Esempio n. 1
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/** Method calculates averaged polar coordinates of the detector's group
(which may consist of one detector)
*@param spDet    -- shared pointer to the Mantid Detector
*@param Observer -- sample position or the centre of the polar system of
coordinates to calculate detector's parameters.

*@param Detector  -- return Detector class containing averaged polar coordinates
of the detector or detector's group in
                     spherical coordinate system with centre at Observer
*/
void FindDetectorsPar::calcDetPar(const Geometry::IDetector_const_sptr &spDet,
                                  const Kernel::V3D &Observer,
                                  DetParameters &Detector) {

  // get number of basic detectors within the composit detector
  size_t nDetectors = spDet->nDets();
  // define summator
  AvrgDetector detSum;
  // do we want spherical or linear box sizes?
  detSum.setUseSpherical(!m_SizesAreLinear);

  if (nDetectors == 1) {
    detSum.addDetInfo(spDet, Observer);
  } else {
    // access contributing detectors;
    Geometry::DetectorGroup_const_sptr spDetGroup =
        boost::dynamic_pointer_cast<const Geometry::DetectorGroup>(spDet);
    if (!spDetGroup) {
      g_log.error() << "calc_cylDetPar: can not downcast IDetector_sptr to "
                       "detector group for det->ID: " << spDet->getID()
                    << std::endl;
      throw(std::bad_cast());
    }
    auto detectors = spDetGroup->getDetectors();
    auto it = detectors.begin();
    auto it_end = detectors.end();
    for (; it != it_end; it++) {
      detSum.addDetInfo(*it, Observer);
    }
  }
  // calculate averages and return the detector parameters
  detSum.returnAvrgDetPar(Detector);
}
Esempio n. 2
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  int LoadIsawPeaks::findPixelID(Instrument_const_sptr inst, std::string bankName, int col, int row)
  {
	  boost::shared_ptr<const IComponent> parent = inst->getComponentByName(bankName);
	  if (parent->type().compare("RectangularDetector") == 0)
	  {
          boost::shared_ptr<const RectangularDetector> RDet = boost::dynamic_pointer_cast<
					const RectangularDetector>(parent);

		  boost::shared_ptr<Detector> pixel = RDet->getAtXY(col, row);
		  return pixel->getID();
	  }
	  else
	  {
          std::vector<Geometry::IComponent_const_sptr> children;
          boost::shared_ptr<const Geometry::ICompAssembly> asmb = boost::dynamic_pointer_cast<const Geometry::ICompAssembly>(parent);
          asmb->getChildren(children, false);
          int col0 = (col%2==0 ? col/2+75 : (col-1)/2);
          boost::shared_ptr<const Geometry::ICompAssembly> asmb2 = boost::dynamic_pointer_cast<const Geometry::ICompAssembly>(children[col0]);
          std::vector<Geometry::IComponent_const_sptr> grandchildren;
          asmb2->getChildren(grandchildren,false);
          Geometry::IComponent_const_sptr first = grandchildren[row-1];
          Geometry::IDetector_const_sptr det = boost::dynamic_pointer_cast<const Geometry::IDetector>(first);
		  return det->getID();
	  }
  }
Esempio n. 3
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/** Purpose: Process mask workspace
 *  Requirement: m_maskWS is not None
 *  Guarantees: an array will be set up for masked detectors
 * @brief IntegratePeaksCWSD::processMaskWorkspace
 * @param maskws
 */
std::vector<detid_t> IntegratePeaksCWSD::processMaskWorkspace(
    DataObjects::MaskWorkspace_const_sptr maskws) {
  std::vector<detid_t> vecMaskedDetID;

  // Add the detector IDs of all masked detector to a vector
  size_t numspec = maskws->getNumberHistograms();
  for (size_t iws = 0; iws < numspec; ++iws) {
    Geometry::IDetector_const_sptr detector = maskws->getDetector(iws);
    const MantidVec &vecY = maskws->readY(iws);
    if (vecY[0] > 0.1) {
      // vecY[] > 0 is masked.  det->isMasked() may not be reliable.
      detid_t detid = detector->getID();
      vecMaskedDetID.push_back(detid);
    }
  }

  // Sort the vector for future lookup
  if (vecMaskedDetID.size() > 1)
    std::sort(vecMaskedDetID.begin(), vecMaskedDetID.end());

  g_log.warning() << "[DB] There are " << vecMaskedDetID.size()
                  << " detectors masked."
                  << "\n";

  return vecMaskedDetID;
}
Esempio n. 4
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/** Extract a component's detectors and return it within detectors array
 *  It is a generalized version of bankToDetectors()
 *
 * @param componentnames -- vector of component names to process
 * @param detectors      -- vector of detector ids, which belongs to components
 *provided as input.
 */
void LoadMask::componentToDetectors(
    const std::vector<std::string> &componentnames,
    std::vector<detid_t> &detectors) {
  Geometry::Instrument_const_sptr minstrument = m_maskWS->getInstrument();

  for (auto &componentname : componentnames) {
    g_log.debug() << "Component name = " << componentname << '\n';

    // a) get component
    Geometry::IComponent_const_sptr component =
        minstrument->getComponentByName(componentname);
    if (component)
      g_log.debug() << "Component ID = " << component->getComponentID() << '\n';
    else {
      // A non-exiting component.  Ignore
      g_log.warning() << "Component " << componentname << " does not exist!\n";
      continue;
    }

    // b) component -> component assembly --> children (more than detectors)
    boost::shared_ptr<const Geometry::ICompAssembly> asmb =
        boost::dynamic_pointer_cast<const Geometry::ICompAssembly>(component);
    std::vector<Geometry::IComponent_const_sptr> children;
    asmb->getChildren(children, true);

    g_log.debug() << "Number of Children = " << children.size() << '\n';

    size_t numdets(0);
    detid_t id_min(std::numeric_limits<Mantid::detid_t>::max());
    detid_t id_max(0);

    for (const auto &child : children) {
      // c) convert component to detector
      Geometry::IDetector_const_sptr det =
          boost::dynamic_pointer_cast<const Geometry::IDetector>(child);

      if (det) {
        detid_t detid = det->getID();
        detectors.push_back(detid);
        numdets++;
        if (detid < id_min)
          id_min = detid;
        if (detid > id_max)
          id_max = detid;
      }
    }

    g_log.debug() << "Number of Detectors in Children = " << numdets
                  << "  Range = " << id_min << ", " << id_max << '\n';
  } // for component
}
Esempio n. 5
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/// helper function to preprocess the detectors directions
void 
ConvertToQ3DdE::process_detectors_positions(const DataObjects::Workspace2D_const_sptr inputWS)
{

    const size_t nHist = inputWS->getNumberHistograms();

    det_loc.det_dir.resize(nHist);
    det_loc.det_id.resize(nHist);
     // Loop over the spectra
   size_t ic(0);
   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 dealing with monitor...
    if (spDet->isMonitor())continue;   

     det_loc.det_id[ic] = spDet->getID();
    // dist     =  spDet->getDistance(*sample);
     double polar    =  inputWS->detectorTwoTheta(spDet);
     double azim     =  spDet->getPhi();    

     double sPhi=sin(polar);
     double ez = cos(polar);
     double ex = sPhi*cos(azim);
     double ey = sPhi*sin(azim);
 
     det_loc.det_dir[ic].setX(ex);
     det_loc.det_dir[ic].setY(ey);
     det_loc.det_dir[ic].setZ(ez);

     ic++;
   }
   // 
   if(ic<nHist){
       det_loc.det_dir.resize(ic);
       det_loc.det_id.resize(ic);
   }
}
Esempio n. 6
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std::pair<double, double> LoadILLSANS::calculateQMaxQMin() {
  double min = std::numeric_limits<double>::max(),
         max = std::numeric_limits<double>::min();
  g_log.debug("Calculating Qmin Qmax...");
  std::size_t nHist = m_localWorkspace->getNumberHistograms();
  for (std::size_t i = 0; i < nHist; ++i) {
    Geometry::IDetector_const_sptr det = m_localWorkspace->getDetector(i);
    if (!det->isMonitor()) {
      const MantidVec &lambdaBinning = m_localWorkspace->readX(i);
      Kernel::V3D detPos = det->getPos();
      double r, theta, phi;
      detPos.getSpherical(r, theta, phi);
      double v1 = calculateQ(*(lambdaBinning.begin()), theta);
      double v2 = calculateQ(*(lambdaBinning.end() - 1), theta);
      // std::cout << "i=" << i << " theta="<<theta << " lambda_i=" <<
      // *(lambdaBinning.begin()) << " lambda_f=" << *(lambdaBinning.end()-1) <<
      // " v1=" << v1 << " v2=" << v2 << '\n';
      if (i == 0) {
        min = v1;
        max = v1;
      }
      if (v1 < min) {
        min = v1;
      }
      if (v2 < min) {
        min = v2;
      }
      if (v1 > max) {
        max = v1;
      }
      if (v2 > max) {
        max = v2;
      }
    } else
      g_log.debug() << "Detector " << i << " is a Monitor : " << det->getID()
                    << '\n';
  }

  g_log.debug() << "Calculating Qmin Qmax. Done : [" << min << "," << max
                << "]\n";

  return std::pair<double, double>(min, max);
}
/*
 * Convert Componenet -> Detector IDs -> Workspace Indices -> set group ID
 */
void LoadDetectorsGroupingFile::setByComponents() {

  // 0. Check
  if (!m_instrument) {
    std::map<int, std::vector<std::string>>::iterator mapiter;
    bool norecord = true;
    for (mapiter = m_groupComponentsMap.begin();
         mapiter != m_groupComponentsMap.end(); ++mapiter) {
      if (mapiter->second.size() > 0) {
        g_log.error() << "Instrument is not specified in XML file.  "
                      << "But tag 'component' is used in XML file for Group "
                      << mapiter->first << " It is not allowed" << std::endl;
        norecord = false;
        break;
      }
    }
    if (!norecord)
      throw std::invalid_argument(
          "XML definition involving component causes error");
  }

  // 1. Prepare
  const detid2index_map indexmap =
      m_groupWS->getDetectorIDToWorkspaceIndexMap(true);

  // 2. Set
  for (auto &componentMap : m_groupComponentsMap) {
    g_log.debug() << "Group ID = " << componentMap.first << " With "
                  << componentMap.second.size() << " Components" << std::endl;

    for (auto &name : componentMap.second) {

      // a) get component
      Geometry::IComponent_const_sptr component =
          m_instrument->getComponentByName(name);

      // b) component -> component assembly --> children (more than detectors)
      boost::shared_ptr<const Geometry::ICompAssembly> asmb =
          boost::dynamic_pointer_cast<const Geometry::ICompAssembly>(component);
      std::vector<Geometry::IComponent_const_sptr> children;
      asmb->getChildren(children, true);

      g_log.debug() << "Component Name = " << name
                    << "  Component ID = " << component->getComponentID()
                    << "Number of Children = " << children.size() << std::endl;

      for (auto child : children) {
        // c) convert component to detector
        Geometry::IDetector_const_sptr det =
            boost::dynamic_pointer_cast<const Geometry::IDetector>(child);

        if (det) {
          // Component is DETECTOR:
          int32_t detid = det->getID();
          auto itx = indexmap.find(detid);
          if (itx != indexmap.end()) {
            size_t wsindex = itx->second;
            m_groupWS->dataY(wsindex)[0] = componentMap.first;
          } else {
            g_log.error() << "Pixel w/ ID = " << detid << " Cannot Be Located"
                          << std::endl;
          }
        } // ENDIF Detector

      } // ENDFOR (children of component)
    }   // ENDFOR (component)

  } // ENDFOR GroupID

  return;
}
Esempio n. 8
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/** 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";
}