# CUFFT and FFTW give different results in 2D batch mode?

When doing one FFT at a time, I find that FFTW and CUFFT give comparable numerical results. However, when I use batch mode to perform multiple FFTs, my FFTW and CUFFT results look nothing alike.

Let's do a simple example...

Setup

``````int howMany = 2;
int nRows = 4;
int nCols = 4;
int n[2] = {nRows, nCols};
float* h_in = (float*)malloc(sizeof(float) * nRows*nCols*howMany);
for(int i=0; i<(nRows*nCols*howMany); i++){ //initialize h_in to [0 1 2 3 4 ...]
h_in[i] = (float)i;
printf("h_in[%d] = %f \n", i, h_in[i]);
}
``````

FFTW Plan

``````fftwf_plan forwardPlan = fftwf_plan_many_dft_r2c(2, //rank
n, //dimensions = {nRows, nCols}
howMany, //howmany
h_in, //in
0, //inembed
howMany, //istride
1, //idist
h_freq, //out
0, //onembed
howMany, //ostride
1, //odist
FFTW_PATIENT /*flags*/);
``````

CUFFT Plan

``````CHECK_CUFFT(cufftPlanMany(&forwardPlan,
2, //rank
n, //dimensions = {nRows, nCols}
0, //inembed
howMany, //istride
1, //idist
0, //onembed
howMany, //ostride
1, //odist
CUFFT_R2C, //cufftType
howMany /*batch*/));
``````

## Results

When I use `howMany=1`, the CUFFT and FFTW results match. However, it gets more messy when I use `howMany=2`, with `istride = ostride = 2` so that two FFTs are interleaved in memory. The CUFFT results are essentially unchanged when I change `howMany` from 1 to 2, but the FFTW results change completely. My hunch is that FFTW is right and CUFFT is wrong here.

FFTW, howMany = 2

``````fftw h_freq[0][0,1] = 240.000000,0.000000
fftw h_freq[1][0,1] = 256.000000,0.000000
fftw h_freq[2][0,1] = -16.000000,16.000000
fftw h_freq[3][0,1] = -16.000000,16.000000
fftw h_freq[4][0,1] = -16.000000,0.000000
fftw h_freq[5][0,1] = -16.000000,0.000000
fftw h_freq[6][0,1] = -64.000000,64.000000
fftw h_freq[7][0,1] = -64.000000,64.000000
fftw h_freq[8][0,1] = 0.000000,0.000000
...
fftw h_freq[31][0,1] = 0.000000,0.000000
``````

CUFFT, howMany = 2

``````cufft h_freq[0].(x,y) = 120.000000,0.000001
cufft h_freq[1].(x,y) = -8.000001,7.999996
cufft h_freq[2].(x,y) = -8.000000,-0.000001
cufft h_freq[3].(x,y) = -32.000000,32.000000
cufft h_freq[4].(x,y) = 0.000000,-0.000000
cufft h_freq[5].(x,y) = -0.000001,0.000001
cufft h_freq[6].(x,y) = -32.000000,-0.000000
cufft h_freq[7].(x,y) = 0.000000,0.000000
cufft h_freq[8].(x,y) = -0.000000,0.000000
...
cufft h_freq[31].(x,y) = 0.000000,0.000000
``````

What might be causing this difference? Am I using the CUFFT batch mode correctly?

Other notes

• In the FFTW version, I initialize the the `h_in` data after setting up the FFTW plan. This way, my `h_in` data doesn't get overwritten during FFTW planning.
I don't think you're using cufft 2D batched mode correctly. I'm pretty sure 2D batched mode with interleaved data requires advanced data layout (and you seem to be thinking that way since you are specifying `istride` and `ostride`). But you have your `inembed` parameter set to NULL which turns off advanced data layout. There is an example of 2D batched mode with advanced data layout in the documentation –  Robert Crovella Jun 2 '13 at 6:52
I'm not an fftw expert (or a cufft expert) but it seems like fftw may have different behavior when you pass NULL for `inembed`. It seems that it treats that case as if you passed `n` for the `inembed` parameter. –  Robert Crovella Jun 2 '13 at 7:01
Cool! When you say we want `inembed=n`, does `n=nRows*nCols`, or `n=nRows*nCols*howMany`? –  solvingPuzzles Jun 2 '13 at 15:38
Oh, wait, perhaps I just want to use `inembed = int n[2] = {nRows, nCols}`. Probably the same thing for `onembed`, too. Right? –  solvingPuzzles Jun 2 '13 at 15:42
Yes, according to the documentation `inembed` is expecting a multi-element array, one element for each dimension in your transform (similar to the `n` parameter). –  Robert Crovella Jun 3 '13 at 1:31