/*
-----------------------------------------------------------------------
Copyright: 2010-2015, iMinds-Vision Lab, University of Antwerp
2014-2015, CWI, Amsterdam
Contact: astra@uantwerpen.be
Website: http://sf.net/projects/astra-toolbox
This file is part of the ASTRA Toolbox.
The ASTRA Toolbox is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
The ASTRA Toolbox is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with the ASTRA Toolbox. If not, see .
-----------------------------------------------------------------------
$Id$
*/
#include "fft.h"
#include "util.h"
#include
#include
#include
#include
#include "../../include/astra/Logging.h"
#include "astra/Fourier.h"
using namespace astra;
// TODO: evaluate what we want to do in these situations:
#define CHECK_ERROR(errorMessage) do { \
cudaError_t err = cudaThreadSynchronize(); \
if( cudaSuccess != err) { \
ASTRA_ERROR("Cuda error %s : %s", \
errorMessage,cudaGetErrorString( err)); \
exit(EXIT_FAILURE); \
} } while (0)
#define SAFE_CALL( call) do { \
cudaError err = call; \
if( cudaSuccess != err) { \
ASTRA_ERROR("Cuda error: %s ", \
cudaGetErrorString( err)); \
exit(EXIT_FAILURE); \
} \
err = cudaThreadSynchronize(); \
if( cudaSuccess != err) { \
ASTRA_ERROR("Cuda error: %s : ", \
cudaGetErrorString( err)); \
exit(EXIT_FAILURE); \
} } while (0)
__global__ static void applyFilter_kernel(int _iProjectionCount,
int _iFreqBinCount,
cufftComplex * _pSinogram,
cufftComplex * _pFilter)
{
int iIndex = threadIdx.x + blockIdx.x * blockDim.x;
int iProjectionIndex = iIndex / _iFreqBinCount;
if(iProjectionIndex >= _iProjectionCount)
{
return;
}
float fA = _pSinogram[iIndex].x;
float fB = _pSinogram[iIndex].y;
float fC = _pFilter[iIndex].x;
float fD = _pFilter[iIndex].y;
_pSinogram[iIndex].x = fA * fC - fB * fD;
_pSinogram[iIndex].y = fA * fD + fC * fB;
}
__global__ static void rescaleInverseFourier_kernel(int _iProjectionCount,
int _iDetectorCount,
float* _pfInFourierOutput)
{
int iIndex = threadIdx.x + blockIdx.x * blockDim.x;
int iProjectionIndex = iIndex / _iDetectorCount;
int iDetectorIndex = iIndex % _iDetectorCount;
if(iProjectionIndex >= _iProjectionCount)
{
return;
}
_pfInFourierOutput[iProjectionIndex * _iDetectorCount + iDetectorIndex] /= (float)_iDetectorCount;
}
static void rescaleInverseFourier(int _iProjectionCount, int _iDetectorCount,
float * _pfInFourierOutput)
{
const int iBlockSize = 256;
int iElementCount = _iProjectionCount * _iDetectorCount;
int iBlockCount = (iElementCount + iBlockSize - 1) / iBlockSize;
rescaleInverseFourier_kernel<<< iBlockCount, iBlockSize >>>(_iProjectionCount,
_iDetectorCount,
_pfInFourierOutput);
CHECK_ERROR("rescaleInverseFourier_kernel failed");
}
void applyFilter(int _iProjectionCount, int _iFreqBinCount,
cufftComplex * _pSinogram, cufftComplex * _pFilter)
{
const int iBlockSize = 256;
int iElementCount = _iProjectionCount * _iFreqBinCount;
int iBlockCount = (iElementCount + iBlockSize - 1) / iBlockSize;
applyFilter_kernel<<< iBlockCount, iBlockSize >>>(_iProjectionCount,
_iFreqBinCount,
_pSinogram, _pFilter);
CHECK_ERROR("applyFilter_kernel failed");
}
static bool invokeCudaFFT(int _iProjectionCount, int _iDetectorCount,
const float * _pfDevSource,
cufftComplex * _pDevTargetComplex)
{
cufftHandle plan;
cufftResult result;
result = cufftPlan1d(&plan, _iDetectorCount, CUFFT_R2C, _iProjectionCount);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to plan 1d r2c fft");
return false;
}
result = cufftExecR2C(plan, (cufftReal *)_pfDevSource, _pDevTargetComplex);
cufftDestroy(plan);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to exec 1d r2c fft");
return false;
}
return true;
}
static bool invokeCudaIFFT(int _iProjectionCount, int _iDetectorCount,
const cufftComplex * _pDevSourceComplex,
float * _pfDevTarget)
{
cufftHandle plan;
cufftResult result;
result = cufftPlan1d(&plan, _iDetectorCount, CUFFT_C2R, _iProjectionCount);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to plan 1d c2r fft");
return false;
}
// todo: why do we have to get rid of the const qualifier?
result = cufftExecC2R(plan, (cufftComplex *)_pDevSourceComplex,
(cufftReal *)_pfDevTarget);
cufftDestroy(plan);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to exec 1d c2r fft");
return false;
}
return true;
}
bool allocateComplexOnDevice(int _iProjectionCount, int _iDetectorCount,
cufftComplex ** _ppDevComplex)
{
size_t bufferSize = sizeof(cufftComplex) * _iProjectionCount * _iDetectorCount;
SAFE_CALL(cudaMalloc((void **)_ppDevComplex, bufferSize));
return true;
}
bool freeComplexOnDevice(cufftComplex * _pDevComplex)
{
SAFE_CALL(cudaFree(_pDevComplex));
return true;
}
bool uploadComplexArrayToDevice(int _iProjectionCount, int _iDetectorCount,
cufftComplex * _pHostComplexSource,
cufftComplex * _pDevComplexTarget)
{
size_t memSize = sizeof(cufftComplex) * _iProjectionCount * _iDetectorCount;
SAFE_CALL(cudaMemcpy(_pDevComplexTarget, _pHostComplexSource, memSize, cudaMemcpyHostToDevice));
return true;
}
bool runCudaFFT(int _iProjectionCount, const float * _pfDevRealSource,
int _iSourcePitch, int _iProjDets,
int _iFFTRealDetectorCount, int _iFFTFourierDetectorCount,
cufftComplex * _pDevTargetComplex)
{
float * pfDevRealFFTSource = NULL;
size_t bufferMemSize = sizeof(float) * _iProjectionCount * _iFFTRealDetectorCount;
SAFE_CALL(cudaMalloc((void **)&pfDevRealFFTSource, bufferMemSize));
SAFE_CALL(cudaMemset(pfDevRealFFTSource, 0, bufferMemSize));
for(int iProjectionIndex = 0; iProjectionIndex < _iProjectionCount; iProjectionIndex++)
{
const float * pfSourceLocation = _pfDevRealSource + iProjectionIndex * _iSourcePitch;
float * pfTargetLocation = pfDevRealFFTSource + iProjectionIndex * _iFFTRealDetectorCount;
SAFE_CALL(cudaMemcpy(pfTargetLocation, pfSourceLocation, sizeof(float) * _iProjDets, cudaMemcpyDeviceToDevice));
}
bool bResult = invokeCudaFFT(_iProjectionCount, _iFFTRealDetectorCount,
pfDevRealFFTSource, _pDevTargetComplex);
if(!bResult)
{
return false;
}
SAFE_CALL(cudaFree(pfDevRealFFTSource));
return true;
}
bool runCudaIFFT(int _iProjectionCount, const cufftComplex* _pDevSourceComplex,
float * _pfRealTarget,
int _iTargetPitch, int _iProjDets,
int _iFFTRealDetectorCount, int _iFFTFourierDetectorCount)
{
float * pfDevRealFFTTarget = NULL;
size_t bufferMemSize = sizeof(float) * _iProjectionCount * _iFFTRealDetectorCount;
SAFE_CALL(cudaMalloc((void **)&pfDevRealFFTTarget, bufferMemSize));
bool bResult = invokeCudaIFFT(_iProjectionCount, _iFFTRealDetectorCount,
_pDevSourceComplex, pfDevRealFFTTarget);
if(!bResult)
{
return false;
}
rescaleInverseFourier(_iProjectionCount, _iFFTRealDetectorCount,
pfDevRealFFTTarget);
SAFE_CALL(cudaMemset(_pfRealTarget, 0, sizeof(float) * _iProjectionCount * _iTargetPitch));
for(int iProjectionIndex = 0; iProjectionIndex < _iProjectionCount; iProjectionIndex++)
{
const float * pfSourceLocation = pfDevRealFFTTarget + iProjectionIndex * _iFFTRealDetectorCount;
float* pfTargetLocation = _pfRealTarget + iProjectionIndex * _iTargetPitch;
SAFE_CALL(cudaMemcpy(pfTargetLocation, pfSourceLocation, sizeof(float) * _iProjDets, cudaMemcpyDeviceToDevice));
}
SAFE_CALL(cudaFree(pfDevRealFFTTarget));
return true;
}
// Because the input is real, the Fourier transform is symmetric.
// CUFFT only outputs the first half (ignoring the redundant second half),
// and expects the same as input for the IFFT.
int calcFFTFourSize(int _iFFTRealSize)
{
int iFFTFourSize = _iFFTRealSize / 2 + 1;
return iFFTFourSize;
}
void genIdenFilter(int _iProjectionCount, cufftComplex * _pFilter,
int _iFFTRealDetectorCount, int _iFFTFourierDetectorCount)
{
for(int iProjectionIndex = 0; iProjectionIndex < _iProjectionCount; iProjectionIndex++)
{
for(int iDetectorIndex = 0; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
int iIndex = iDetectorIndex + iProjectionIndex * _iFFTFourierDetectorCount;
_pFilter[iIndex].x = 1.0f;
_pFilter[iIndex].y = 0.0f;
}
}
}
void genFilter(E_FBPFILTER _eFilter, float _fD, int _iProjectionCount,
cufftComplex * _pFilter, int _iFFTRealDetectorCount,
int _iFFTFourierDetectorCount, float _fParameter /* = -1.0f */)
{
float * pfFilt = new float[_iFFTFourierDetectorCount];
float * pfW = new float[_iFFTFourierDetectorCount];
// We cache one Fourier transform for repeated FBP's of the same size
static float *pfData = 0;
static int iFilterCacheSize = 0;
if (!pfData || iFilterCacheSize != _iFFTRealDetectorCount) {
// Compute filter in spatial domain
delete[] pfData;
pfData = new float[2*_iFFTRealDetectorCount];
int *ip = new int[int(2+sqrt(_iFFTRealDetectorCount)+1)];
ip[0] = 0;
float32 *w = new float32[_iFFTRealDetectorCount/2];
for (int i = 0; i < _iFFTRealDetectorCount; ++i) {
pfData[2*i+1] = 0.0f;
if (i & 1) {
int j = i;
if (2*j > _iFFTRealDetectorCount)
j = _iFFTRealDetectorCount - j;
float f = M_PI * j;
pfData[2*i] = -1 / (f*f);
} else {
pfData[2*i] = 0.0f;
}
}
pfData[0] = 0.25f;
cdft(2*_iFFTRealDetectorCount, -1, pfData, ip, w);
delete[] ip;
delete[] w;
iFilterCacheSize = _iFFTRealDetectorCount;
}
for(int iDetectorIndex = 0; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fRelIndex = (float)iDetectorIndex / (float)_iFFTRealDetectorCount;
pfFilt[iDetectorIndex] = 2.0f * pfData[2*iDetectorIndex];
pfW[iDetectorIndex] = M_PI * 2.0f * fRelIndex;
}
switch(_eFilter)
{
case FILTER_RAMLAK:
{
// do nothing
break;
}
case FILTER_SHEPPLOGAN:
{
// filt(2:end) = filt(2:end) .* (sin(w(2:end)/(2*d))./(w(2:end)/(2*d)))
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
pfFilt[iDetectorIndex] = pfFilt[iDetectorIndex] * (sinf(pfW[iDetectorIndex] / 2.0f / _fD) / (pfW[iDetectorIndex] / 2.0f / _fD));
}
break;
}
case FILTER_COSINE:
{
// filt(2:end) = filt(2:end) .* cos(w(2:end)/(2*d))
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
pfFilt[iDetectorIndex] = pfFilt[iDetectorIndex] * cosf(pfW[iDetectorIndex] / 2.0f / _fD);
}
break;
}
case FILTER_HAMMING:
{
// filt(2:end) = filt(2:end) .* (.54 + .46 * cos(w(2:end)/d))
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
pfFilt[iDetectorIndex] = pfFilt[iDetectorIndex] * ( 0.54f + 0.46f * cosf(pfW[iDetectorIndex] / _fD));
}
break;
}
case FILTER_HANN:
{
// filt(2:end) = filt(2:end) .*(1+cos(w(2:end)./d)) / 2
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
pfFilt[iDetectorIndex] = pfFilt[iDetectorIndex] * (1.0f + cosf(pfW[iDetectorIndex] / _fD)) / 2.0f;
}
break;
}
case FILTER_TUKEY:
{
float fAlpha = _fParameter;
if(_fParameter < 0.0f) fAlpha = 0.5f;
float fN = (float)_iFFTFourierDetectorCount;
float fHalfN = fN / 2.0f;
float fEnumTerm = fAlpha * fHalfN;
float fDenom = (1.0f - fAlpha) * fHalfN;
float fBlockStart = fHalfN - fEnumTerm;
float fBlockEnd = fHalfN + fEnumTerm;
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fAbsSmallN = fabs((float)iDetectorIndex);
float fStoredValue = 0.0f;
if((fBlockStart <= fAbsSmallN) && (fAbsSmallN <= fBlockEnd))
{
fStoredValue = 1.0f;
}
else
{
float fEnum = fAbsSmallN - fEnumTerm;
float fCosInput = M_PI * fEnum / fDenom;
fStoredValue = 0.5f * (1.0f + cosf(fCosInput));
}
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_LANCZOS:
{
float fDenum = (float)(_iFFTFourierDetectorCount - 1);
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fX = 2.0f * fSmallN / fDenum - 1.0f;
float fSinInput = M_PI * fX;
float fStoredValue = 0.0f;
if(fabsf(fSinInput) > 0.001f)
{
fStoredValue = sin(fSinInput)/fSinInput;
}
else
{
fStoredValue = 1.0f;
}
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_TRIANGULAR:
{
float fNMinusOne = (float)(_iFFTFourierDetectorCount - 1);
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fAbsInput = fSmallN - fNMinusOne / 2.0f;
float fParenInput = fNMinusOne / 2.0f - fabsf(fAbsInput);
float fStoredValue = 2.0f / fNMinusOne * fParenInput;
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_GAUSSIAN:
{
float fSigma = _fParameter;
if(_fParameter < 0.0f) fSigma = 0.4f;
float fN = (float)_iFFTFourierDetectorCount;
float fQuotient = (fN - 1.0f) / 2.0f;
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fEnum = fSmallN - fQuotient;
float fDenom = fSigma * fQuotient;
float fPower = -0.5f * (fEnum / fDenom) * (fEnum / fDenom);
float fStoredValue = expf(fPower);
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_BARTLETTHANN:
{
const float fA0 = 0.62f;
const float fA1 = 0.48f;
const float fA2 = 0.38f;
float fNMinusOne = (float)(_iFFTFourierDetectorCount) - 1.0f;
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fAbsInput = fSmallN / fNMinusOne - 0.5f;
float fFirstTerm = fA1 * fabsf(fAbsInput);
float fCosInput = 2.0f * M_PI * fSmallN / fNMinusOne;
float fSecondTerm = fA2 * cosf(fCosInput);
float fStoredValue = fA0 - fFirstTerm - fSecondTerm;
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_BLACKMAN:
{
float fAlpha = _fParameter;
if(_fParameter < 0.0f) fAlpha = 0.16f;
float fA0 = (1.0f - fAlpha) / 2.0f;
float fA1 = 0.5f;
float fA2 = fAlpha / 2.0f;
float fNMinusOne = (float)(_iFFTFourierDetectorCount - 1);
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fCosInput1 = 2.0f * M_PI * 0.5f * fSmallN / fNMinusOne;
float fCosInput2 = 4.0f * M_PI * 0.5f * fSmallN / fNMinusOne;
float fStoredValue = fA0 - fA1 * cosf(fCosInput1) + fA2 * cosf(fCosInput2);
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_NUTTALL:
{
const float fA0 = 0.355768f;
const float fA1 = 0.487396f;
const float fA2 = 0.144232f;
const float fA3 = 0.012604f;
float fNMinusOne = (float)(_iFFTFourierDetectorCount) - 1.0f;
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fBaseCosInput = M_PI * fSmallN / fNMinusOne;
float fFirstTerm = fA1 * cosf(2.0f * fBaseCosInput);
float fSecondTerm = fA2 * cosf(4.0f * fBaseCosInput);
float fThirdTerm = fA3 * cosf(6.0f * fBaseCosInput);
float fStoredValue = fA0 - fFirstTerm + fSecondTerm - fThirdTerm;
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_BLACKMANHARRIS:
{
const float fA0 = 0.35875f;
const float fA1 = 0.48829f;
const float fA2 = 0.14128f;
const float fA3 = 0.01168f;
float fNMinusOne = (float)(_iFFTFourierDetectorCount) - 1.0f;
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fBaseCosInput = M_PI * fSmallN / fNMinusOne;
float fFirstTerm = fA1 * cosf(2.0f * fBaseCosInput);
float fSecondTerm = fA2 * cosf(4.0f * fBaseCosInput);
float fThirdTerm = fA3 * cosf(6.0f * fBaseCosInput);
float fStoredValue = fA0 - fFirstTerm + fSecondTerm - fThirdTerm;
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_BLACKMANNUTTALL:
{
const float fA0 = 0.3635819f;
const float fA1 = 0.4891775f;
const float fA2 = 0.1365995f;
const float fA3 = 0.0106411f;
float fNMinusOne = (float)(_iFFTFourierDetectorCount) - 1.0f;
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fBaseCosInput = M_PI * fSmallN / fNMinusOne;
float fFirstTerm = fA1 * cosf(2.0f * fBaseCosInput);
float fSecondTerm = fA2 * cosf(4.0f * fBaseCosInput);
float fThirdTerm = fA3 * cosf(6.0f * fBaseCosInput);
float fStoredValue = fA0 - fFirstTerm + fSecondTerm - fThirdTerm;
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_FLATTOP:
{
const float fA0 = 1.0f;
const float fA1 = 1.93f;
const float fA2 = 1.29f;
const float fA3 = 0.388f;
const float fA4 = 0.032f;
float fNMinusOne = (float)(_iFFTFourierDetectorCount) - 1.0f;
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fBaseCosInput = M_PI * fSmallN / fNMinusOne;
float fFirstTerm = fA1 * cosf(2.0f * fBaseCosInput);
float fSecondTerm = fA2 * cosf(4.0f * fBaseCosInput);
float fThirdTerm = fA3 * cosf(6.0f * fBaseCosInput);
float fFourthTerm = fA4 * cosf(8.0f * fBaseCosInput);
float fStoredValue = fA0 - fFirstTerm + fSecondTerm - fThirdTerm + fFourthTerm;
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_KAISER:
{
float fAlpha = _fParameter;
if(_fParameter < 0.0f) fAlpha = 3.0f;
float fPiTimesAlpha = M_PI * fAlpha;
float fNMinusOne = (float)(_iFFTFourierDetectorCount - 1);
float fDenom = (float)j0((double)fPiTimesAlpha);
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fSquareInput = 2.0f * fSmallN / fNMinusOne - 1;
float fSqrtInput = 1.0f - fSquareInput * fSquareInput;
float fBesselInput = fPiTimesAlpha * sqrt(fSqrtInput);
float fEnum = (float)j0((double)fBesselInput);
float fStoredValue = fEnum / fDenom;
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
case FILTER_PARZEN:
{
for(int iDetectorIndex = 1; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fSmallN = (float)iDetectorIndex;
float fQ = fSmallN / (float)(_iFFTFourierDetectorCount - 1);
float fStoredValue = 0.0f;
if(fQ <= 0.5f)
{
fStoredValue = 1.0f - 6.0f * fQ * fQ * (1.0f - fQ);
}
else
{
float fCubedValue = 1.0f - fQ;
fStoredValue = 2.0f * fCubedValue * fCubedValue * fCubedValue;
}
pfFilt[iDetectorIndex] *= fStoredValue;
}
break;
}
default:
{
ASTRA_ERROR("Cannot serve requested filter");
}
}
// filt(w>pi*d) = 0;
float fPiTimesD = M_PI * _fD;
for(int iDetectorIndex = 0; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fWValue = pfW[iDetectorIndex];
if(fWValue > fPiTimesD)
{
pfFilt[iDetectorIndex] = 0.0f;
}
}
for(int iDetectorIndex = 0; iDetectorIndex < _iFFTFourierDetectorCount; iDetectorIndex++)
{
float fFilterValue = pfFilt[iDetectorIndex];
for(int iProjectionIndex = 0; iProjectionIndex < _iProjectionCount; iProjectionIndex++)
{
int iIndex = iDetectorIndex + iProjectionIndex * _iFFTFourierDetectorCount;
_pFilter[iIndex].x = fFilterValue;
_pFilter[iIndex].y = 0.0f;
}
}
delete[] pfFilt;
delete[] pfW;
}
#ifdef STANDALONE
__global__ static void doubleFourierOutput_kernel(int _iProjectionCount,
int _iDetectorCount,
cufftComplex* _pFourierOutput)
{
int iIndex = threadIdx.x + blockIdx.x * blockDim.x;
int iProjectionIndex = iIndex / _iDetectorCount;
int iDetectorIndex = iIndex % _iDetectorCount;
if(iProjectionIndex >= _iProjectionCount)
{
return;
}
if(iDetectorIndex <= (_iDetectorCount / 2))
{
return;
}
int iOtherDetectorIndex = _iDetectorCount - iDetectorIndex;
_pFourierOutput[iProjectionIndex * _iDetectorCount + iDetectorIndex].x = _pFourierOutput[iProjectionIndex * _iDetectorCount + iOtherDetectorIndex].x;
_pFourierOutput[iProjectionIndex * _iDetectorCount + iDetectorIndex].y = -_pFourierOutput[iProjectionIndex * _iDetectorCount + iOtherDetectorIndex].y;
}
static void doubleFourierOutput(int _iProjectionCount, int _iDetectorCount,
cufftComplex * _pFourierOutput)
{
const int iBlockSize = 256;
int iElementCount = _iProjectionCount * _iDetectorCount;
int iBlockCount = (iElementCount + iBlockSize - 1) / iBlockSize;
doubleFourierOutput_kernel<<< iBlockCount, iBlockSize >>>(_iProjectionCount,
_iDetectorCount,
_pFourierOutput);
CHECK_ERROR("doubleFourierOutput_kernel failed");
}
static void writeToMatlabFile(const char * _fileName, const float * _pfData,
int _iRowCount, int _iColumnCount)
{
std::ofstream out(_fileName);
for(int iRowIndex = 0; iRowIndex < _iRowCount; iRowIndex++)
{
for(int iColumnIndex = 0; iColumnIndex < _iColumnCount; iColumnIndex++)
{
out << _pfData[iColumnIndex + iRowIndex * _iColumnCount] << " ";
}
out << std::endl;
}
}
static void convertComplexToRealImg(const cufftComplex * _pComplex,
int _iElementCount,
float * _pfReal, float * _pfImaginary)
{
for(int iIndex = 0; iIndex < _iElementCount; iIndex++)
{
_pfReal[iIndex] = _pComplex[iIndex].x;
_pfImaginary[iIndex] = _pComplex[iIndex].y;
}
}
void testCudaFFT()
{
const int iProjectionCount = 2;
const int iDetectorCount = 1024;
const int iTotalElementCount = iProjectionCount * iDetectorCount;
float * pfHostProj = new float[iTotalElementCount];
memset(pfHostProj, 0, sizeof(float) * iTotalElementCount);
for(int iProjectionIndex = 0; iProjectionIndex < iProjectionCount; iProjectionIndex++)
{
for(int iDetectorIndex = 0; iDetectorIndex < iDetectorCount; iDetectorIndex++)
{
// int
// pfHostProj[iIndex] = (float)rand() / (float)RAND_MAX;
}
}
writeToMatlabFile("proj.mat", pfHostProj, iProjectionCount, iDetectorCount);
float * pfDevProj = NULL;
SAFE_CALL(cudaMalloc((void **)&pfDevProj, sizeof(float) * iTotalElementCount));
SAFE_CALL(cudaMemcpy(pfDevProj, pfHostProj, sizeof(float) * iTotalElementCount, cudaMemcpyHostToDevice));
cufftComplex * pDevFourProj = NULL;
SAFE_CALL(cudaMalloc((void **)&pDevFourProj, sizeof(cufftComplex) * iTotalElementCount));
cufftHandle plan;
cufftResult result;
result = cufftPlan1d(&plan, iDetectorCount, CUFFT_R2C, iProjectionCount);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to plan 1d r2c fft");
}
result = cufftExecR2C(plan, pfDevProj, pDevFourProj);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to exec 1d r2c fft");
}
cufftDestroy(plan);
doubleFourierOutput(iProjectionCount, iDetectorCount, pDevFourProj);
cufftComplex * pHostFourProj = new cufftComplex[iTotalElementCount];
SAFE_CALL(cudaMemcpy(pHostFourProj, pDevFourProj, sizeof(cufftComplex) * iTotalElementCount, cudaMemcpyDeviceToHost));
float * pfHostFourProjReal = new float[iTotalElementCount];
float * pfHostFourProjImaginary = new float[iTotalElementCount];
convertComplexToRealImg(pHostFourProj, iTotalElementCount, pfHostFourProjReal, pfHostFourProjImaginary);
writeToMatlabFile("proj_four_real.mat", pfHostFourProjReal, iProjectionCount, iDetectorCount);
writeToMatlabFile("proj_four_imaginary.mat", pfHostFourProjImaginary, iProjectionCount, iDetectorCount);
float * pfDevInFourProj = NULL;
SAFE_CALL(cudaMalloc((void **)&pfDevInFourProj, sizeof(float) * iTotalElementCount));
result = cufftPlan1d(&plan, iDetectorCount, CUFFT_C2R, iProjectionCount);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to plan 1d c2r fft");
}
result = cufftExecC2R(plan, pDevFourProj, pfDevInFourProj);
if(result != CUFFT_SUCCESS)
{
ASTRA_ERROR("Failed to exec 1d c2r fft");
}
cufftDestroy(plan);
rescaleInverseFourier(iProjectionCount, iDetectorCount, pfDevInFourProj);
float * pfHostInFourProj = new float[iTotalElementCount];
SAFE_CALL(cudaMemcpy(pfHostInFourProj, pfDevInFourProj, sizeof(float) * iTotalElementCount, cudaMemcpyDeviceToHost));
writeToMatlabFile("in_four.mat", pfHostInFourProj, iProjectionCount, iDetectorCount);
SAFE_CALL(cudaFree(pDevFourProj));
SAFE_CALL(cudaFree(pfDevProj));
delete [] pfHostInFourProj;
delete [] pfHostFourProjReal;
delete [] pfHostFourProjImaginary;
delete [] pfHostProj;
delete [] pHostFourProj;
}
void downloadDebugFilterComplex(float * _pfHostSinogram, int _iProjectionCount,
int _iDetectorCount,
cufftComplex * _pDevFilter,
int _iFilterDetCount)
{
cufftComplex * pHostFilter = NULL;
size_t complMemSize = sizeof(cufftComplex) * _iFilterDetCount * _iProjectionCount;
pHostFilter = (cufftComplex *)malloc(complMemSize);
SAFE_CALL(cudaMemcpy(pHostFilter, _pDevFilter, complMemSize, cudaMemcpyDeviceToHost));
for(int iTargetProjIndex = 0; iTargetProjIndex < _iProjectionCount; iTargetProjIndex++)
{
for(int iTargetDetIndex = 0; iTargetDetIndex < min(_iDetectorCount, _iFilterDetCount); iTargetDetIndex++)
{
cufftComplex source = pHostFilter[iTargetDetIndex + iTargetProjIndex * _iFilterDetCount];
float fReadValue = sqrtf(source.x * source.x + source.y * source.y);
_pfHostSinogram[iTargetDetIndex + iTargetProjIndex * _iDetectorCount] = fReadValue;
}
}
free(pHostFilter);
}
void downloadDebugFilterReal(float * _pfHostSinogram, int _iProjectionCount,
int _iDetectorCount, float * _pfDevFilter,
int _iFilterDetCount)
{
float * pfHostFilter = NULL;
size_t memSize = sizeof(float) * _iFilterDetCount * _iProjectionCount;
pfHostFilter = (float *)malloc(memSize);
SAFE_CALL(cudaMemcpy(pfHostFilter, _pfDevFilter, memSize, cudaMemcpyDeviceToHost));
for(int iTargetProjIndex = 0; iTargetProjIndex < _iProjectionCount; iTargetProjIndex++)
{
for(int iTargetDetIndex = 0; iTargetDetIndex < min(_iDetectorCount, _iFilterDetCount); iTargetDetIndex++)
{
float fSource = pfHostFilter[iTargetDetIndex + iTargetProjIndex * _iFilterDetCount];
_pfHostSinogram[iTargetDetIndex + iTargetProjIndex * _iDetectorCount] = fSource;
}
}
free(pfHostFilter);
}
#endif