Beispiel #1
0
/**
* Run instead of exec when operating on groups
*/
bool SaveNXTomo::processGroups() {
  try {
    std::string name = getPropertyValue("InputWorkspaces");
    WorkspaceGroup_sptr groupWS =
        AnalysisDataService::Instance().retrieveWS<WorkspaceGroup>(name);

    for (int i = 0; i < groupWS->getNumberOfEntries(); ++i) {
      m_workspaces.push_back(
          boost::dynamic_pointer_cast<Workspace2D>(groupWS->getItem(i)));
    }
  } catch (...) {
  }

  if (m_workspaces.size() != 0)
    processAll();

  return true;
}
/**
*   Executes the algorithm
*/
void PlotAsymmetryByLogValue::exec()
{
    m_forward_list = getProperty("ForwardSpectra");
    m_backward_list = getProperty("BackwardSpectra");
    m_autogroup = ( m_forward_list.size() == 0 && m_backward_list.size() == 0);

    //double alpha = getProperty("Alpha");

    std::string logName = getProperty("LogValue");

    int red = getProperty("Red");
    int green = getProperty("Green");

    std::string stype = getProperty("Type");
    m_int = stype == "Integral";

    std::string firstFN = getProperty("FirstRun");
    std::string lastFN = getProperty("LastRun");

    std::string ext = firstFN.substr(firstFN.find_last_of("."));

    firstFN.erase(firstFN.size()-4);
    lastFN.erase(lastFN.size()-4);

    std::string fnBase = firstFN;
    size_t i = fnBase.size()-1;
    while(isdigit(fnBase[i]))  i--;
    if (i == fnBase.size()-1)
    {
        g_log.error("File name must end with a number.");
        throw Exception::FileError("File name must end with a number.",firstFN);
    }
    fnBase.erase(i+1);

    firstFN.erase(0,fnBase.size());
    lastFN.erase(0,fnBase.size());

    size_t is = atoi(firstFN.c_str());  // starting run number
    size_t ie = atoi(lastFN.c_str());   // last run number
    int w  = static_cast<int>(firstFN.size());

    // The number of runs
    size_t npoints = ie - is + 1;

    // Create the 2D workspace for the output
    int nplots = green != EMPTY_INT() ? 4 : 1;
    MatrixWorkspace_sptr outWS = WorkspaceFactory::Instance().create("Workspace2D",
                                 nplots,          //  the number of plots
                                 npoints,    //  the number of data points on a plot
                                 npoints     //  it's not a histogram
                                                                    );
    TextAxis* tAxis = new TextAxis(nplots);
    if (nplots == 1)
    {
        tAxis->setLabel(0,"Asymmetry");
    }
    else
    {
        tAxis->setLabel(0,"Red-Green");
        tAxis->setLabel(1,"Red");
        tAxis->setLabel(2,"Green");
        tAxis->setLabel(3,"Red+Green");
    }
    outWS->replaceAxis(1,tAxis);

    Progress progress(this,0,1,ie-is+2);
    for(size_t i=is; i<=ie; i++)
    {
        std::ostringstream fn,fnn;
        fnn << std::setw(w) << std::setfill('0') << i ;
        fn << fnBase << fnn.str() << ext;

        // Load a muon nexus file with auto_group set to true
        IAlgorithm_sptr loadNexus = createChildAlgorithm("LoadMuonNexus");
        loadNexus->setPropertyValue("Filename", fn.str());
        loadNexus->setPropertyValue("OutputWorkspace","tmp"+fnn.str());
        if (m_autogroup)
            loadNexus->setPropertyValue("AutoGroup","1");
        loadNexus->execute();

        std::string wsProp = "OutputWorkspace";

        DataObjects::Workspace2D_sptr ws_red;
        DataObjects::Workspace2D_sptr ws_green;

        // Run through the periods of the loaded file and do calculations on the selected ones
        Workspace_sptr tmp = loadNexus->getProperty(wsProp);
        WorkspaceGroup_sptr wsGroup = boost::dynamic_pointer_cast<WorkspaceGroup>(tmp);
        if (!wsGroup)
        {
            ws_red = boost::dynamic_pointer_cast<DataObjects::Workspace2D>(tmp);
            TimeSeriesProperty<double>* logp =
                dynamic_cast<TimeSeriesProperty<double>*>(ws_red->run().getLogData(logName));
            if (!logp)
            {
                throw std::invalid_argument("Log "+logName+" does not exist or not a double type");
            }
            double Y,E;
            calcIntAsymmetry(ws_red,Y,E);
            outWS->dataY(0)[i-is] = Y;
            outWS->dataX(0)[i-is] = logp->lastValue();
            outWS->dataE(0)[i-is] = E;
        }
        else
        {

            for( int period = 1; period <= wsGroup->getNumberOfEntries(); ++period )
            {
                std::stringstream suffix;
                suffix << period;
                wsProp = "OutputWorkspace_" + suffix.str();// form the property name for higher periods
                // Do only one period
                if (green == EMPTY_INT() && period == red)
                {
                    Workspace_sptr tmpff = loadNexus->getProperty(wsProp);
                    ws_red = boost::dynamic_pointer_cast<DataObjects::Workspace2D>(tmpff);
                    TimeSeriesProperty<double>* logp =
                        dynamic_cast<TimeSeriesProperty<double>*>(ws_red->run().getLogData(logName));
                    if (!logp)
                    {
                        throw std::invalid_argument("Log "+logName+" does not exist or not a double type");
                    }
                    double Y,E;
                    calcIntAsymmetry(ws_red,Y,E);
                    outWS->dataY(0)[i-is] = Y;
                    outWS->dataX(0)[i-is] = logp->lastValue();
                    outWS->dataE(0)[i-is] = E;
                }
                else // red & green
                {
                    if (period == red)
                    {
                        Workspace_sptr temp = loadNexus->getProperty(wsProp);
                        ws_red = boost::dynamic_pointer_cast<Workspace2D>(temp);
                    }
                    if (period == green)
                    {
                        Workspace_sptr temp = loadNexus->getProperty(wsProp);
                        ws_green = boost::dynamic_pointer_cast<Workspace2D>(temp);
                    }
                }

            }
            // red & green claculation
            if (green != EMPTY_INT())
            {
                if (!ws_red || !ws_green)
                    throw std::invalid_argument("Red or green period is out of range");
                TimeSeriesProperty<double>* logp =
                    dynamic_cast<TimeSeriesProperty<double>*>(ws_red->run().getLogData(logName));
                if (!logp)
                {
                    throw std::invalid_argument("Log "+logName+" does not exist or not a double type");
                }
                double Y,E;
                double Y1,E1;
                calcIntAsymmetry(ws_red,Y,E);
                calcIntAsymmetry(ws_green,Y1,E1);
                outWS->dataY(1)[i-is] = Y;
                outWS->dataX(1)[i-is] = logp->lastValue();
                outWS->dataE(1)[i-is] = E;

                outWS->dataY(2)[i-is] = Y1;
                outWS->dataX(2)[i-is] = logp->lastValue();
                outWS->dataE(2)[i-is] = E1;

                outWS->dataY(3)[i-is] = Y + Y1;
                outWS->dataX(3)[i-is] = logp->lastValue();
                outWS->dataE(3)[i-is] = sqrt(E*E+E1*E1);

                // move to last for safety since some grouping takes place in the
                // calcIntAsymmetry call below
                calcIntAsymmetry(ws_red,ws_green,Y,E);
                outWS->dataY(0)[i-is] = Y;
                outWS->dataX(0)[i-is] = logp->lastValue();
                outWS->dataE(0)[i-is] = E;
            }
            else if (!ws_red)
                throw std::invalid_argument("Red period is out of range");

        }
        progress.report();
    }

    outWS->getAxis(0)->title() = logName;
    outWS->setYUnitLabel("Asymmetry");

    // Assign the result to the output workspace property
    setProperty("OutputWorkspace", outWS);

}
WorkspaceGroup_sptr PolarizationCorrection::execPA(WorkspaceGroup_sptr inWS) {

  if (isPropertyDefault(cAlphaLabel())) {
    throw std::invalid_argument("Must provide as input for PA: " +
                                cAlphaLabel());
  }
  if (isPropertyDefault(cApLabel())) {
    throw std::invalid_argument("Must provide as input for PA: " + cApLabel());
  }

  size_t itemIndex = 0;
  MatrixWorkspace_sptr Ipp =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));
  MatrixWorkspace_sptr Ipa =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));
  MatrixWorkspace_sptr Iap =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));
  MatrixWorkspace_sptr Iaa =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));

  Ipp->setTitle("Ipp");
  Iaa->setTitle("Iaa");
  Ipa->setTitle("Ipa");
  Iap->setTitle("Iap");

  auto cropAlg = this->createChildAlgorithm("CropWorkspace");
  cropAlg->initialize();
  cropAlg->setProperty("InputWorkspace", Ipp);
  cropAlg->setProperty("EndWorkspaceIndex", 0);
  cropAlg->execute();
  MatrixWorkspace_sptr croppedIpp = cropAlg->getProperty("OutputWorkspace");

  MatrixWorkspace_sptr ones = copyShapeAndFill(croppedIpp, 1.0);
  // The ones workspace is now identical to the input workspaces in x, but has 1
  // as y values. It can therefore be used to build real polynomial functions.

  const VecDouble c_rho = getProperty(crhoLabel());
  const VecDouble c_alpha = getProperty(cAlphaLabel());
  const VecDouble c_pp = getProperty(cppLabel());
  const VecDouble c_ap = getProperty(cApLabel());

  const auto rho = this->execPolynomialCorrection(
      ones, c_rho); // Execute polynomial expression
  const auto pp = this->execPolynomialCorrection(
      ones, c_pp); // Execute polynomial expression
  const auto alpha = this->execPolynomialCorrection(
      ones, c_alpha); // Execute polynomial expression
  const auto ap = this->execPolynomialCorrection(
      ones, c_ap); // Execute polynomial expression

  const auto A0 = (Iaa * pp * ap) + (ap * Ipa * rho * pp) +
                  (ap * Iap * alpha * pp) + (Ipp * ap * alpha * rho * pp);
  const auto A1 = pp * Iaa;
  const auto A2 = pp * Iap;
  const auto A3 = ap * Iaa;
  const auto A4 = ap * Ipa;
  const auto A5 = ap * alpha * Ipp;
  const auto A6 = ap * alpha * Iap;
  const auto A7 = pp * rho * Ipp;
  const auto A8 = pp * rho * Ipa;

  const auto D = pp * ap * (rho + alpha + 1.0 + (rho * alpha));

  const auto nIpp =
      (A0 - A1 + A2 - A3 + A4 + A5 - A6 + A7 - A8 + Ipp + Iaa - Ipa - Iap) / D;
  const auto nIaa =
      (A0 + A1 - A2 + A3 - A4 - A5 + A6 - A7 + A8 + Ipp + Iaa - Ipa - Iap) / D;
  const auto nIpa =
      (A0 - A1 + A2 + A3 - A4 - A5 + A6 + A7 - A8 - Ipp - Iaa + Ipa + Iap) / D;
  const auto nIap =
      (A0 + A1 - A2 - A3 + A4 + A5 - A6 - A7 + A8 - Ipp - Iaa + Ipa + Iap) / D;

  WorkspaceGroup_sptr dataOut = boost::make_shared<WorkspaceGroup>();
  dataOut->addWorkspace(nIpp);
  dataOut->addWorkspace(nIpa);
  dataOut->addWorkspace(nIap);
  dataOut->addWorkspace(nIaa);
  size_t totalGroupEntries(dataOut->getNumberOfEntries());
  for (size_t i = 1; i < totalGroupEntries; i++) {
    auto alg = this->createChildAlgorithm("ReplaceSpecialValues");
    alg->setProperty("InputWorkspace", dataOut->getItem(i));
    alg->setProperty("OutputWorkspace", "dataOut_" + std::to_string(i));
    alg->setProperty("NaNValue", 0.0);
    alg->setProperty("NaNError", 0.0);
    alg->setProperty("InfinityValue", 0.0);
    alg->setProperty("InfinityError", 0.0);
    alg->execute();
  }
  // Preserve the history of the inside workspaces
  nIpp->history().addHistory(Ipp->getHistory());
  nIaa->history().addHistory(Iaa->getHistory());
  nIpa->history().addHistory(Ipa->getHistory());
  nIap->history().addHistory(Iap->getHistory());

  return dataOut;
}
WorkspaceGroup_sptr
PolarizationCorrectionFredrikze::execPA(WorkspaceGroup_sptr inWS) {

  size_t itemIndex = 0;
  MatrixWorkspace_sptr Ipp =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));
  MatrixWorkspace_sptr Ipa =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));
  MatrixWorkspace_sptr Iap =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));
  MatrixWorkspace_sptr Iaa =
      boost::dynamic_pointer_cast<MatrixWorkspace>(inWS->getItem(itemIndex++));

  Ipp->setTitle("Ipp");
  Iaa->setTitle("Iaa");
  Ipa->setTitle("Ipa");
  Iap->setTitle("Iap");

  const auto rho = this->getEfficiencyWorkspace(crhoLabel);
  const auto pp = this->getEfficiencyWorkspace(cppLabel);
  const auto alpha = this->getEfficiencyWorkspace(cAlphaLabel);
  const auto ap = this->getEfficiencyWorkspace(cApLabel);

  const auto A0 = (Iaa * pp * ap) + (Ipa * ap * rho * pp) +
                  (Iap * ap * alpha * pp) + (Ipp * ap * alpha * rho * pp);
  const auto A1 = Iaa * pp;
  const auto A2 = Iap * pp;
  const auto A3 = Iaa * ap;
  const auto A4 = Ipa * ap;
  const auto A5 = Ipp * ap * alpha;
  const auto A6 = Iap * ap * alpha;
  const auto A7 = Ipp * pp * rho;
  const auto A8 = Ipa * pp * rho;

  const auto D = pp * ap * (rho + alpha + 1.0 + (rho * alpha));

  const auto nIpp =
      (A0 - A1 + A2 - A3 + A4 + A5 - A6 + A7 - A8 + Ipp + Iaa - Ipa - Iap) / D;
  const auto nIaa =
      (A0 + A1 - A2 + A3 - A4 - A5 + A6 - A7 + A8 + Ipp + Iaa - Ipa - Iap) / D;
  const auto nIap =
      (A0 - A1 + A2 + A3 - A4 - A5 + A6 + A7 - A8 - Ipp - Iaa + Ipa + Iap) / D;
  const auto nIpa =
      (A0 + A1 - A2 - A3 + A4 + A5 - A6 - A7 + A8 - Ipp - Iaa + Ipa + Iap) / D;

  WorkspaceGroup_sptr dataOut = boost::make_shared<WorkspaceGroup>();
  dataOut->addWorkspace(nIpp);
  dataOut->addWorkspace(nIpa);
  dataOut->addWorkspace(nIap);
  dataOut->addWorkspace(nIaa);
  size_t totalGroupEntries(dataOut->getNumberOfEntries());
  for (size_t i = 1; i < totalGroupEntries; i++) {
    auto alg = this->createChildAlgorithm("ReplaceSpecialValues");
    alg->setProperty("InputWorkspace", dataOut->getItem(i));
    alg->setProperty("OutputWorkspace", "dataOut_" + std::to_string(i));
    alg->setProperty("NaNValue", 0.0);
    alg->setProperty("NaNError", 0.0);
    alg->setProperty("InfinityValue", 0.0);
    alg->setProperty("InfinityError", 0.0);
    alg->execute();
  }
  // Preserve the history of the inside workspaces
  nIpp->history().addHistory(Ipp->getHistory());
  nIaa->history().addHistory(Iaa->getHistory());
  nIpa->history().addHistory(Ipa->getHistory());
  nIap->history().addHistory(Iap->getHistory());

  return dataOut;
}