/** Retrieves the detector postion for a given spectrum
* @param index :: The workspace index of the spectrum
* @param l1 :: Returns the source-sample distance
* @param l2 :: Returns the sample-detector distance
* @param twoTheta :: Returns the detector's scattering angle
*/
void RemoveBins::calculateDetectorPosition(const int& index, double& l1, double& l2, double& twoTheta)
{
// Get a pointer to the instrument contained in the workspace
Geometry::Instrument_const_sptr instrument = m_inputWorkspace->getInstrument();
// Get the distance between the source and the sample (assume in metres)
Geometry::IObjComponent_const_sptr sample = instrument->getSample();
// Check for valid instrument
if (sample == NULL)
{
throw Exception::InstrumentDefinitionError("Instrument not sufficiently defined: failed to get sample");
}
l1 = instrument->getSource()->getDistance(*sample);
Geometry::IDetector_const_sptr det = m_inputWorkspace->getDetector(index);
// Get the sample-detector distance for this detector (in metres)
if ( ! det->isMonitor() )
{
l2 = det->getDistance(*sample);
// The scattering angle for this detector (in radians).
twoTheta = m_inputWorkspace->detectorTwoTheta(det);
}
else // If this is a monitor then make l1+l2 = source-detector distance and twoTheta=0
{
l2 = det->getDistance(*(instrument->getSource()));
l2 = l2 - l1;
twoTheta = 0.0;
}
g_log.debug() << "Detector for index " << index << " has L1+L2=" << l1+l2 << " & 2theta= " << twoTheta << std::endl;
return;
}
/** Calculates the total flightpath for the given detector.
* This is L1+L2 normally, but is the source-detector distance for a monitor.
* @param spectrum :: The workspace index
* @param L1 :: The primary flightpath
* @param isMonitor :: Output: true is this detector is a monitor
* @return The flightpath (Ld) for the detector linked to spectrum
* @throw Kernel::Exception::InstrumentDefinitionError if the detector position
* can't be obtained
*/
double UnwrapMonitor::calculateFlightpath(const int &spectrum, const double &L1,
bool &isMonitor) const {
double Ld = -1.0;
try {
// Get the detector object for this histogram
Geometry::IDetector_const_sptr det = m_inputWS->getDetector(spectrum);
// Get the sample-detector distance for this detector (or source-detector if
// a monitor)
// This is the total flightpath
isMonitor = det->isMonitor();
// Get the L2 distance if this detector is not a monitor
if (!isMonitor) {
double L2 = det->getDistance(*(m_inputWS->getInstrument()->getSample()));
Ld = L1 + L2;
}
// If it is a monitor, then the flightpath is the distance to the source
else {
Ld = det->getDistance(*(m_inputWS->getInstrument()->getSource()));
}
} catch (Exception::NotFoundError &) {
// If the detector information is missing, return a negative number
}
return Ld;
}
void FindDetectorsPar::populate_values_from_file(
const API::MatrixWorkspace_sptr &inputWS) {
size_t nHist = inputWS->getNumberHistograms();
if (this->current_ASCII_file.Type == PAR_type) {
// in this case data in azimuthal width and polar width are in fact real
// sizes in meters; have to transform it in into angular values
for (size_t i = 0; i < nHist; i++) {
azimuthalWidth[i] =
atan2(azimuthalWidth[i], secondaryFlightpath[i]) * rad2deg;
polarWidth[i] = atan2(polarWidth[i], secondaryFlightpath[i]) * rad2deg;
}
m_SizesAreLinear = false;
} else {
Geometry::IComponent_const_sptr sample =
inputWS->getInstrument()->getSample();
secondaryFlightpath.resize(nHist);
// Loop over the spectra
for (size_t i = 0; i < nHist; i++) {
Geometry::IDetector_const_sptr spDet;
try {
spDet = inputWS->getDetector(i);
} catch (Kernel::Exception::NotFoundError &) {
continue;
}
// Check that we aren't writing a monitor...
if (spDet->isMonitor())
continue;
/// this is the only value, which is not defined in phx file, so we
/// calculate it
secondaryFlightpath[i] = spDet->getDistance(*sample);
}
}
}
/** method does preliminary calculations of the detectors positions to convert
results into k-dE space ;
and places the results into static cash to be used in subsequent calls to this
algorithm */
void PreprocessDetectorsToMD::processDetectorsPositions(
const API::MatrixWorkspace_const_sptr &inputWS,
DataObjects::TableWorkspace_sptr &targWS) {
g_log.information()
<< "Preprocessing detector locations in a target reciprocal space\n";
//
Geometry::Instrument_const_sptr instrument = inputWS->getInstrument();
// this->pBaseInstr = instrument->baseInstrument();
//
Geometry::IComponent_const_sptr source = instrument->getSource();
Geometry::IComponent_const_sptr sample = instrument->getSample();
if ((!source) || (!sample)) {
g_log.error() << " Instrument is not fully defined. Can not identify "
"source or sample\n";
throw Kernel::Exception::InstrumentDefinitionError(
"Instrument not sufficiently defined: failed to get source and/or "
"sample");
}
// L1
try {
double L1 = source->getDistance(*sample);
targWS->logs()->addProperty<double>("L1", L1, true);
g_log.debug() << "Source-sample distance: " << L1 << std::endl;
} catch (Kernel::Exception::NotFoundError &) {
throw Kernel::Exception::InstrumentDefinitionError(
"Unable to calculate source-sample distance for workspace",
inputWS->getTitle());
}
// Instrument name
std::string InstrName = instrument->getName();
targWS->logs()->addProperty<std::string>(
"InstrumentName", InstrName,
true); // "The name which should unique identify current instrument");
targWS->logs()->addProperty<bool>("FakeDetectors", false, true);
// get access to the workspace memory
auto &sp2detMap = targWS->getColVector<size_t>("spec2detMap");
auto &detId = targWS->getColVector<int32_t>("DetectorID");
auto &detIDMap = targWS->getColVector<size_t>("detIDMap");
auto &L2 = targWS->getColVector<double>("L2");
auto &TwoTheta = targWS->getColVector<double>("TwoTheta");
auto &Azimuthal = targWS->getColVector<double>("Azimuthal");
auto &detDir = targWS->getColVector<Kernel::V3D>("DetDirections");
// Efixed; do we need one and does one exist?
double Efi = targWS->getLogs()->getPropertyValueAsType<double>("Ei");
float *pEfixedArray(nullptr);
const Geometry::ParameterMap &pmap = inputWS->constInstrumentParameters();
if (m_getEFixed)
pEfixedArray = targWS->getColDataArray<float>("eFixed");
// check if one needs to generate masked detectors column.
int *pMasksArray(nullptr);
if (m_getIsMasked)
pMasksArray = targWS->getColDataArray<int>("detMask");
//// progress message appearance
size_t div = 100;
size_t nHist = targWS->rowCount();
Mantid::API::Progress theProgress(this, 0, 1, nHist);
//// Loop over the spectra
uint32_t liveDetectorsCount(0);
for (size_t i = 0; i < nHist; i++) {
sp2detMap[i] = std::numeric_limits<uint64_t>::quiet_NaN();
detId[i] = std::numeric_limits<int32_t>::quiet_NaN();
detIDMap[i] = std::numeric_limits<uint64_t>::quiet_NaN();
L2[i] = std::numeric_limits<double>::quiet_NaN();
TwoTheta[i] = std::numeric_limits<double>::quiet_NaN();
Azimuthal[i] = std::numeric_limits<double>::quiet_NaN();
// detMask[i] = true;
// get detector or detector group which corresponds to the spectra i
Geometry::IDetector_const_sptr spDet;
try {
spDet = inputWS->getDetector(i);
} catch (Kernel::Exception::NotFoundError &) {
continue;
}
// Check that we aren't dealing with monitor...
if (spDet->isMonitor())
continue;
// if masked detectors state is not used, masked detectors just ignored;
bool maskDetector = spDet->isMasked();
if (m_getIsMasked)
*(pMasksArray + liveDetectorsCount) = maskDetector ? 1 : 0;
else if (maskDetector)
continue;
// calculate the requested values;
sp2detMap[i] = liveDetectorsCount;
detId[liveDetectorsCount] = int32_t(spDet->getID());
detIDMap[liveDetectorsCount] = i;
L2[liveDetectorsCount] = spDet->getDistance(*sample);
double polar = inputWS->detectorTwoTheta(spDet);
double azim = spDet->getPhi();
TwoTheta[liveDetectorsCount] = polar;
Azimuthal[liveDetectorsCount] = azim;
double sPhi = sin(polar);
double ez = cos(polar);
double ex = sPhi * cos(azim);
double ey = sPhi * sin(azim);
detDir[liveDetectorsCount].setX(ex);
detDir[liveDetectorsCount].setY(ey);
detDir[liveDetectorsCount].setZ(ez);
// double sinTheta=sin(0.5*polar);
// this->SinThetaSq[liveDetectorsCount] = sinTheta*sinTheta;
// specific code which should work and makes sense
// for indirect instrument but may be deployed on any code with Ei property
// defined;
if (pEfixedArray) {
try {
Geometry::Parameter_sptr par = pmap.getRecursive(spDet.get(), "eFixed");
if (par)
Efi = par->value<double>();
} catch (std::runtime_error &) {
}
// set efixed for each existing detector
*(pEfixedArray + liveDetectorsCount) = static_cast<float>(Efi);
}
liveDetectorsCount++;
if (i % div == 0)
theProgress.report(i, "Preprocessing detectors");
}
targWS->logs()->addProperty<uint32_t>("ActualDetectorsNum",
liveDetectorsCount, true);
theProgress.report();
g_log.information() << "Finished preprocessing detector locations. Found: "
<< liveDetectorsCount << " detectors out of: " << nHist
<< " histograms\n";
}