Пример #1
0
/**
 * This function handles the logic for summing RebinnedOutput workspaces.
 * @param outputWorkspace the workspace to hold the summed input
 * @param progress the progress indicator
 * @param numSpectra
 * @param numMasked
 * @param numZeros
 */
void SumSpectra::doRebinnedOutput(MatrixWorkspace_sptr outputWorkspace,
                                  Progress &progress, size_t &numSpectra,
                                  size_t &numMasked, size_t &numZeros) {
  // Get a copy of the input workspace
  MatrixWorkspace_sptr temp = getProperty("InputWorkspace");

  // First, we need to clean the input workspace for nan's and inf's in order
  // to treat the data correctly later. This will create a new private
  // workspace that will be retrieved as mutable.
  IAlgorithm_sptr alg = this->createChildAlgorithm("ReplaceSpecialValues");
  alg->setProperty<MatrixWorkspace_sptr>("InputWorkspace", temp);
  std::string outName = "_" + temp->getName() + "_clean";
  alg->setProperty("OutputWorkspace", outName);
  alg->setProperty("NaNValue", 0.0);
  alg->setProperty("NaNError", 0.0);
  alg->setProperty("InfinityValue", 0.0);
  alg->setProperty("InfinityError", 0.0);
  alg->executeAsChildAlg();
  MatrixWorkspace_sptr localworkspace = alg->getProperty("OutputWorkspace");

  // Transform to real workspace types
  RebinnedOutput_sptr inWS =
      boost::dynamic_pointer_cast<RebinnedOutput>(localworkspace);
  RebinnedOutput_sptr outWS =
      boost::dynamic_pointer_cast<RebinnedOutput>(outputWorkspace);

  // Get references to the output workspaces's data vectors
  ISpectrum *outSpec = outputWorkspace->getSpectrum(0);
  MantidVec &YSum = outSpec->dataY();
  MantidVec &YError = outSpec->dataE();
  MantidVec &FracSum = outWS->dataF(0);
  MantidVec Weight;
  std::vector<size_t> nZeros;
  if (m_calculateWeightedSum) {
    Weight.assign(YSum.size(), 0);
    nZeros.assign(YSum.size(), 0);
  }
  numSpectra = 0;
  numMasked = 0;
  numZeros = 0;

  // Loop over spectra
  std::set<int>::iterator it;
  // for (int i = m_minSpec; i <= m_maxSpec; ++i)
  for (it = m_indices.begin(); it != m_indices.end(); ++it) {
    int i = *it;
    // Don't go outside the range.
    if ((i >= m_numberOfSpectra) || (i < 0)) {
      g_log.error() << "Invalid index " << i
                    << " was specified. Sum was aborted.\n";
      break;
    }

    try {
      // Get the detector object for this spectrum
      Geometry::IDetector_const_sptr det = localworkspace->getDetector(i);
      // Skip monitors, if the property is set to do so
      if (!m_keepMonitors && det->isMonitor())
        continue;
      // Skip masked detectors
      if (det->isMasked()) {
        numMasked++;
        continue;
      }
    } catch (...) {
      // if the detector not found just carry on
    }
    numSpectra++;

    // Retrieve the spectrum into a vector
    const MantidVec &YValues = localworkspace->readY(i);
    const MantidVec &YErrors = localworkspace->readE(i);
    const MantidVec &FracArea = inWS->readF(i);

    if (m_calculateWeightedSum) {
      for (int k = 0; k < this->m_yLength; ++k) {
        if (YErrors[k] != 0) {
          double errsq = YErrors[k] * YErrors[k] * FracArea[k] * FracArea[k];
          YError[k] += errsq;
          Weight[k] += 1. / errsq;
          YSum[k] += YValues[k] * FracArea[k] / errsq;
          FracSum[k] += FracArea[k];
        } else {
          nZeros[k]++;
          FracSum[k] += FracArea[k];
        }
      }
    } else {
      for (int k = 0; k < this->m_yLength; ++k) {
        YSum[k] += YValues[k] * FracArea[k];
        YError[k] += YErrors[k] * YErrors[k] * FracArea[k] * FracArea[k];
        FracSum[k] += FracArea[k];
      }
    }

    // Map all the detectors onto the spectrum of the output
    outSpec->addDetectorIDs(localworkspace->getSpectrum(i)->getDetectorIDs());

    progress.report();
  }

  if (m_calculateWeightedSum) {
    numZeros = 0;
    for (size_t i = 0; i < Weight.size(); i++) {
      if (nZeros[i] == 0)
        YSum[i] *= double(numSpectra) / Weight[i];
      else
        numZeros += nZeros[i];
    }
  }

  // Create the correct representation
  outWS->finalize();
}
Пример #2
0
/**
 * This function deals with the logic necessary for summing a Workspace2D.
 * @param localworkspace The input workspace for summing.
 * @param outSpec The spectrum for the summed output.
 * @param progress The progress indicator.
 * @param numSpectra The number of spectra contributed to the sum.
 * @param numMasked The spectra dropped from the summations because they are
 * masked.
 * @param numZeros The number of zero bins in histogram workspace or empty
 * spectra for event workspace.
 */
void SumSpectra::doWorkspace2D(MatrixWorkspace_const_sptr localworkspace,
                               ISpectrum *outSpec, Progress &progress,
                               size_t &numSpectra, size_t &numMasked,
                               size_t &numZeros) {
  // Get references to the output workspaces's data vectors
  MantidVec &YSum = outSpec->dataY();
  MantidVec &YError = outSpec->dataE();

  MantidVec Weight;
  std::vector<size_t> nZeros;
  if (m_calculateWeightedSum) {
    Weight.assign(YSum.size(), 0);
    nZeros.assign(YSum.size(), 0);
  }
  numSpectra = 0;
  numMasked = 0;
  numZeros = 0;

  // Loop over spectra
  std::set<int>::iterator it;
  // for (int i = m_minSpec; i <= m_maxSpec; ++i)
  for (it = this->m_indices.begin(); it != this->m_indices.end(); ++it) {
    int i = *it;
    // Don't go outside the range.
    if ((i >= this->m_numberOfSpectra) || (i < 0)) {
      g_log.error() << "Invalid index " << i
                    << " was specified. Sum was aborted.\n";
      break;
    }

    try {
      // Get the detector object for this spectrum
      Geometry::IDetector_const_sptr det = localworkspace->getDetector(i);
      // Skip monitors, if the property is set to do so
      if (!m_keepMonitors && det->isMonitor())
        continue;
      // Skip masked detectors
      if (det->isMasked()) {
        numMasked++;
        continue;
      }
    } catch (...) {
      // if the detector not found just carry on
    }
    numSpectra++;

    // Retrieve the spectrum into a vector
    const MantidVec &YValues = localworkspace->readY(i);
    const MantidVec &YErrors = localworkspace->readE(i);
    if (m_calculateWeightedSum) {
      for (int k = 0; k < this->m_yLength; ++k) {
        if (YErrors[k] != 0) {
          double errsq = YErrors[k] * YErrors[k];
          YError[k] += errsq;
          Weight[k] += 1. / errsq;
          YSum[k] += YValues[k] / errsq;
        } else {
          nZeros[k]++;
        }
      }
    } else {
      for (int k = 0; k < this->m_yLength; ++k) {
        YSum[k] += YValues[k];
        YError[k] += YErrors[k] * YErrors[k];
      }
    }

    // Map all the detectors onto the spectrum of the output
    outSpec->addDetectorIDs(localworkspace->getSpectrum(i)->getDetectorIDs());

    progress.report();
  }

  if (m_calculateWeightedSum) {
    numZeros = 0;
    for (size_t i = 0; i < Weight.size(); i++) {
      if (nZeros[i] == 0)
        YSum[i] *= double(numSpectra) / Weight[i];
      else
        numZeros += nZeros[i];
    }
  }
}