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CentroidPeaksMD2.cpp
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CentroidPeaksMD2.cpp
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// Mantid Repository : https://github.com/mantidproject/mantid
//
// Copyright © 2018 ISIS Rutherford Appleton Laboratory UKRI,
// NScD Oak Ridge National Laboratory, European Spallation Source,
// Institut Laue - Langevin & CSNS, Institute of High Energy Physics, CAS
// SPDX - License - Identifier: GPL - 3.0 +
#include "MantidMDAlgorithms/CentroidPeaksMD2.h"
#include "MantidAPI/IMDEventWorkspace.h"
#include "MantidAPI/IPeaksWorkspace.h"
#include "MantidDataObjects/CoordTransformDistance.h"
#include "MantidDataObjects/LeanElasticPeaksWorkspace.h"
#include "MantidDataObjects/MDEventFactory.h"
#include "MantidDataObjects/PeaksWorkspace.h"
#include "MantidKernel/ListValidator.h"
#include "MantidKernel/System.h"
#include "MantidMDAlgorithms/IntegratePeaksMD.h"
namespace Mantid::MDAlgorithms {
// Register the algorithm into the AlgorithmFactory
DECLARE_ALGORITHM(CentroidPeaksMD2)
using namespace Mantid::API;
using namespace Mantid::DataObjects;
using namespace Mantid::Geometry;
using namespace Mantid::Kernel;
using namespace Mantid::DataObjects;
//----------------------------------------------------------------------------------------------
/** Initialize the algorithm's properties.
*/
void CentroidPeaksMD2::init() {
declareProperty(std::make_unique<WorkspaceProperty<IMDEventWorkspace>>("InputWorkspace", "", Direction::Input),
"An input MDEventWorkspace.");
declareProperty(std::make_unique<PropertyWithValue<double>>("PeakRadius", 1.0, Direction::Input),
"Fixed radius around each peak position in which to calculate the "
"centroid.");
declareProperty(std::make_unique<WorkspaceProperty<IPeaksWorkspace>>("PeaksWorkspace", "", Direction::Input),
"A PeaksWorkspace containing the peaks to centroid.");
declareProperty(std::make_unique<WorkspaceProperty<IPeaksWorkspace>>("OutputWorkspace", "", Direction::Output),
"The output PeaksWorkspace will be a copy of the input PeaksWorkspace "
"with the peaks' positions modified by the new found centroids.");
}
//----------------------------------------------------------------------------------------------
/** Integrate the peaks of the workspace using parameters saved in the algorithm
* class
* @param ws :: MDEventWorkspace to integrate
*/
template <typename MDE, size_t nd> void CentroidPeaksMD2::integrate(typename MDEventWorkspace<MDE, nd>::sptr ws) {
if (nd != 3)
throw std::invalid_argument("For now, we expect the input MDEventWorkspace "
"to have 3 dimensions only.");
/// Peak workspace to centroid
IPeaksWorkspace_sptr inPeakWS = getProperty("PeaksWorkspace");
/// Output peaks workspace, create if needed
IPeaksWorkspace_sptr peakWS = getProperty("OutputWorkspace");
if (peakWS != inPeakWS)
peakWS = inPeakWS->clone();
int CoordinatesToUse = ws->getSpecialCoordinateSystem();
/// Radius to use around peaks
double PeakRadius = getProperty("PeakRadius");
PRAGMA_OMP(parallel for schedule(dynamic, 10) )
for (int i = 0; i < int(peakWS->getNumberPeaks()); ++i) {
// Get a direct ref to that peak.
IPeak &p = peakWS->getPeak(i);
Peak *peak = dynamic_cast<Peak *>(&p);
double detectorDistance = 0.;
if (peak)
detectorDistance = p.getL2();
// Get the peak center as a position in the dimensions of the workspace
V3D pos;
if (CoordinatesToUse == 1) //"Q (lab frame)"
pos = p.getQLabFrame();
else if (CoordinatesToUse == 2) //"Q (sample frame)"
pos = p.getQSampleFrame();
else if (CoordinatesToUse == 3) //"HKL"
pos = p.getHKL();
// Build the sphere transformation
bool dimensionsUsed[nd];
coord_t center[nd];
for (size_t d = 0; d < nd; ++d) {
dimensionsUsed[d] = true; // Use all dimensions
center[d] = static_cast<coord_t>(pos[d]);
}
CoordTransformDistance sphere(nd, center, dimensionsUsed);
// Initialize the centroid to 0.0
signal_t signal = 0;
coord_t centroid[nd];
for (size_t d = 0; d < nd; d++)
centroid[d] = 0.0;
// Perform centroid
ws->getBox()->centroidSphere(sphere, static_cast<coord_t>(PeakRadius * PeakRadius), centroid, signal);
// Normalize by signal
if (signal != 0.0) {
for (size_t d = 0; d < nd; d++)
centroid[d] /= static_cast<coord_t>(signal);
V3D vecCentroid(centroid[0], centroid[1], centroid[2]);
p.setBinCount(static_cast<double>(signal));
// Save it back in the peak object, in the dimension specified.
try {
if (CoordinatesToUse == 1) //"Q (lab frame)"
{
p.setQLabFrame(vecCentroid, detectorDistance);
if (peak)
peak->findDetector();
} else if (CoordinatesToUse == 2) //"Q (sample frame)"
{
p.setQSampleFrame(vecCentroid, detectorDistance);
if (peak)
peak->findDetector();
} else if (CoordinatesToUse == 3) //"HKL"
{
p.setHKL(vecCentroid);
}
} catch (std::exception &e) {
g_log.warning() << "Error setting Q or HKL\n";
g_log.warning() << e.what() << '\n';
}
g_log.information() << "Peak " << i << " at " << pos << ": signal " << signal << ", centroid " << vecCentroid
<< " in " << CoordinatesToUse << '\n';
} else {
g_log.information() << "Peak " << i << " at " << pos << " had no signal, and could not be centroided.\n";
}
}
// Save the output
setProperty("OutputWorkspace", peakWS);
}
//----------------------------------------------------------------------------------------------
/** Execute the algorithm.
*/
void CentroidPeaksMD2::exec() {
inWS = getProperty("InputWorkspace");
CALL_MDEVENT_FUNCTION3(this->integrate, inWS);
}
} // namespace Mantid::MDAlgorithms