Пример #1
0
void MantidMatrix::setup(Mantid::API::MatrixWorkspace_const_sptr ws, int start,
                         int end) {
  if (!ws) {
    QMessageBox::critical(0, "WorkspaceMatrixModel error",
                          "2D workspace expected.");
    m_rows = 0;
    m_cols = 0;
    m_startRow = 0;
    m_endRow = 0;
    return;
  }

  m_workspace = ws;
  m_workspaceTotalHist = static_cast<int>(ws->getNumberHistograms());
  m_startRow = (start < 0 || start >= m_workspaceTotalHist) ? 0 : start;
  m_endRow = (end < 0 || end >= m_workspaceTotalHist || end < start)
                 ? m_workspaceTotalHist - 1
                 : end;
  m_rows = m_endRow - m_startRow + 1;
  m_cols = static_cast<int>(ws->blocksize());
  if (ws->isHistogramData())
    m_histogram = true;
  connect(this, SIGNAL(needsUpdating()), this, SLOT(repaintAll()));

  m_bk_color = QColor(128, 255, 255);
  m_matrix_icon = getQPixmap("mantid_matrix_xpm");
  m_column_width = 100;
}
Пример #2
0
void MantidWSIndexDialog::checkForSpectraAxes()
{
  // Check to see if *all* workspaces have a spectrum axis.
  // If even one does not have a spectra axis, then we wont
  // ask the user to enter spectra IDs - only workspace indices.
  QList<QString>::const_iterator it = m_wsNames.constBegin();
  m_spectra = true;

  for ( ; it != m_wsNames.constEnd(); ++it )
  {
    Mantid::API::MatrixWorkspace_const_sptr ws = boost::dynamic_pointer_cast<const Mantid::API::MatrixWorkspace>(Mantid::API::AnalysisDataService::Instance().retrieve((*it).toStdString()));
    if ( NULL == ws ) continue;
    bool hasSpectra = false;
    for(int i = 0; i < ws->axes(); i++)
    {
      if(ws->getAxis(i)->isSpectra()) 
        hasSpectra = true;
    }
    if(hasSpectra == false)
    {
      m_spectra = false;
      break;
    }
  }
}
Пример #3
0
  /**
   * Creates and returns a "mini plot", from the given QwtPlot and QwtPlotCurve objects, as well as the given workspace
   * and workspace index.
   *
   * @param plot      :: the QwtPlot object
   * @param curve     :: the QwtPlotCurve object
   * @param workspace :: the workspace to use
   * @param wsIndex   :: the workspace index
   *
   * @returns the resulting QwtPlotCurve object
   */
  QwtPlotCurve* IDATab::plotMiniplot(QwtPlot* plot, QwtPlotCurve* curve, const std::string & workspace, size_t wsIndex)
  {
    if ( curve != NULL )
    {
      curve->attach(0);
      delete curve;
      curve = 0;
    }

    Mantid::API::MatrixWorkspace_const_sptr ws = boost::dynamic_pointer_cast<Mantid::API::MatrixWorkspace>(Mantid::API::AnalysisDataService::Instance().retrieve(workspace));

    size_t nhist = ws->getNumberHistograms();
    if ( wsIndex >= nhist )
    {
      showInformationBox("Error: Workspace index out of range.");
      return NULL;
    }

    using Mantid::MantidVec;
    const MantidVec & dataX = ws->readX(wsIndex);
    const MantidVec & dataY = ws->readY(wsIndex);

    curve = new QwtPlotCurve();
    curve->setData(&dataX[0], &dataY[0], static_cast<int>(ws->blocksize()));
    curve->attach(plot);

    plot->replot();

    return curve;
  }
Пример #4
0
void MantidWSIndexDialog::generateWsIndexIntervals()
{
  // Get the available interval for each of the workspaces, and then
  // present the user with interval which is the INTERSECTION of each of
  // those intervals.
  QList<QString>::const_iterator it = m_wsNames.constBegin();
  
  // Cycle through the workspaces ...
  for ( ; it != m_wsNames.constEnd(); ++it )
  {
    Mantid::API::MatrixWorkspace_const_sptr ws = boost::dynamic_pointer_cast<const Mantid::API::MatrixWorkspace>(Mantid::API::AnalysisDataService::Instance().retrieve((*it).toStdString()));
    if ( NULL == ws ) continue;
    
    const int endWs = static_cast<int>(ws->getNumberHistograms() - 1);//= static_cast<int> (end->first);

    Interval interval(0,endWs);
    // If no interval has been added yet, just add it ...
    if(it == m_wsNames.constBegin())
      m_wsIndexIntervals.addInterval(interval);
    // ... else set the list as the intersection of what's already there
    // and what has just been added.
    else
      m_wsIndexIntervals.setIntervalList(IntervalList::intersect(m_wsIndexIntervals,interval));
  }
}
Пример #5
0
/**
 * Convert to the output dimensions
 * @param inputWs : Input Matrix workspace
 * @return workspace group containing output matrix workspaces of ki and kf
 */
Mantid::API::MatrixWorkspace_sptr ReflectometryTransform::execute(
    Mantid::API::MatrixWorkspace_const_sptr inputWs) const {
  auto ws = boost::make_shared<Mantid::DataObjects::Workspace2D>();

  ws->initialize(m_d1NumBins, m_d0NumBins,
                 m_d0NumBins); // Create the output workspace as a distribution

  // Mapping so that d0 and d1 values calculated can be added to the matrix
  // workspace at the correct index.
  const double gradD0 =
      double(m_d0NumBins) / (m_d0Max - m_d0Min); // The x - axis
  const double gradD1 =
      double(m_d1NumBins) / (m_d1Max - m_d1Min); // Actually the y-axis
  const double cxToIndex = -gradD0 * m_d0Min;
  const double cyToIndex = -gradD1 * m_d1Min;
  const double cxToD0 = m_d0Min - (1 / gradD0);
  const double cyToD1 = m_d1Min - (1 / gradD1);

  // Create an X - Axis.
  MantidVec xAxisVec = createXAxis(ws.get(), gradD0, cxToD0, m_d0NumBins,
                                   m_d0Label, "1/Angstroms");
  // Create a Y (vertical) Axis
  createVerticalAxis(ws.get(), xAxisVec, gradD1, cyToD1, m_d1NumBins, m_d1Label,
                     "1/Angstroms");

  // Loop over all entries in the input workspace and calculate d0 and d1
  // for each.
  auto spectraAxis = inputWs->getAxis(1);
  for (size_t index = 0; index < inputWs->getNumberHistograms(); ++index) {
    auto counts = inputWs->readY(index);
    auto wavelengths = inputWs->readX(index);
    auto errors = inputWs->readE(index);
    const size_t nInputBins = wavelengths.size() - 1;
    const double theta_final = spectraAxis->getValue(index);
    m_calculator->setThetaFinal(theta_final);
    // Loop over all bins in spectra
    for (size_t binIndex = 0; binIndex < nInputBins; ++binIndex) {
      const double wavelength =
          0.5 * (wavelengths[binIndex] + wavelengths[binIndex + 1]);
      double _d0 = m_calculator->calculateDim0(wavelength);
      double _d1 = m_calculator->calculateDim1(wavelength);

      if (_d0 >= m_d0Min && _d0 <= m_d0Max && _d1 >= m_d1Min &&
          _d1 <= m_d1Max) // Check that the calculated ki and kf are in range
      {
        const int outIndexX = static_cast<int>((gradD0 * _d0) + cxToIndex);
        const int outIndexZ = static_cast<int>((gradD1 * _d1) + cyToIndex);

        ws->dataY(outIndexZ)[outIndexX] += counts[binIndex];
        ws->dataE(outIndexZ)[outIndexX] += errors[binIndex];
      }
    }
  }
  return ws;
}
Пример #6
0
/** function retrieves copy of the oriented lattice from the workspace */
boost::shared_ptr<Geometry::OrientedLattice>
MDWSDescription::getOrientedLattice(
    Mantid::API::MatrixWorkspace_const_sptr inWS2D) {
  // try to get the WS oriented lattice
  boost::shared_ptr<Geometry::OrientedLattice> orl;
  if (inWS2D->sample().hasOrientedLattice())
    orl = boost::shared_ptr<Geometry::OrientedLattice>(
        new Geometry::OrientedLattice(inWS2D->sample().getOrientedLattice()));

  return orl;
}
Пример #7
0
void MantidWSIndexDialog::generateSpectraIdIntervals()
{
  // Get the list of available intervals for each of the workspaces, and then
  // present the user with intervals which are the INTERSECTION of each of
  // those lists of intervals.
  QList<QString>::const_iterator it = m_wsNames.constBegin();
  
  // Cycle through the workspaces ...
  for ( ; it != m_wsNames.constEnd(); ++it )
  {
    Mantid::API::MatrixWorkspace_const_sptr ws = boost::dynamic_pointer_cast<const Mantid::API::MatrixWorkspace>(Mantid::API::AnalysisDataService::Instance().retrieve((*it).toStdString()));
    if ( NULL == ws ) continue;
    Mantid::spec2index_map * spec2index = ws->getSpectrumToWorkspaceIndexMap();
    
    Mantid::spec2index_map::const_iterator last = spec2index->end();
    --last;
    Mantid::spec2index_map::const_iterator first = spec2index->begin();
    
    const int startSpectrum = static_cast<int> (first->first);
    const int endSpectrum = static_cast<int> (last->first);
    const int size = static_cast<int> (spec2index->size());
    if(size == (1 + endSpectrum - startSpectrum))
    {
      // Here we make the assumption (?) that the spectra IDs are sorted, and so
      // are a list of ints from startSpectrum to endSpectrum without any gaps.
      Interval interval(startSpectrum, endSpectrum);
      if(it == m_wsNames.constBegin())
        m_spectraIdIntervals.addInterval(interval);
      else
        m_spectraIdIntervals.setIntervalList(IntervalList::intersect(m_spectraIdIntervals,interval));
    }
    else
    {
      // The spectra IDs do not appear to be an uninterrupted list of numbers,
      // and so we must go through each one and construct the intervals that way.
      // TODO - is this at all feasible for large workspaces, and/or many workspaces?
      ++last;
      for ( ; first != last; ++first) 
      {
        const int spectraId = static_cast<int> (first->first);
        
        Interval interval(spectraId);
        if(it == m_wsNames.constBegin())
          m_spectraIdIntervals.addInterval(interval);
        else
          m_spectraIdIntervals.setIntervalList(IntervalList::intersect(m_spectraIdIntervals,interval));
      }
    }
  }
}
Пример #8
0
void StepScan::fillNormalizationCombobox( const Mantid::API::MatrixWorkspace_const_sptr & ws )
{
  // If there are more than 3 entries in the combobox (nothing, time, proton_charge) then
  // remove any stale ones
  while ( m_uiForm.normalization->count() > 3 )
  {
    m_uiForm.normalization->removeItem(m_uiForm.normalization->count()-1);
  }

  for ( std::size_t i = 0; i < ws->getNumberHistograms(); ++i )
  {
    const std::string monitorName = ws->getDetector(i)->getName();
    m_uiForm.normalization->addItem( QString::fromStdString( monitorName ) );
  }
}
Пример #9
0
/**
 * Sum counts in detectors for purposes of rough plotting against the units on the x-axis.
 * Assumes that all spectra share the x vector.
 *
 * @param dets :: A list of detector IDs to sum.
 * @param x :: (output) Time of flight values (or whatever values the x axis has) to plot against.
 * @param y :: (output) The sums of the counts for each bin.
 */
void InstrumentActor::sumDetectorsUniform(QList<int>& dets, std::vector<double>&x, std::vector<double>&y) const
{

    size_t wi;
    bool isDataEmpty = dets.isEmpty();

    if ( !isDataEmpty )
    {
        try {
            wi = getWorkspaceIndex( dets[0] );
        } catch (Mantid::Kernel::Exception::NotFoundError &) {
            isDataEmpty = true; // Detector doesn't have a workspace index relating to it
        }
    }

    if ( isDataEmpty )
    {
        x.clear();
        y.clear();
        return;
    }

    // find the bins inside the integration range
    size_t imin,imax;
    getBinMinMaxIndex(wi,imin,imax);

    Mantid::API::MatrixWorkspace_const_sptr ws = getWorkspace();
    const Mantid::MantidVec& X = ws->readX(wi);
    x.assign(X.begin() + imin, X.begin() + imax);
    if ( ws->isHistogramData() )
    {
        // calculate the bin centres
        std::transform(x.begin(),x.end(),X.begin() + imin + 1,x.begin(),std::plus<double>());
        std::transform(x.begin(),x.end(),x.begin(),std::bind2nd(std::divides<double>(),2.0));
    }
    y.resize(x.size(),0);
    // sum the spectra
    foreach(int id, dets)
    {
        try {
            size_t index = getWorkspaceIndex( id );
            const Mantid::MantidVec& Y = ws->readY(index);
            std::transform(y.begin(),y.end(),Y.begin() + imin,y.begin(),std::plus<double>());
        } catch (Mantid::Kernel::Exception::NotFoundError &) {
            continue; // Detector doesn't have a workspace index relating to it
        }
    }
}
Пример #10
0
    DataObjects::TableWorkspace_sptr  ConvertToMDParent::runPreprocessDetectorsToMDChildUpdatingMasks(Mantid::API::MatrixWorkspace_const_sptr InWS2D,
      const std::string &OutWSName,const std::string &dEModeRequested,Kernel::DeltaEMode::Type &Emode)
    {
      // prospective result
      DataObjects::TableWorkspace_sptr TargTableWS;

      // if input workspace does not exist in analysis data service, we have to add it there to work with the Child Algorithm 
      std::string InWSName = InWS2D->getName();
      if(!API::AnalysisDataService::Instance().doesExist(InWSName))
      {
        throw std::runtime_error("Can not retrieve input matrix workspace "+InWSName+" from the analysis data service");
      }

      Mantid::API::Algorithm_sptr childAlg = createChildAlgorithm("PreprocessDetectorsToMD",0.,1.);
      if(!childAlg)throw(std::runtime_error("Can not create child ChildAlgorithm to preprocess detectors"));
      childAlg->setProperty("InputWorkspace",InWSName);
      childAlg->setProperty("OutputWorkspace",OutWSName);
      childAlg->setProperty("GetMaskState",true);
      childAlg->setProperty("UpdateMasksInfo",true);
      childAlg->setProperty("OutputWorkspace",OutWSName);

      // check and get energy conversion mode to define additional ChildAlgorithm parameters
      Emode = Kernel::DeltaEMode().fromString(dEModeRequested);
      if(Emode == Kernel::DeltaEMode::Indirect) 
        childAlg->setProperty("GetEFixed",true); 


      childAlg->execute();
      if(!childAlg->isExecuted())throw(std::runtime_error("Can not properly execute child algorithm PreprocessDetectorsToMD"));

      TargTableWS = childAlg->getProperty("OutputWorkspace");
      if(!TargTableWS)throw(std::runtime_error("Can not retrieve results of child algorithm PreprocessDetectorsToMD"));

      return TargTableWS;
    }
Пример #11
0
/** function extracts the coordinates from additional workspace properties and
*places them to proper position within
*  the vector of MD coordinates for the particular workspace.
*
*  @param inWS2D -- input workspace
*  @param dimPropertyNames  -- names of properties which should be treated as
*dimensions
*  @param AddCoord --
*
*  @return AddCoord       -- vector of additional coordinates (derived from WS
*properties) for current multidimensional event
*/
void MDWSDescription::fillAddProperties(
    Mantid::API::MatrixWorkspace_const_sptr inWS2D,
    const std::vector<std::string> &dimPropertyNames,
    std::vector<coord_t> &AddCoord) {
  size_t nDimPropNames = dimPropertyNames.size();
  if (AddCoord.size() != nDimPropNames)
    AddCoord.resize(nDimPropNames);

  for (size_t i = 0; i < nDimPropNames; i++) {
    // HACK: A METHOD, Which converts TSP into value, correspondent to time
    // scale of matrix workspace has to be developed and deployed!
    Kernel::Property *pProperty =
        (inWS2D->run().getProperty(dimPropertyNames[i]));
    Kernel::TimeSeriesProperty<double> *run_property =
        dynamic_cast<Kernel::TimeSeriesProperty<double> *>(pProperty);
    if (run_property) {
      AddCoord[i] = coord_t(run_property->firstValue());
    } else {
      // e.g Ei can be a property and dimension
      Kernel::PropertyWithValue<double> *proc_property =
          dynamic_cast<Kernel::PropertyWithValue<double> *>(pProperty);
      if (!proc_property) {
        std::string ERR =
            " Can not interpret property, used as dimension.\n Property: " +
            dimPropertyNames[i] + " is neither a time series (run) property "
                                  "nor a property with value<double>";
        throw(std::invalid_argument(ERR));
      }
      AddCoord[i] = coord_t(*(proc_property));
    }
  }
}
Пример #12
0
 /// function checks if source workspace still has information about detectors. Some ws (like rebinned one) do not have this information any more. 
 bool PreprocessDetectorsToMD::isDetInfoLost(Mantid::API::MatrixWorkspace_const_sptr inWS2D)const
 {
   auto pYAxis = dynamic_cast<API::NumericAxis *>(inWS2D->getAxis(1));
   // if this is numeric axis, then the detector's information has been lost:
   if(pYAxis)     return true; 
   return false;
 }
Пример #13
0
		/**
		 * Find all of the spectra in the workspace that have width data
		 *
		 * @param ws :: The workspace to search
		 */
		void JumpFit::findAllWidths(Mantid::API::MatrixWorkspace_const_sptr ws)
		{
			m_uiForm.cbWidth->clear();
			m_spectraList.clear();

			for (size_t i = 0; i < ws->getNumberHistograms(); ++i)
			{
				auto axis = dynamic_cast<Mantid::API::TextAxis*>(ws->getAxis(1));
        if(!axis)
          return;

        std::string title = axis->label(i);

				//check if the axis labels indicate this spectrum is width data
				size_t qLinesWidthIndex = title.find(".Width");
				size_t convFitWidthIndex = title.find(".FWHM");

				bool qLinesWidth = qLinesWidthIndex != std::string::npos;
				bool convFitWidth = convFitWidthIndex != std::string::npos;

				//if we get a match, add this spectrum to the combobox
				if(convFitWidth || qLinesWidth)
				{
					std::string cbItemName = "";
					size_t substrIndex = 0;

					if (qLinesWidth)
					{
						substrIndex = qLinesWidthIndex;
					}
					else if (convFitWidth)
					{
						substrIndex = convFitWidthIndex;
					}

					cbItemName = title.substr(0, substrIndex);
					m_spectraList[cbItemName] = static_cast<int>(i);
					m_uiForm.cbWidth->addItem(QString(cbItemName.c_str()));

					//display widths f1.f1, f2.f1 and f2.f2
					if (m_uiForm.cbWidth->count() == 3)
					{
						return;
					}
				}
			}
		}
Пример #14
0
void InstrumentWindowPickTab::getBinMinMaxIndex(size_t wi,size_t& imin, size_t& imax)
{
  InstrumentActor* instrActor = m_instrWindow->getInstrumentActor();
  Mantid::API::MatrixWorkspace_const_sptr ws = instrActor->getWorkspace();
  const Mantid::MantidVec& x = ws->readX(wi);
  if (instrActor->wholeRange())
  {
    imin = 0;
    imax = x.size() - 1;
  }
  else
  {
    Mantid::MantidVec::const_iterator x_begin = std::lower_bound(x.begin(),x.end(),instrActor->minBinValue());
    Mantid::MantidVec::const_iterator x_end = std::lower_bound(x.begin(),x.end(),instrActor->maxBinValue());
    imin = static_cast<size_t>(x_begin - x.begin());
    imax = static_cast<size_t>(x_end - x.begin()) - 1;
  }
}
Пример #15
0
/**
 * Sum counts in detectors for purposes of rough plotting against the units on the x-axis.
 * Checks (approximately) if the workspace is ragged or not and uses the appropriate summation
 * method.
 *
 * @param dets :: A list of detector IDs to sum.
 * @param x :: (output) Time of flight values (or whatever values the x axis has) to plot against.
 * @param y :: (output) The sums of the counts for each bin.
 * @param size :: (optional input) Size of the output vectors. If not given it will be determined automatically.
 */
void InstrumentActor::sumDetectors(QList<int> &dets, std::vector<double> &x, std::vector<double> &y, size_t size) const
{
    Mantid::API::MatrixWorkspace_const_sptr ws = getWorkspace();
    if ( size > ws->blocksize() || size == 0 )
    {
        size = ws->blocksize();
    }

    if ( m_ragged )
    {
        // could be slower than uniform
        sumDetectorsRagged( dets, x, y, size );
    }
    else
    {
        // should be faster than ragged
        sumDetectorsUniform( dets, x, y );
    }
}
Пример #16
0
std::tuple<double, double, double> EnggDiffFittingModel::getDifcDifaTzero(
    Mantid::API::MatrixWorkspace_const_sptr ws) {
  const auto run = ws->run();

  const auto difc = run.getPropertyValueAsType<double>("difc");
  const auto difa = run.getPropertyValueAsType<double>("difa");
  const auto tzero = run.getPropertyValueAsType<double>("tzero");

  return std::tuple<double, double, double>(difc, difa, tzero);
}
Пример #17
0
QMultiMap<QString,std::set<int> > MantidWSIndexDialog::getPlots() const
{
  // Map of workspace names to set of indices to be plotted.
  QMultiMap<QString,std::set<int> > plots;

  // If the user typed in the wsField ...
  if(m_wsIndexChoice.getList().size() > 0)
  {
    
    for(int i = 0; i < m_wsNames.size(); i++)
    {
      std::set<int> intSet = m_wsIndexChoice.getIntSet();
      plots.insert(m_wsNames[i],intSet);
    }
  }
  // Else if the user typed in the spectraField ...
  else if(m_spectraIdChoice.getList().size() > 0)
  {
    for(int i = 0; i < m_wsNames.size(); i++)
    {
      // Convert the spectra choices of the user into workspace indices for us to use.
      Mantid::API::MatrixWorkspace_const_sptr ws = boost::dynamic_pointer_cast<const Mantid::API::MatrixWorkspace>(Mantid::API::AnalysisDataService::Instance().retrieve(m_wsNames[i].toStdString()));
      if ( NULL == ws ) continue;

      Mantid::spec2index_map *spec2index = ws->getSpectrumToWorkspaceIndexMap();

      std::set<int> origSet = m_spectraIdChoice.getIntSet();
      std::set<int>::iterator it = origSet.begin();
      std::set<int> convertedSet;

      for( ; it != origSet.end(); ++it)
      {
        int origInt = (*it);
        int convertedInt = static_cast<int>(spec2index->find(origInt)->second);
        convertedSet.insert(convertedInt);
      }

      plots.insert(m_wsNames[i],convertedSet);
    }
  }

  return plots;
}
Пример #18
0
/**
 * Plot data for a detector.
 * @param detid :: ID of the detector to be plotted.
 */
void InstrumentWindowPickTab::plotSingle(int detid)
{
  m_plot->clearLabels();
  InstrumentActor* instrActor = m_instrWindow->getInstrumentActor();
  Mantid::API::MatrixWorkspace_const_sptr ws = instrActor->getWorkspace();
  size_t wi;
  try {
    wi = instrActor->getWorkspaceIndex(detid);
  } catch (Mantid::Kernel::Exception::NotFoundError) {
    return; // Detector doesn't have a workspace index relating to it
  }
  // get the data
  const Mantid::MantidVec& x = ws->readX(wi);
  const Mantid::MantidVec& y = ws->readY(wi);

  // find min and max for x
  size_t imin,imax;
  getBinMinMaxIndex(wi,imin,imax);

  Mantid::MantidVec::const_iterator y_begin = y.begin() + imin;
  Mantid::MantidVec::const_iterator y_end = y.begin() + imax;

  m_plot->setXScale(x[imin],x[imax]);

  // fins min and max for y
  Mantid::MantidVec::const_iterator min_it = std::min_element(y_begin,y_end);
  Mantid::MantidVec::const_iterator max_it = std::max_element(y_begin,y_end);
  // set the data 
  m_plot->setData(&x[0],&y[0],static_cast<int>(y.size()));
  m_plot->setYScale(*min_it,*max_it);

  // find any markers
  ProjectionSurface* surface = mInstrumentDisplay->getSurface();
  if (surface)
  {
    QList<PeakMarker2D*> markers = surface->getMarkersWithID(detid);
    foreach(PeakMarker2D* marker,markers)
    {
      m_plot->addLabel(new PeakLabel(marker));
      //std::cerr << marker->getLabel().toStdString() << std::endl;
    }
  }
Пример #19
0
/**
 * Find the offsets in the spectrum's x vector of the bounds of integration.
 * @param wi :: The works[ace index of the spectrum.
 * @param imin :: Index of the lower bound: x_min == readX(wi)[imin]
 * @param imax :: Index of the upper bound: x_max == readX(wi)[imax]
 */
void InstrumentActor::getBinMinMaxIndex( size_t wi, size_t& imin, size_t& imax ) const
{
    Mantid::API::MatrixWorkspace_const_sptr ws = getWorkspace();
    const Mantid::MantidVec& x = ws->readX(wi);
    Mantid::MantidVec::const_iterator x_begin = x.begin();
    Mantid::MantidVec::const_iterator x_end = x.end();
    if (x_begin == x_end)
    {
        throw std::runtime_error("No bins found to plot");
    }
    if (ws->isHistogramData())
    {
        --x_end;
    }
    if ( wholeRange() )
    {
        imin = 0;
        imax = static_cast<size_t>(x_end - x_begin);
    }
    else
    {
        Mantid::MantidVec::const_iterator x_from = std::lower_bound( x_begin, x_end, minBinValue() );
        Mantid::MantidVec::const_iterator x_to = std::upper_bound( x_begin, x_end, maxBinValue() );
        imin = static_cast<size_t>(x_from - x_begin);
        imax = static_cast<size_t>(x_to - x_begin);
        if (imax <= imin)
        {
            if (x_from == x_end)
            {
                --x_from;
                x_to = x_end;
            }
            else
            {
                x_to = x_from + 1;
            }
            imin = static_cast<size_t>(x_from - x_begin);
            imax = static_cast<size_t>(x_to - x_begin);
        }
    }
}
Пример #20
0
/**
 * Performs centre-point rebinning and produces an MDWorkspace
 * @param inputWs : The workspace you wish to perform centre-point rebinning on.
 * @param boxController : controls how the MDWorkspace will be split
 * @param frame: the md frame for the two MDHistoDimensions
 * @returns An MDWorkspace based on centre-point rebinning of the inputWS
 */
Mantid::API::IMDEventWorkspace_sptr ReflectometryTransform::executeMD(
    Mantid::API::MatrixWorkspace_const_sptr inputWs,
    BoxController_sptr boxController,
    Mantid::Geometry::MDFrame_uptr frame) const {
  auto dim0 = boost::make_shared<MDHistoDimension>(
      m_d0Label, m_d0ID, *frame, static_cast<Mantid::coord_t>(m_d0Min),
      static_cast<Mantid::coord_t>(m_d0Max), m_d0NumBins);
  auto dim1 = boost::make_shared<MDHistoDimension>(
      m_d1Label, m_d1ID, *frame, static_cast<Mantid::coord_t>(m_d1Min),
      static_cast<Mantid::coord_t>(m_d1Max), m_d1NumBins);

  auto ws = createMDWorkspace(dim0, dim1, boxController);

  auto spectraAxis = inputWs->getAxis(1);
  for (size_t index = 0; index < inputWs->getNumberHistograms(); ++index) {
    auto counts = inputWs->readY(index);
    auto wavelengths = inputWs->readX(index);
    auto errors = inputWs->readE(index);
    const size_t nInputBins = wavelengths.size() - 1;
    const double theta_final = spectraAxis->getValue(index);
    m_calculator->setThetaFinal(theta_final);
    // Loop over all bins in spectra
    for (size_t binIndex = 0; binIndex < nInputBins; ++binIndex) {
      const double &wavelength =
          0.5 * (wavelengths[binIndex] + wavelengths[binIndex + 1]);
      double _d0 = m_calculator->calculateDim0(wavelength);
      double _d1 = m_calculator->calculateDim1(wavelength);
      double centers[2] = {_d0, _d1};

      ws->addEvent(MDLeanEvent<2>(float(counts[binIndex]),
                                  float(errors[binIndex] * errors[binIndex]),
                                  centers));
    }
  }
  ws->splitAllIfNeeded(nullptr);
  ws->refreshCache();
  return ws;
}
Пример #21
0
void Elwin::setDefaultSampleLog(Mantid::API::MatrixWorkspace_const_sptr ws) {
  auto inst = ws->getInstrument();
  // Set sample environment log name
  auto log = inst->getStringParameter("Workflow.SE-log");
  QString logName("sample");
  if (log.size() > 0) {
    logName = QString::fromStdString(log[0]);
  }
  m_uiForm.leLogName->setText(logName);
  // Set sample environment log value
  auto logval = inst->getStringParameter("Workflow.SE-log-value");
  if (logval.size() > 0) {
    auto logValue = QString::fromStdString(logval[0]);
    int index = m_uiForm.leLogValue->findText(logValue);
    if (index >= 0) {
      m_uiForm.leLogValue->setCurrentIndex(index);
    }
  }
}
Пример #22
0
/**
 * Checks the workspace's intrument for a resolution parameter to use as
 * a default for the energy range on the mini plot
 *
 * @param ws :: Pointer to the workspace to use
 * @param res :: The retrieved values for the resolution parameter (if one was
 *found)
 */
bool IndirectTab::getResolutionRangeFromWs(
    Mantid::API::MatrixWorkspace_const_sptr ws, QPair<double, double> &res) {
  auto inst = ws->getInstrument();
  auto analyser = inst->getStringParameter("analyser");

  if (analyser.size() > 0) {
    auto comp = inst->getComponentByName(analyser[0]);
    if (comp) {
      auto params = comp->getNumberParameter("resolution", true);

      // set the default instrument resolution
      if (params.size() > 0) {
        res = qMakePair(-params[0], params[0]);
        return true;
      }
    }
  }

  return false;
}
Пример #23
0
Mantid::API::ITableWorkspace_sptr
EnggDiffFittingModel::createCalibrationParamsTable(
    Mantid::API::MatrixWorkspace_const_sptr inputWS) {
  double difc, difa, tzero;
  std::tie(difc, difa, tzero) = getDifcDifaTzero(inputWS);

  auto calibrationParamsTable =
      Mantid::API::WorkspaceFactory::Instance().createTable();

  calibrationParamsTable->addColumn("int", "detid");
  calibrationParamsTable->addColumn("double", "difc");
  calibrationParamsTable->addColumn("double", "difa");
  calibrationParamsTable->addColumn("double", "tzero");

  Mantid::API::TableRow row = calibrationParamsTable->appendRow();
  const auto &spectrum = inputWS->getSpectrum(0);

  Mantid::detid_t detID = *(spectrum.getDetectorIDs().cbegin());
  row << detID << difc << difa << tzero;
  return calibrationParamsTable;
}
Пример #24
0
  void Elwin::setDefaultResolution(Mantid::API::MatrixWorkspace_const_sptr ws)
  {
    auto inst = ws->getInstrument();
    auto analyser = inst->getStringParameter("analyser");

    if(analyser.size() > 0)
    {
      auto comp = inst->getComponentByName(analyser[0]);
      auto params = comp->getNumberParameter("resolution", true);

      //set the default instrument resolution
      if(params.size() > 0)
      {
        double res = params[0];
        m_dblManager->setValue(m_properties["IntegrationStart"], -res);
        m_dblManager->setValue(m_properties["IntegrationEnd"], res);

        m_dblManager->setValue(m_properties["BackgroundStart"], -10*res);
        m_dblManager->setValue(m_properties["BackgroundEnd"], -9*res);
      }
    }
  }
Пример #25
0
MantidMatrix::MantidMatrix(Mantid::API::MatrixWorkspace_const_sptr ws,
                           QWidget *parent, const QString &label,
                           const QString &name, int start, int end)
    : MdiSubWindow(parent, label, name, 0), WorkspaceObserver(),
      m_workspace(ws), y_start(0.0), y_end(0.0), m_histogram(false), m_min(0),
      m_max(0), m_are_min_max_set(false), m_boundingRect(),
      m_strName(name.toStdString()), m_selectedRows(), m_selectedCols() {
  m_workspace = ws;

  setup(ws, start, end);
  setWindowTitle(name);
  setName(name);

  m_modelY = new MantidMatrixModel(this, ws.get(), m_rows, m_cols, m_startRow,
                                   MantidMatrixModel::Y);
  m_table_viewY = new QTableView();
  connectTableView(m_table_viewY, m_modelY);
  setColumnsWidth(0, MantidPreferences::MantidMatrixColumnWidthY());
  setNumberFormat(0, MantidPreferences::MantidMatrixNumberFormatY(),
                  MantidPreferences::MantidMatrixNumberPrecisionY());

  m_modelX = new MantidMatrixModel(this, ws.get(), m_rows, m_cols, m_startRow,
                                   MantidMatrixModel::X);
  m_table_viewX = new QTableView();
  connectTableView(m_table_viewX, m_modelX);
  setColumnsWidth(1, MantidPreferences::MantidMatrixColumnWidthX());
  setNumberFormat(1, MantidPreferences::MantidMatrixNumberFormatX(),
                  MantidPreferences::MantidMatrixNumberPrecisionX());

  m_modelE = new MantidMatrixModel(this, ws.get(), m_rows, m_cols, m_startRow,
                                   MantidMatrixModel::E);
  m_table_viewE = new QTableView();
  connectTableView(m_table_viewE, m_modelE);
  setColumnsWidth(2, MantidPreferences::MantidMatrixColumnWidthE());
  setNumberFormat(2, MantidPreferences::MantidMatrixNumberFormatE(),
                  MantidPreferences::MantidMatrixNumberPrecisionE());

  m_YTabLabel = QString("Y values");
  m_XTabLabel = QString("X values");
  m_ETabLabel = QString("Errors");

  m_tabs = new QTabWidget(this);
  m_tabs->insertTab(0, m_table_viewY, m_YTabLabel);
  m_tabs->insertTab(1, m_table_viewX, m_XTabLabel);
  m_tabs->insertTab(2, m_table_viewE, m_ETabLabel);

  setWidget(m_tabs);
  // for synchronizing the views
  // index is zero for the defualt view
  m_PrevIndex = 0;
  // install event filter on  these objects
  m_table_viewY->installEventFilter(this);
  m_table_viewX->installEventFilter(this);
  m_table_viewE->installEventFilter(this);

  connect(m_tabs, SIGNAL(currentChanged(int)), this, SLOT(viewChanged(int)));

  setGeometry(50, 50,
              qMin(5, numCols()) *
                      m_table_viewY->horizontalHeader()->sectionSize(0) +
                  55,
              (qMin(10, numRows()) + 1) *
                      m_table_viewY->verticalHeader()->sectionSize(0) +
                  100);

  // Add an extension for the DX component if required
  if (ws->hasDx(0)) {
    addMantidMatrixTabExtension(MantidMatrixModel::DX);
  }

  observeAfterReplace();
  observePreDelete();
  observeADSClear();

  connect(this, SIGNAL(needWorkspaceChange(Mantid::API::MatrixWorkspace_sptr)),
          this, SLOT(changeWorkspace(Mantid::API::MatrixWorkspace_sptr)));
  connect(this, SIGNAL(needToClose()), this, SLOT(closeMatrix()));

  connect(this, SIGNAL(closedWindow(MdiSubWindow *)), this,
          SLOT(selfClosed(MdiSubWindow *)));

  confirmClose(false);
}
Пример #26
0
/**
 *  @param g :: The Graph widget which will display the curve
 *  @param distr :: True for a distribution
 *  @param style :: The curve type to use
 */
void MantidMatrixCurve::init(Graph *g, bool distr,
                             GraphOptions::CurveType style) {
  // Will throw if name not found but return NULL ptr if the type is incorrect
  MatrixWorkspace_const_sptr workspace =
      AnalysisDataService::Instance().retrieveWS<MatrixWorkspace>(
          m_wsName.toStdString());

  if (!workspace) // The respective *Data classes will check for index validity
  {
    std::stringstream ss;
    ss << "Workspace named '" << m_wsName.toStdString()
       << "' found but it is not a MatrixWorkspace. ID='"
       << AnalysisDataService::Instance().retrieve(m_wsName.toStdString())->id()
       << "'";
    throw std::invalid_argument(ss.str());
  }

  // Set the curve name if it the non-naming constructor was called
  if (this->title().isEmpty()) {
    // If there's only one spectrum in the workspace, title is simply workspace
    // name
    if (workspace->getNumberHistograms() == 1)
      this->setTitle(m_wsName);
    else
      this->setTitle(createCurveName(workspace));
  }

  Mantid::API::MatrixWorkspace_const_sptr matrixWS =
      boost::dynamic_pointer_cast<const Mantid::API::MatrixWorkspace>(
          workspace);
  // we need to censor the data if there is a log scale because it can't deal
  // with negative values, only the y-axis has been found to be problem so far
  const bool log = g->isLog(QwtPlot::yLeft);

  // Y units are the same for both spectrum and bin plots, e.g. counts
  m_yUnits.reset(new Mantid::Kernel::Units::Label(matrixWS->YUnit(),
                                                  matrixWS->YUnitLabel()));

  if (m_indexType == Spectrum) // Spectrum plot
  {
    QwtWorkspaceSpectrumData data(*matrixWS, m_index, log, distr);

    setData(data);

    // For spectrum plots, X axis are actual X axis, e.g. TOF
    m_xUnits = matrixWS->getAxis(0)->unit();
  } else // Bin plot
  {
    QwtWorkspaceBinData data(*matrixWS, m_index, log);

    setData(data);

    // For bin plots, X axis are "spectra axis", e.g. spectra numbers
    m_xUnits = matrixWS->getAxis(1)->unit();
  }

  if (!m_xUnits) {
    m_xUnits.reset(new Mantid::Kernel::Units::Empty());
  }

  int lineWidth = 1;
  MultiLayer *ml = dynamic_cast<MultiLayer *>(g->parent()->parent()->parent());
  if (ml && (style == GraphOptions::Unspecified ||
             ml->applicationWindow()->applyCurveStyleToMantid)) {
    applyStyleChoice(style, ml, lineWidth);
  } else if (matrixWS->isHistogramData() && !matrixWS->isDistribution()) {
    setStyle(QwtPlotCurve::Steps);
    setCurveAttribute(
        Inverted,
        true); // this is the Steps style modifier that makes horizontal steps
  } else {
    setStyle(QwtPlotCurve::Lines);
  }
  g->insertCurve(this, lineWidth);

  // set the option to draw all error bars from the global settings
  if (hasErrorBars()) {
    setErrorBars(true, g->multiLayer()->applicationWindow()->drawAllErrors);
  }
  // Initialise error bar colour to match curve colour
  m_errorSettings->m_color = pen().color();
  m_errorSettings->setWidth(pen().widthF());

  connect(g, SIGNAL(axisScaleChanged(int, bool)), this,
          SLOT(axisScaleChanged(int, bool)));
  observePostDelete();
  connect(this, SIGNAL(resetData(const QString &)), this,
          SLOT(dataReset(const QString &)));
  observeAfterReplace();
  observeADSClear();
}
Пример #27
0
    /**The method responsible for analyzing input workspace parameters and preprocessing detectors positions into reciprocal space
    *
    * @param InWS2D -- input Matrix workspace with defined instrument
    * @param dEModeRequested -- energy conversion mode (direct/indirect/elastic)
    * @param updateMasks  --  if full detector positions calculations or just update masking requested
    * @param OutWSName    -- the name for the preprocessed detectors workspace to have in the analysis data service
    * 
    * @return          shared pointer to the workspace with preprocessed detectors information. 
    */
    DataObjects::TableWorkspace_const_sptr ConvertToMDParent::preprocessDetectorsPositions( Mantid::API::MatrixWorkspace_const_sptr InWS2D,const std::string &dEModeRequested,
      bool updateMasks, const std::string & OutWSName)
    {

      DataObjects::TableWorkspace_sptr TargTableWS;
      Kernel::DeltaEMode::Type Emode;

      // Do we need to reuse output workspace
      bool storeInDataService(true);
      std::string tOutWSName(OutWSName);
      if(tOutWSName=="-"||tOutWSName.empty()) // TargTableWS is recalculated each time;
      {
        storeInDataService = false;
        tOutWSName = "ServiceTableWS";  // TODO: should be hidden?
      }
      else
      {
        storeInDataService = true;
      }

      // if output workspace exists in dataservice, we may try to use it
      if(storeInDataService && API::AnalysisDataService::Instance().doesExist(tOutWSName) ) 
      {
        TargTableWS = API::AnalysisDataService::Instance().retrieveWS<DataObjects::TableWorkspace>(tOutWSName);
        // get number of all histograms (may be masked or invalid)
        size_t nHist = InWS2D->getNumberHistograms();
        size_t nDetMap=TargTableWS->rowCount();
        if(nHist==nDetMap)
        {
          // let's take at least some precaution to ensure that instrument have not changed
          std::string currentWSInstrumentName = InWS2D->getInstrument()->getName();
          std::string oldInstrName            = TargTableWS->getLogs()->getPropertyValueAsType<std::string>("InstrumentName");

          if(oldInstrName==currentWSInstrumentName)
          { 
            if(!updateMasks) return TargTableWS;
            //Target workspace with preprocessed detectors exists and seems is correct one. 
            // We still need to update masked detectors information
            TargTableWS = this->runPreprocessDetectorsToMDChildUpdatingMasks(InWS2D,tOutWSName,dEModeRequested,Emode);
            return TargTableWS;
          }
        }
        else // there is a workspace in the data service with the same name but this ws is not suitable as target for this algorithm. 
        {    // Should delete this WS from the dataservice
          API::AnalysisDataService::Instance().remove(tOutWSName);
        }
      }
      // No result found in analysis data service or the result is unsatisfactory. Try to calculate target workspace.  

      TargTableWS =this->runPreprocessDetectorsToMDChildUpdatingMasks(InWS2D,tOutWSName,dEModeRequested,Emode);

      if(storeInDataService)
        API::AnalysisDataService::Instance().addOrReplace(tOutWSName,TargTableWS);
      //    else
      //      TargTableWS->setName(OutWSName);


      // check if we got what we wanted:

      // in direct or indirect mode input ws has to have input energy
      if(Emode==Kernel::DeltaEMode::Direct||Emode==Kernel::DeltaEMode::Indirect)
      {
        double   m_Ei  = TargTableWS->getLogs()->getPropertyValueAsType<double>("Ei");
        if(isNaN(m_Ei))
        {
          // Direct mode needs Ei
          if(Emode==Kernel::DeltaEMode::Direct)throw(std::invalid_argument("Input neutron's energy has to be defined in inelastic mode "));

          // Do we have at least something for Indirect?
          float *eFixed = TargTableWS->getColDataArray<float>("eFixed");
          if(!eFixed)
            throw(std::invalid_argument("Input neutron's energy has to be defined in inelastic mode "));

          uint32_t NDetectors = TargTableWS->getLogs()->getPropertyValueAsType<uint32_t>("ActualDetectorsNum");
          for(uint32_t i=0;i<NDetectors;i++)
            if(isNaN(*(eFixed+i)))throw(std::invalid_argument("Undefined eFixed energy for detector N: "+boost::lexical_cast<std::string>(i)));
        }
      }

      return TargTableWS;
    }
Пример #28
0
/**
 * Sum counts in detectors for purposes of rough plotting against the units on the x-axis.
 * Assumes that all spectra have different x vectors.
 *
 * @param dets :: A list of detector IDs to sum.
 * @param x :: (output) Time of flight values (or whatever values the x axis has) to plot against.
 * @param y :: (output) The sums of the counts for each bin.
 * @param size :: (input) Size of the output vectors.
 */
void InstrumentActor::sumDetectorsRagged(QList<int> &dets, std::vector<double> &x, std::vector<double> &y, size_t size) const
{
    if ( dets.isEmpty() || size == 0 )
    {
        x.clear();
        y.clear();
        return;
    }

    Mantid::API::MatrixWorkspace_const_sptr ws = getWorkspace();
    //  create a workspace to hold the data from the selected detectors
    Mantid::API::MatrixWorkspace_sptr dws = Mantid::API::WorkspaceFactory::Instance().create(ws,dets.size());

    // x-axis limits
    double xStart = maxBinValue();
    double xEnd = minBinValue();

    size_t nSpec = 0; // number of actual spectra to add
    // fill in the temp workspace with the data from the detectors
    foreach(int id, dets)
    {
        try {
            size_t index = getWorkspaceIndex( id );
            dws->dataX(nSpec) = ws->readX(index);
            dws->dataY(nSpec) = ws->readY(index);
            dws->dataE(nSpec) = ws->readE(index);
            double xmin = dws->readX(nSpec).front();
            double xmax = dws->readX(nSpec).back();
            if ( xmin < xStart )
            {
                xStart = xmin;
            }
            if ( xmax > xEnd )
            {
                xEnd = xmax;
            }
            ++nSpec;
        } catch (Mantid::Kernel::Exception::NotFoundError &) {
            continue; // Detector doesn't have a workspace index relating to it
        }
    }

    if ( nSpec == 0 )
    {
        x.clear();
        y.clear();
        return;
    }

    // limits should exceed the integration range
    if ( xStart < minBinValue() )
    {
        xStart = minBinValue();
    }

    if ( xEnd > maxBinValue() )
    {
        xEnd = maxBinValue();
    }

    double dx = (xEnd - xStart) / static_cast<double>(size - 1);
    std::string params = QString("%1,%2,%3").arg(xStart).arg(dx).arg(xEnd).toStdString();
    std::string outName = "_TMP_sumDetectorsRagged";

    try
    {
        // rebin all spectra to the same binning
        Mantid::API::IAlgorithm * alg = Mantid::API::FrameworkManager::Instance().createAlgorithm("Rebin",-1);
        alg->setProperty( "InputWorkspace", dws );
        alg->setPropertyValue( "OutputWorkspace", outName );
        alg->setPropertyValue( "Params", params );
        alg->execute();

        ws = boost::dynamic_pointer_cast<Mantid::API::MatrixWorkspace>(Mantid::API::AnalysisDataService::Instance().retrieve(outName));
        Mantid::API::AnalysisDataService::Instance().remove( outName );

        x = ws->readX(0);
        y = ws->readY(0);
        // add the spectra
        for(size_t i = 0; i < nSpec; ++i)
        {
            const Mantid::MantidVec& Y = ws->readY(i);
            std::transform( y.begin(), y.end(), Y.begin(), y.begin(), std::plus<double>() );
        }
    }
    catch(std::invalid_argument&)
    {
        // wrong Params for any reason
        x.resize(size,(xEnd + xStart)/2);
        y.resize(size,0.0);
    }

}