/*
-----------------------------------------------------------------------
Copyright: 2010-2014, iMinds-Vision Lab, University of Antwerp
2014, 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 "astra/ArtAlgorithm.h"
#include
#include "astra/AstraObjectManager.h"
using namespace std;
namespace astra {
// type of the algorithm, needed to register with CAlgorithmFactory
std::string CArtAlgorithm::type = "ART";
//----------------------------------------------------------------------------------------
// Constructor
CArtAlgorithm::CArtAlgorithm()
: CReconstructionAlgorithm2D()
{
m_fLambda = 1.0f;
m_iRayCount = 0;
m_iCurrentRay = 0;
m_piProjectionOrder = NULL;
m_piDetectorOrder = NULL;
m_bIsInitialized = false;
}
//----------------------------------------------------------------------------------------
// Destructor
CArtAlgorithm::~CArtAlgorithm()
{
if (m_piProjectionOrder != NULL)
delete[] m_piProjectionOrder;
if (m_piDetectorOrder != NULL)
delete[] m_piDetectorOrder;
}
//---------------------------------------------------------------------------------------
// Clear - Constructors
void CArtAlgorithm::_clear()
{
CReconstructionAlgorithm2D::_clear();
m_piDetectorOrder = NULL;
m_piProjectionOrder = NULL;
m_iRayCount = 0;
m_iCurrentRay = 0;
m_bIsInitialized = false;
}
//---------------------------------------------------------------------------------------
// Clear - Public
void CArtAlgorithm::clear()
{
CReconstructionAlgorithm2D::clear();
if (m_piDetectorOrder) {
delete[] m_piDetectorOrder;
m_piDetectorOrder = NULL;
}
if (m_piProjectionOrder) {
delete[] m_piProjectionOrder;
m_piProjectionOrder = NULL;
}
m_fLambda = 1.0f;
m_iRayCount = 0;
m_iCurrentRay = 0;
m_bIsInitialized = false;
}
//---------------------------------------------------------------------------------------
// Check
bool CArtAlgorithm::_check()
{
// check base class
ASTRA_CONFIG_CHECK(CReconstructionAlgorithm2D::_check(), "ART", "Error in ReconstructionAlgorithm2D initialization");
// check ray order list
for (int i = 0; i < m_iRayCount; i++) {
if (m_piProjectionOrder[i] < 0 || m_piProjectionOrder[i] > m_pSinogram->getAngleCount()-1) {
ASTRA_CONFIG_CHECK(false, "ART", "Invalid value in ray order list.");
}
if (m_piDetectorOrder[i] < 0 || m_piDetectorOrder[i] > m_pSinogram->getDetectorCount()-1) {
ASTRA_CONFIG_CHECK(false, "ART", "Invalid value in ray order list.");
}
}
// success
return true;
}
//---------------------------------------------------------------------------------------
// Initialize - Config
bool CArtAlgorithm::initialize(const Config& _cfg)
{
ASTRA_ASSERT(_cfg.self);
ConfigStackCheck CC("ArtAlgorithm", this, _cfg);
// if already initialized, clear first
if (m_bIsInitialized) {
clear();
}
// initialization of parent class
if (!CReconstructionAlgorithm2D::initialize(_cfg)) {
return false;
}
// ray order
string projOrder = _cfg.self->getOption("RayOrder", "sequential");
CC.markOptionParsed("RayOrder");
m_iCurrentRay = 0;
m_iRayCount = m_pProjector->getProjectionGeometry()->getProjectionAngleCount() *
m_pProjector->getProjectionGeometry()->getDetectorCount();
if (projOrder == "sequential") {
m_piProjectionOrder = new int[m_iRayCount];
m_piDetectorOrder = new int[m_iRayCount];
for (int i = 0; i < m_iRayCount; i++) {
m_piProjectionOrder[i] = (int)floor((float)i / m_pProjector->getProjectionGeometry()->getDetectorCount());
m_piDetectorOrder[i] = i % m_pProjector->getProjectionGeometry()->getDetectorCount();
}
} else if (projOrder == "custom") {
vector rayOrderList = _cfg.self->getOptionNumericalArray("RayOrderList");
m_iRayCount = rayOrderList.size() / 2;
m_piProjectionOrder = new int[m_iRayCount];
m_piDetectorOrder = new int[m_iRayCount];
for (int i = 0; i < m_iRayCount; i++) {
m_piProjectionOrder[i] = static_cast(rayOrderList[2*i]);
m_piDetectorOrder[i] = static_cast(rayOrderList[2*i+1]);
}
CC.markOptionParsed("RayOrderList");
} else {
return false;
}
m_fLambda = _cfg.self->getOptionNumerical("Lambda", 1.0f);
CC.markOptionParsed("Lambda");
// success
m_bIsInitialized = _check();
return m_bIsInitialized;
}
//----------------------------------------------------------------------------------------
// Initialize - C++
bool CArtAlgorithm::initialize(CProjector2D* _pProjector,
CFloat32ProjectionData2D* _pSinogram,
CFloat32VolumeData2D* _pReconstruction)
{
// if already initialized, clear first
if (m_bIsInitialized) {
clear();
}
// required classes
m_pProjector = _pProjector;
m_pSinogram = _pSinogram;
m_pReconstruction = _pReconstruction;
// ray order
m_iCurrentRay = 0;
m_iRayCount = _pProjector->getProjectionGeometry()->getDetectorCount() *
_pProjector->getProjectionGeometry()->getProjectionAngleCount();
m_piProjectionOrder = new int[m_iRayCount];
m_piDetectorOrder = new int[m_iRayCount];
for (int i = 0; i < m_iRayCount; i++) {
m_piProjectionOrder[i] = (int)floor((float)i / _pProjector->getProjectionGeometry()->getDetectorCount());
m_piDetectorOrder[i] = i % _pProjector->getProjectionGeometry()->getDetectorCount();
}
// success
m_bIsInitialized = _check();
return m_bIsInitialized;
}
//----------------------------------------------------------------------------------------
// Set the relaxation factor.
void CArtAlgorithm::setLambda(float32 _fLambda)
{
m_fLambda = _fLambda;
}
//----------------------------------------------------------------------------------------
// Set the order in which the rays will be selected
void CArtAlgorithm::setRayOrder(int* _piProjectionOrder, int* _piDetectorOrder, int _iRayCount)
{
if (m_piDetectorOrder) {
delete[] m_piDetectorOrder;
m_piDetectorOrder = NULL;
}
if (m_piProjectionOrder) {
delete[] m_piProjectionOrder;
m_piProjectionOrder = NULL;
}
m_iCurrentRay = 0;
m_iRayCount = _iRayCount;
m_piProjectionOrder = new int[m_iRayCount];
m_piDetectorOrder = new int[m_iRayCount];
for (int i = 0; i < m_iRayCount; i++) {
m_piProjectionOrder[i] = _piProjectionOrder[i];
m_piDetectorOrder[i] = _piDetectorOrder[i];
}
}
//---------------------------------------------------------------------------------------
// Information - All
map CArtAlgorithm::getInformation()
{
map res;
res["RayOrder"] = getInformation("RayOrder");
res["Lambda"] = getInformation("Lambda");
return mergeMap(CReconstructionAlgorithm2D::getInformation(), res);
};
//---------------------------------------------------------------------------------------
// Information - Specific
boost::any CArtAlgorithm::getInformation(std::string _sIdentifier)
{
if (_sIdentifier == "Lambda") { return m_fLambda; }
if (_sIdentifier == "RayOrder") {
vector res;
for (int i = 0; i < m_iRayCount; i++) {
res.push_back(m_piProjectionOrder[i]);
}
for (int i = 0; i < m_iRayCount; i++) {
res.push_back(m_piDetectorOrder[i]);
}
return res;
}
return CAlgorithm::getInformation(_sIdentifier);
};
//----------------------------------------------------------------------------------------
// Iterate
void CArtAlgorithm::run(int _iNrIterations)
{
// check initialized
assert(m_bIsInitialized);
// variables
int iIteration, iPixel;
int iUsedPixels, iProjection, iDetector;
float32 fRayForwardProj, fSumSquaredWeights;
float32 fProjectionDifference, fBackProjectionFactor;
// create a pixel buffer
int iPixelBufferSize = m_pProjector->getProjectionWeightsCount(0);
SPixelWeight* pPixels = new SPixelWeight[iPixelBufferSize];
// start iterations
for (iIteration = _iNrIterations-1; iIteration >= 0; --iIteration) {
// step0: compute single weight rays
iProjection = m_piProjectionOrder[m_iCurrentRay];
iDetector = m_piDetectorOrder[m_iCurrentRay];
m_iCurrentRay = (m_iCurrentRay + 1) % m_iRayCount;
if (m_bUseSinogramMask && m_pSinogramMask->getData2D()[iProjection][iDetector] == 0) continue;
m_pProjector->computeSingleRayWeights(iProjection, iDetector, pPixels, iPixelBufferSize, iUsedPixels);
// step1: forward projections
fRayForwardProj = 0.0f;
fSumSquaredWeights = 0.0f;
for (iPixel = iUsedPixels-1; iPixel >= 0; --iPixel) {
if (m_bUseReconstructionMask && m_pReconstructionMask->getDataConst()[pPixels[iPixel].m_iIndex] == 0) continue;
fRayForwardProj += pPixels[iPixel].m_fWeight * m_pReconstruction->getDataConst()[pPixels[iPixel].m_iIndex];
fSumSquaredWeights += pPixels[iPixel].m_fWeight * pPixels[iPixel].m_fWeight;
}
if (fSumSquaredWeights == 0) continue;
// step2: difference
fProjectionDifference = m_pSinogram->getData2D()[iProjection][iDetector] - fRayForwardProj;
// step3: back projection
fBackProjectionFactor = m_fLambda * fProjectionDifference / fSumSquaredWeights;
for (iPixel = iUsedPixels-1; iPixel >= 0; --iPixel) {
// pixel must be loose
if (m_bUseReconstructionMask && m_pReconstructionMask->getDataConst()[pPixels[iPixel].m_iIndex] == 0) continue;
// update
m_pReconstruction->getData()[pPixels[iPixel].m_iIndex] += fBackProjectionFactor * pPixels[iPixel].m_fWeight;
// constraints
if (m_bUseMinConstraint && m_pReconstruction->getData()[pPixels[iPixel].m_iIndex] < m_fMinValue) {
m_pReconstruction->getData()[pPixels[iPixel].m_iIndex] = m_fMinValue;
}
if (m_bUseMaxConstraint && m_pReconstruction->getData()[pPixels[iPixel].m_iIndex] > m_fMaxValue) {
m_pReconstruction->getData()[pPixels[iPixel].m_iIndex] = m_fMaxValue;
}
}
}
delete[] pPixels;
// update statistics
m_pReconstruction->updateStatistics();
}
//----------------------------------------------------------------------------------------
} // namespace astra