/*
-----------------------------------------------------------------------
Copyright: 2010-2018, imec Vision Lab, University of Antwerp
2014-2018, CWI, Amsterdam
Contact: astra@astra-toolbox.com
Website: http://www.astra-toolbox.com/
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 <http://www.gnu.org/licenses/>.
-----------------------------------------------------------------------
*/
#include "astra/CudaForwardProjectionAlgorithm.h"
#ifdef ASTRA_CUDA
#include "astra/cuda/2d/astra.h"
#include <driver_types.h>
#include <cuda_runtime_api.h>
#include "astra/AstraObjectManager.h"
#include "astra/ParallelProjectionGeometry2D.h"
#include "astra/FanFlatProjectionGeometry2D.h"
#include "astra/FanFlatVecProjectionGeometry2D.h"
#include "astra/Float32ProjectionData2D.h"
#include "astra/Float32VolumeData2D.h"
#include "astra/CudaProjector2D.h"
#include "astra/Logging.h"
using namespace std;
namespace astra {
// type of the algorithm, needed to register with CAlgorithmFactory
std::string CCudaForwardProjectionAlgorithm::type = "FP_CUDA";
//----------------------------------------------------------------------------------------
// Constructor
CCudaForwardProjectionAlgorithm::CCudaForwardProjectionAlgorithm()
{
m_bIsInitialized = false;
}
//----------------------------------------------------------------------------------------
// Destructor
CCudaForwardProjectionAlgorithm::~CCudaForwardProjectionAlgorithm()
{
}
//---------------------------------------------------------------------------------------
void CCudaForwardProjectionAlgorithm::initializeFromProjector()
{
m_iDetectorSuperSampling = 1;
m_iGPUIndex = -1;
// Projector
CCudaProjector2D* pCudaProjector = dynamic_cast<CCudaProjector2D*>(m_pProjector);
if (!pCudaProjector) {
if (m_pProjector) {
ASTRA_WARN("non-CUDA Projector2D passed to FP_CUDA");
}
} else {
m_iDetectorSuperSampling = pCudaProjector->getDetectorSuperSampling();
m_iGPUIndex = pCudaProjector->getGPUIndex();
}
}
//---------------------------------------------------------------------------------------
// Initialize - Config
bool CCudaForwardProjectionAlgorithm::initialize(const Config& _cfg)
{
ASTRA_ASSERT(_cfg.self);
ConfigStackCheck<CAlgorithm> CC("CudaForwardProjectionAlgorithm", this, _cfg);
// Projector
m_pProjector = 0;
XMLNode node = _cfg.self.getSingleNode("ProjectorId");
if (node) {
int id = StringUtil::stringToInt(node.getContent(), -1);
m_pProjector = CProjector2DManager::getSingleton().get(id);
}
CC.markNodeParsed("ProjectorId");
// sinogram data
node = _cfg.self.getSingleNode("ProjectionDataId");
ASTRA_CONFIG_CHECK(node, "FP_CUDA", "No ProjectionDataId tag specified.");
int id = StringUtil::stringToInt(node.getContent(), -1);
m_pSinogram = dynamic_cast<CFloat32ProjectionData2D*>(CData2DManager::getSingleton().get(id));
CC.markNodeParsed("ProjectionDataId");
// volume data
node = _cfg.self.getSingleNode("VolumeDataId");
ASTRA_CONFIG_CHECK(node, "FP_CUDA", "No VolumeDataId tag specified.");
id = StringUtil::stringToInt(node.getContent(), -1);
m_pVolume = dynamic_cast<CFloat32VolumeData2D*>(CData2DManager::getSingleton().get(id));
CC.markNodeParsed("VolumeDataId");
initializeFromProjector();
// Deprecated options
try {
m_iDetectorSuperSampling = _cfg.self.getOptionInt("DetectorSuperSampling", m_iDetectorSuperSampling);
} catch (const StringUtil::bad_cast &e) {
ASTRA_CONFIG_CHECK(false, "FP_CUDA", "Supersampling options must be integers.");
}
CC.markOptionParsed("DetectorSuperSampling");
// GPU number
try {
m_iGPUIndex = _cfg.self.getOptionInt("GPUindex", -1);
m_iGPUIndex = _cfg.self.getOptionInt("GPUIndex", m_iGPUIndex);
} catch (const StringUtil::bad_cast &e) {
ASTRA_CONFIG_CHECK(false, "FP_CUDA", "GPUIndex must be an integer.");
}
CC.markOptionParsed("GPUIndex");
if (!_cfg.self.hasOption("GPUIndex"))
CC.markOptionParsed("GPUindex");
// return success
return check();
}
//----------------------------------------------------------------------------------------
// Initialize - C++
bool CCudaForwardProjectionAlgorithm::initialize(CProjector2D* _pProjector,
CFloat32VolumeData2D* _pVolume,
CFloat32ProjectionData2D* _pSinogram)
{
// store classes
m_pProjector = _pProjector;
m_pVolume = _pVolume;
m_pSinogram = _pSinogram;
initializeFromProjector();
// return success
return check();
}
//----------------------------------------------------------------------------------------
// Check
bool CCudaForwardProjectionAlgorithm::check()
{
// check pointers
ASTRA_CONFIG_CHECK(m_pSinogram, "FP_CUDA", "No valid projection data object found.");
ASTRA_CONFIG_CHECK(m_pSinogram->isInitialized(), "FP_CUDA", "Projection data not initialized.");
ASTRA_CONFIG_CHECK(m_pVolume, "FP_CUDA", "No valid volume data object found.");
ASTRA_CONFIG_CHECK(m_pVolume->isInitialized(), "FP_CUDA", "Volume data not initialized.");
// check restrictions
//int iImageSideBlocks = m_pReconstructionGeometry->getGridColCount() / G_BLOCKIMAGESIZE;
//ASTRA_CONFIG_CHECK((iImageSideBlocks * G_BLOCKIMAGESIZE) == m_pVolume->getWidth(), "FP_CUDA", "Volume Width must be a multiple of G_BLOCKIMAGESIZE");
//ASTRA_CONFIG_CHECK((iImageSideBlocks * G_BLOCKIMAGESIZE) == m_pVolume->getHeight(), "FP_CUDA", "Volume Height must be a multiple of G_BLOCKIMAGESIZE");
//ASTRA_CONFIG_CHECK(m_pProjectionGeometry->getDetectorCount() == (m_pVolume->getWidth() * 3 / 2), "SIRT_CUDA", "Number of detectors must be 1.5 times the width of the image");
ASTRA_CONFIG_CHECK(m_iGPUIndex >= -1, "FP_CUDA", "GPUIndex must be a non-negative integer.");
// success
m_bIsInitialized = true;
return true;
}
void CCudaForwardProjectionAlgorithm::setGPUIndex(int _iGPUIndex)
{
m_iGPUIndex = _iGPUIndex;
}
//---------------------------------------------------------------------------------------
// Information - All
map<string,boost::any> CCudaForwardProjectionAlgorithm::getInformation()
{
map<string, boost::any> res;
res["ProjectionGeometry"] = getInformation("ProjectionGeometry");
res["ReconstructionGeometry"] = getInformation("ReconstructionGeometry");
res["ProjectionDataId"] = getInformation("ProjectionDataId");
res["VolumeDataId"] = getInformation("VolumeDataId");
res["GPUindex"] = getInformation("GPUindex");
res["DetectorSuperSampling"] = getInformation("DetectorSuperSampling");
return mergeMap<string,boost::any>(CAlgorithm::getInformation(), res);
};
//---------------------------------------------------------------------------------------
// Information - Specific
boost::any CCudaForwardProjectionAlgorithm::getInformation(std::string _sIdentifier)
{
if (_sIdentifier == "ProjectionGeometry") { return string("not implemented"); }
if (_sIdentifier == "ReconstructionGeometry") { return string("not implemented"); }
if (_sIdentifier == "ProjectionDataId") {
int iIndex = CData2DManager::getSingleton().getIndex(m_pSinogram);
if (iIndex != 0) return iIndex;
return std::string("not in manager");
}
if (_sIdentifier == "VolumeDataId") {
int iIndex = CData2DManager::getSingleton().getIndex(m_pVolume);
if (iIndex != 0) return iIndex;
return std::string("not in manager");
}
if (_sIdentifier == "GPUindex") { return m_iGPUIndex; }
if (_sIdentifier == "DetectorSuperSampling") { return m_iDetectorSuperSampling; }
return CAlgorithm::getInformation(_sIdentifier);
};
//----------------------------------------------------------------------------------------
// Run
void CCudaForwardProjectionAlgorithm::run(int)
{
// check initialized
assert(m_bIsInitialized);
bool ok;
const CVolumeGeometry2D* pVolGeom = m_pVolume->getGeometry();
const CProjectionGeometry2D* pProjGeom = m_pSinogram->getGeometry();
astraCUDA::SDimensions dims;
ok = convertAstraGeometry_dims(pVolGeom, pProjGeom, dims);
if (!ok)
return;
astraCUDA::SParProjection* pParProjs = 0;
astraCUDA::SFanProjection* pFanProjs = 0;
float fOutputScale = 1.0f;
ok = convertAstraGeometry(pVolGeom, pProjGeom, pParProjs, pFanProjs, fOutputScale);
if (!ok)
return;
if (pParProjs) {
assert(!pFanProjs);
ok = astraCudaFP(m_pVolume->getDataConst(), m_pSinogram->getData(),
pVolGeom->getGridColCount(), pVolGeom->getGridRowCount(),
pProjGeom->getProjectionAngleCount(),
pProjGeom->getDetectorCount(),
pParProjs,
m_iDetectorSuperSampling, 1.0f * fOutputScale, m_iGPUIndex);
delete[] pParProjs;
} else {
assert(pFanProjs);
ok = astraCudaFanFP(m_pVolume->getDataConst(), m_pSinogram->getData(),
pVolGeom->getGridColCount(), pVolGeom->getGridRowCount(),
pProjGeom->getProjectionAngleCount(),
pProjGeom->getDetectorCount(),
pFanProjs,
m_iDetectorSuperSampling, fOutputScale, m_iGPUIndex);
delete[] pFanProjs;
}
ASTRA_ASSERT(ok);
}
} // namespace astra
#endif // ASTRA_CUDA