easy way to handle scaling directly inside cufft. Either write your own kernel or use thrust later to scale down the signal. – Pavan Yalamanchili Jan 23 '13 at 18:43
note that in the cufft sample code a division by the number of data elements is suggested, to return the original data, after the CUFFT_INVERSE operation. – Robert Crovella May 29 '14 at 17:49

2 Answers 2

This is a late answer to remove this question from the unanswered list.

You are not giving enough information to diagnose your problem, since you are missing to specify the way you are setting up the cuFFT plan. You are even not specifying whether you have exactly the same shape for the Matlab's and cuFFT's signals (so you have just a scaling) or you have approximately the same shape. However, let me make the following two observations:

  1. The yp vector has 4000 elements; opposite to thatm by fft(yp,1024), you are performing an FFT by truncating the signal to 1024 elements;
  2. The inverse cuFFT does not perform the scaling by the number of vector elements.

For the sake of convenience (it could be useful to other users), I'm reporting below a simple FFT-IFFT scheme which includes also the scaling performed by using the CUDA Thrust library.

#include <cufft.h>
#include <thrust/host_vector.h>
#include <thrust/device_vector.h>

class Scale_by_constant
        float c_;

        Scale_by_constant(float c) { c_ = c; };

        __host__ __device__ float2 operator()(float2 &a) const
            float2 output;

            output.x = a.x / c_;
            output.y = a.y / c_;

            return output;


int main(void){

    const int N=4;

    // --- Setting up input device vector    
    thrust::device_vector<float2> d_vec(N,make_cuComplex(1.f,2.f));

    cufftHandle plan;
    cufftPlan1d(&plan, N, CUFFT_C2C, 1);

    // --- Perform in-place direct Fourier transform
    cufftExecC2C(plan, thrust::raw_pointer_cast(,thrust::raw_pointer_cast(, CUFFT_FORWARD);

    // --- Perform in-place inverse Fourier transform
    cufftExecC2C(plan, thrust::raw_pointer_cast(,thrust::raw_pointer_cast(, CUFFT_INVERSE);

    thrust::transform(d_vec.begin(), d_vec.end(), d_vec.begin(), Scale_by_constant((float)(N)));

    // --- Setting up output host vector    
    thrust::host_vector<float2> h_vec(d_vec);

    for (int i=0; i<N; i++) printf("Element #%i; Real part = %f; Imaginary part: %f\n",i,h_vec[i].x,h_vec[i].y);

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With the introduction of the cuFFT callback feature, the normalization required by the inverse FFT performed by the cuFFT can be embedded directly within the cufftExecC2C call by defining the normalization operation as a __device__ function.

Besides the cuFFT User Guide, for the cuFFT callback features, see

CUDA Pro Tip: Use cuFFT Callbacks for Custom Data Processing

Below is an example of implementing the IFFT normalization by cuFFT callback.

#include <stdio.h>
#include <assert.h>

#include "cuda_runtime.h"
#include "device_launch_parameters.h"

#include <cufft.h>
#include <cufftXt.h>

#define gpuErrchk(ans) { gpuAssert((ans), __FILE__, __LINE__); }
inline void gpuAssert(cudaError_t code, char *file, int line, bool abort=true)
    if (code != cudaSuccess)
        fprintf(stderr,"GPUassert: %s %s %d\n", cudaGetErrorString(code), file, line);
        if (abort) exit(code);

// See
#ifdef _CUFFT_H_
static const char *_cudaGetErrorEnum(cufftResult error)
    switch (error)
        case CUFFT_SUCCESS:
            return "CUFFT_SUCCESS";

        case CUFFT_INVALID_PLAN:
            return "CUFFT_INVALID_PLAN";

        case CUFFT_ALLOC_FAILED:
            return "CUFFT_ALLOC_FAILED";

        case CUFFT_INVALID_TYPE:
             return "CUFFT_INVALID_TYPE";

            return "CUFFT_INVALID_VALUE";

            return "CUFFT_INTERNAL_ERROR";

        case CUFFT_EXEC_FAILED:
            return "CUFFT_EXEC_FAILED";

        case CUFFT_SETUP_FAILED:
            return "CUFFT_SETUP_FAILED";

        case CUFFT_INVALID_SIZE:
            return "CUFFT_INVALID_SIZE";

            return "CUFFT_UNALIGNED_DATA";

    return "<unknown>";

#define cufftSafeCall(err)      __cufftSafeCall(err, __FILE__, __LINE__)
inline void __cufftSafeCall(cufftResult err, const char *file, const int line)
    if( CUFFT_SUCCESS != err) {
    fprintf(stderr, "CUFFT error in file '%s', line %d\n %s\nerror %d: %s\nterminating!\n",__FILE__, __LINE__,err, \
                            _cudaGetErrorEnum(err)); \
    cudaDeviceReset(); assert(0); \

__device__ void IFFT_Scaling(void *dataOut, size_t offset, cufftComplex element, void *callerInfo, void *sharedPtr) {

    float *scaling_factor = (float*)callerInfo;

    float2 output;
    output.x = cuCrealf(element);
    output.y = cuCimagf(element);

    output.x = output.x / scaling_factor[0];
    output.y = output.y / scaling_factor[0];

    ((float2*)dataOut)[offset] = output;


__device__ cufftCallbackStoreC d_storeCallbackPtr = IFFT_Scaling;

/* MAIN */
int main() {

    const int N = 16;

    cufftHandle plan;

    float2 *h_input             = (float2*)malloc(N*sizeof(float2));
    float2 *h_output1           = (float2*)malloc(N*sizeof(float2));
    float2 *h_output2           = (float2*)malloc(N*sizeof(float2));

    float2 *d_input;            gpuErrchk(cudaMalloc((void**)&d_input, N*sizeof(float2)));
    float2 *d_output1;          gpuErrchk(cudaMalloc((void**)&d_output1, N*sizeof(float2)));
    float2 *d_output2;          gpuErrchk(cudaMalloc((void**)&d_output2, N*sizeof(float2)));

    float *h_scaling_factor     = (float*)malloc(sizeof(float));
    h_scaling_factor[0] = 16.0f;
    float *d_scaling_factor;    gpuErrchk(cudaMalloc((void**)&d_scaling_factor, sizeof(float)));
    gpuErrchk(cudaMemcpy(d_scaling_factor, h_scaling_factor, sizeof(float), cudaMemcpyHostToDevice));

    for (int i=0; i<N; i++) {
        h_input[i].x = 1.0f;
        h_input[i].y = 0.f;

    gpuErrchk(cudaMemcpy(d_input, h_input, N*sizeof(float2), cudaMemcpyHostToDevice));

    cufftSafeCall(cufftPlan1d(&plan, N, CUFFT_C2C, 1));

    cufftSafeCall(cufftExecC2C(plan, d_input, d_output1, CUFFT_FORWARD));
    gpuErrchk(cudaMemcpy(h_output1, d_output1, N*sizeof(float2), cudaMemcpyDeviceToHost));
    for (int i=0; i<N; i++) printf("Direct transform - %d - (%f, %f)\n", i, h_output1[i].x, h_output1[i].y);

    cufftCallbackStoreC h_storeCallbackPtr;
    gpuErrchk(cudaMemcpyFromSymbol(&h_storeCallbackPtr, d_storeCallbackPtr, sizeof(h_storeCallbackPtr)));

    cufftSafeCall(cufftXtSetCallback(plan, (void **)&h_storeCallbackPtr, CUFFT_CB_ST_COMPLEX, (void **)&d_scaling_factor));

    cufftSafeCall(cufftExecC2C(plan, d_output1, d_output2, CUFFT_INVERSE));
    gpuErrchk(cudaMemcpy(h_output2, d_output2, N*sizeof(float2), cudaMemcpyDeviceToHost));
    for (int i=0; i<N; i++) printf("Inverse transform - %d - (%f, %f)\n", i, h_output2[i].x, h_output2[i].y);



    return 0;
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