I am looking at the Nvidia SDK for the convolution FFT example (for large kernels), I know the theory behind fourier transforms and their FFT implementations (the basics at least), but I can't figure out what the following code does:

```
const int fftH = snapTransformSize(dataH + kernelH - 1);
const int fftW = snapTransformSize(dataW + kernelW - 1);
....//gpu initialization code
printf("...creating R2C & C2R FFT plans for %i x %i\n", fftH, fftW);
cuf ftSafeCall( cufftPlan2d(&fftPlanFwd, fftH, fftW, CUFFT_R2C) );
cufftSafeCall( cufftPlan2d(&fftPlanInv, fftH, fftW, CUFFT_C2R) );
printf("...uploading to GPU and padding convolution kernel and input data\n");
cutilSafeCall( cudaMemcpy(d_Kernel, h_Kernel, kernelH * kernelW * sizeof(float), cudaMemcpyHostToDevice) );
cutilSafeCall( cudaMemcpy(d_Data, h_Data, dataH * dataW * sizeof(float), cudaMemcpyHostToDevice) );
cutilSafeCall( cudaMemset(d_PaddedKernel, 0, fftH * fftW * sizeof(float)) );
cutilSafeCall( cudaMemset(d_PaddedData, 0, fftH * fftW * sizeof(float)) );
padKernel(
d_PaddedKernel,
d_Kernel,
fftH,
fftW,
kernelH,
kernelW,
kernelY,
kernelX
);
padDataClampToBorder(
d_PaddedData,
d_Data,
fftH,
fftW,
dataH,
dataW,
kernelH,
kernelW,
kernelY,
kernelX
);
```

I've never used CUFFT library before so I don't know what the snapTransformSize does

(here's the code)

```
int snapTransformSize(int dataSize){
int hiBit;
unsigned int lowPOT, hiPOT;
dataSize = iAlignUp(dataSize, 16);
for(hiBit = 31; hiBit >= 0; hiBit--)
if(dataSize & (1U << hiBit)) break;
lowPOT = 1U << hiBit;
if(lowPOT == dataSize)
return dataSize;
hiPOT = 1U << (hiBit + 1);
if(hiPOT <= 1024)
return hiPOT;
else
return iAlignUp(dataSize, 512);
}
```

nor why the complex plane is such initialized.

Can you provide me explanation links or answers please?