bool IMDDimensionComparitor::isXDimension(
    const Mantid::Geometry::IMDDimension &queryDimension) {
  // Compare dimensions on the basis of their ids.
  Mantid::Geometry::IMDDimension_const_sptr actualXDimension =
      m_workspace->getXDimension();
  return queryDimension.getDimensionId() == actualXDimension->getDimensionId();
}
bool IMDDimensionComparitor::istDimension(
    const Mantid::Geometry::IMDDimension &queryDimension) {
  Mantid::Geometry::IMDDimension_const_sptr actualtDimension =
      m_workspace->getTDimension();
  if (actualtDimension) {
    // Compare dimensions on the basis of their ids.
    return queryDimension.getDimensionId() ==
           actualtDimension->getDimensionId();
  } else {
    return false; // MDImages may have 1 dimension or more.
  }
}
示例#3
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/** Set the labels for the Y dimensions
 * @param dim : IMDDimension */
void XYLimitsDialog::setYDim(Mantid::Geometry::IMDDimension_const_sptr dim)
{
  ui.lblYName->setText( QString::fromStdString(dim->getName()) );
  ui.lblYUnits->setText( QString::fromStdString(dim->getUnits()) );
}
示例#4
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//----------------------------------------------------------------------------------------------
/// Run the algorithm
void QueryMDWorkspace::exec() {
    // Extract the required normalisation.
    std::string strNormalisation = getPropertyValue("Normalisation");
    MDNormalization requestedNormalisation = whichNormalisation(strNormalisation);

    IMDWorkspace_sptr input = getProperty("InputWorkspace");

    const bool transformCoordsToOriginal = getProperty("TransformCoordsToOriginal");

    // Define a table workspace with a specific column schema.
    ITableWorkspace_sptr output = WorkspaceFactory::Instance().createTable();
    const std::string signalColumnName = "Signal/" + strNormalisation;
    const std::string errorColumnName = "Error/" + strNormalisation;
    output->addColumn("double", signalColumnName);
    output->addColumn("double", errorColumnName);
    output->addColumn("int", "Number of Events");

    const size_t ndims = input->getNumDims();
    for (size_t index = 0; index < ndims; ++index) {
        Mantid::Geometry::IMDDimension_const_sptr dim = input->getDimension(index);
        std::string dimInUnit = dim->getName() + "/" + dim->getUnits().ascii();
        output->addColumn("double", dimInUnit);
        // Magic numbers required to configure the X axis.
        output->getColumn(dimInUnit)->setPlotType(1);
    }

    // Magic numbers required to configure the Y axis.
    output->getColumn(signalColumnName)->setPlotType(2);
    output->getColumn(errorColumnName)->setPlotType(5);

    IMDIterator *it = input->createIterator();
    it->setNormalization(requestedNormalisation);

    bool bLimitRows = getProperty("LimitRows");
    int maxRows = 0;
    if (bLimitRows) {
        maxRows = getProperty("MaximumRows");
    }

    // Use the iterator to loop through each MDBoxBase and create a row for each
    // entry.
    int rowCounter = 0;

    Progress progress(this, 0, 1, int64_t(input->getNPoints()));
    while (true) {
        size_t cellIndex = 0;
        output->appendRow();
        output->cell<double>(rowCounter, cellIndex++) = it->getNormalizedSignal();
        output->cell<double>(rowCounter, cellIndex++) = it->getNormalizedError();
        output->cell<int>(rowCounter, cellIndex++) = int(it->getNumEvents());
        VMD center = it->getCenter();
        const size_t numberOriginal = input->getNumberTransformsToOriginal();
        if (transformCoordsToOriginal && numberOriginal > 0) {
            const size_t index = numberOriginal - 1;
            CoordTransform const *transform = input->getTransformToOriginal(index);
            VMD temp = transform->applyVMD(center);
            center = temp;
        }

        for (size_t index = 0; index < ndims; ++index) {
            output->cell<double>(rowCounter, cellIndex++) = center[index];
        }

        progress.report();
        if (!it->next() || (bLimitRows && ((rowCounter + 1) >= maxRows))) {
            break;
        }
        rowCounter++;
    }
    setProperty("OutputWorkspace", output);
    delete it;

    //
    IMDEventWorkspace_sptr mdew;
    CALL_MDEVENT_FUNCTION(this->getBoxData, input);
}
/**
  * Make 1D MatrixWorkspace
  */
void ConvertMDHistoToMatrixWorkspace::make1DWorkspace() {
  IMDHistoWorkspace_sptr inputWorkspace = getProperty("InputWorkspace");

  // This code is copied from MantidQwtIMDWorkspaceData
  Mantid::Geometry::VecIMDDimension_const_sptr nonIntegDims =
      inputWorkspace->getNonIntegratedDimensions();

  std::string alongDim = "";
  if (!nonIntegDims.empty())
    alongDim = nonIntegDims[0]->getDimensionId();
  else
    alongDim = inputWorkspace->getDimension(0)->getDimensionId();

  size_t nd = inputWorkspace->getNumDims();
  Mantid::Kernel::VMD start = VMD(nd);
  Mantid::Kernel::VMD end = VMD(nd);

  size_t id = 0;
  for (size_t d = 0; d < nd; d++) {
    Mantid::Geometry::IMDDimension_const_sptr dim =
        inputWorkspace->getDimension(d);
    if (dim->getDimensionId() == alongDim) {
      // All the way through in the single dimension
      start[d] = dim->getMinimum();
      end[d] = dim->getMaximum();
      id = d; // We take the first non integrated dimension to be the diemnsion
              // of interest.
    } else {
      // Mid point along each dimension
      start[d] = (dim->getMaximum() + dim->getMinimum()) / 2.0f;
      end[d] = start[d];
    }
  }

  // Unit direction of the line
  Mantid::Kernel::VMD dir = end - start;
  dir.normalize();

  std::string normProp = getPropertyValue("Normalization");

  Mantid::API::MDNormalization normalization;
  if (normProp == "NoNormalization") {
    normalization = NoNormalization;
  } else if (normProp == "VolumeNormalization") {
    normalization = VolumeNormalization;
  } else if (normProp == "NumEventsNormalization") {
    normalization = NumEventsNormalization;
  } else {
    normalization = NoNormalization;
  }

  auto line = inputWorkspace->getLineData(start, end, normalization);

  MatrixWorkspace_sptr outputWorkspace = WorkspaceFactory::Instance().create(
      "Workspace2D", 1, line.x.size(), line.y.size());
  outputWorkspace->dataY(0).assign(line.y.begin(), line.y.end());
  outputWorkspace->dataE(0).assign(line.e.begin(), line.e.end());

  const size_t numberTransformsToOriginal =
      inputWorkspace->getNumberTransformsToOriginal();

  CoordTransform_const_sptr transform =
      boost::make_shared<NullCoordTransform>(inputWorkspace->getNumDims());
  if (numberTransformsToOriginal > 0) {
    const size_t indexToLastTransform = numberTransformsToOriginal - 1;
    transform = CoordTransform_const_sptr(
        inputWorkspace->getTransformToOriginal(indexToLastTransform),
        NullDeleter());
  }

  assert(line.x.size() == outputWorkspace->dataX(0).size());

  std::string xAxisLabel = inputWorkspace->getDimension(id)->getName();
  const bool autoFind = this->getProperty("FindXAxis");
  if (autoFind) {
    // We look to the original workspace if possbible to find the dimension of
    // interest to plot against.
    id = findXAxis(start, end, transform.get(), inputWorkspace.get(), g_log, id,
                   xAxisLabel);
  }

  for (size_t i = 0; i < line.x.size(); ++i) {
    // Coordinates in the workspace being plotted
    VMD wsCoord = start + dir * line.x[i];

    VMD inTargetCoord = transform->applyVMD(wsCoord);
    outputWorkspace->dataX(0)[i] = inTargetCoord[id];
  }

  boost::shared_ptr<Kernel::Units::Label> labelX =
      boost::dynamic_pointer_cast<Kernel::Units::Label>(
          Kernel::UnitFactory::Instance().create("Label"));
  labelX->setLabel(xAxisLabel);
  outputWorkspace->getAxis(0)->unit() = labelX;

  outputWorkspace->setYUnitLabel("Signal");

  setProperty("OutputWorkspace", outputWorkspace);
}
示例#6
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/** Set the labels for the X dimensions
 * @param dim : IMDDimension */
void XYLimitsDialog::setXDim(Mantid::Geometry::IMDDimension_const_sptr dim) {
  ui.lblXName->setText(QString::fromStdString(dim->getName()));
  ui.lblXUnits->setText(toQStringInternal(dim->getUnits().utf8()));
}