/** * Returns the input vertical * @param workspace :: A pointer to a workspace * @return An axis pointer for the vertical axis of the input workspace */ API::Axis * Transpose::getVerticalAxis(API::MatrixWorkspace_const_sptr workspace) const { API::Axis *yAxis; try { yAxis = workspace->getAxis(1); } catch (Kernel::Exception::IndexError &) { throw std::invalid_argument("Axis(1) not found on input workspace."); } // Can't put text in dataX if (yAxis->isText()) { throw std::invalid_argument( "Axis(1) is a text axis. Transpose is unable to cope with text axes."); } return yAxis; }
/** Get a workspace identified by an InputData structure. * @param data :: InputData with name and either spec or i fields defined. * @return InputData structure with the ws field set if everything was OK. */ PlotPeakByLogValue::InputData PlotPeakByLogValue::getWorkspace(const InputData& data) { InputData out(data); if (API::AnalysisDataService::Instance().doesExist(data.name)) { DataObjects::Workspace2D_sptr ws = boost::dynamic_pointer_cast<DataObjects::Workspace2D>( API::AnalysisDataService::Instance().retrieve(data.name)); if (ws) { out.ws = ws; } else { return data; } } else { std::ifstream fil(data.name.c_str()); if (!fil) { g_log.warning() << "File "<<data.name<<" does not exist\n"; return data; } fil.close(); std::string::size_type i = data.name.find_last_of('.'); if (i == std::string::npos) { g_log.warning() << "Cannot open file "<<data.name<<"\n"; return data; } std::string ext = data.name.substr(i); try { API::IAlgorithm_sptr load = createSubAlgorithm("Load"); load->initialize(); load->setPropertyValue("FileName",data.name); load->execute(); if (load->isExecuted()) { API::Workspace_sptr rws = load->getProperty("OutputWorkspace"); if (rws) { DataObjects::Workspace2D_sptr ws = boost::dynamic_pointer_cast<DataObjects::Workspace2D>(rws); if (ws) { out.ws = ws; } else { API::WorkspaceGroup_sptr gws = boost::dynamic_pointer_cast<API::WorkspaceGroup>(rws); if (gws) { std::vector<std::string> wsNames = gws->getNames(); std::string propName = "OUTPUTWORKSPACE_" + boost::lexical_cast<std::string>(data.period); if (load->existsProperty(propName)) { Workspace_sptr rws1 = load->getProperty(propName); out.ws = boost::dynamic_pointer_cast<DataObjects::Workspace2D>(rws1); } } } } } } catch(std::exception& e) { g_log.error(e.what()); return data; } } if (!out.ws) return data; API::Axis* axis = out.ws->getAxis(1); if (axis->isSpectra()) {// spectra axis if (out.spec < 0) { if (out.i >= 0) { out.spec = axis->spectraNo(out.i); } else {// i < 0 && spec < 0 => use start and end for(size_t i=0;i<axis->length();++i) { double s = double(axis->spectraNo(i)); if (s >= out.start && s <= out.end) { out.indx.push_back(static_cast<int>(i)); } } } } else { for(size_t i=0;i<axis->length();++i) { int j = axis->spectraNo(i); if (j == out.spec) { out.i = static_cast<int>(i); break; } } } if (out.i < 0 && out.indx.empty()) { return data; } } else {// numeric axis out.spec = -1; if (out.i >= 0) { out.indx.clear(); } else { if (out.i < -1) { out.start = (*axis)(0); out.end = (*axis)(axis->length()-1); } for(size_t i=0;i<axis->length();++i) { double s = (*axis)(i); if (s >= out.start && s <= out.end) { out.indx.push_back(static_cast<int>(i)); } } } } return out; }
/** Executes the algorithm * * @throw Exception::FileError If the grouping file cannot be opened or read successfully * @throw runtime_error If unable to run one of the sub-algorithms successfully */ void DiffractionFocussing::exec() { // retrieve the properties std::string groupingFileName=getProperty("GroupingFileName"); // Get the input workspace MatrixWorkspace_sptr inputW = getProperty("InputWorkspace"); bool dist = inputW->isDistribution(); //do this first to check that a valid file is available before doing any work std::multimap<int64_t,int64_t> detectorGroups;// <group, UDET> if (!readGroupingFile(groupingFileName, detectorGroups)) { throw Exception::FileError("Error reading .cal file",groupingFileName); } //Convert to d-spacing units API::MatrixWorkspace_sptr tmpW = convertUnitsToDSpacing(inputW); //Rebin to a common set of bins RebinWorkspace(tmpW); std::set<int64_t> groupNumbers; for(std::multimap<int64_t,int64_t>::const_iterator d = detectorGroups.begin();d!=detectorGroups.end();d++) { if (groupNumbers.find(d->first) == groupNumbers.end()) { groupNumbers.insert(d->first); } } int iprogress = 0; int iprogress_count = static_cast<int>(groupNumbers.size()); int iprogress_step = iprogress_count / 100; if (iprogress_step == 0) iprogress_step = 1; std::vector<int64_t> resultIndeces; for(std::set<int64_t>::const_iterator g = groupNumbers.begin();g!=groupNumbers.end();g++) { if (iprogress++ % iprogress_step == 0) { progress(0.68 + double(iprogress)/iprogress_count/3); } std::multimap<int64_t,int64_t>::const_iterator from = detectorGroups.lower_bound(*g); std::multimap<int64_t,int64_t>::const_iterator to = detectorGroups.upper_bound(*g); std::vector<detid_t> detectorList; for(std::multimap<int64_t,int64_t>::const_iterator d = from;d!=to;d++) detectorList.push_back(static_cast<detid_t>(d->second)); // Want version 1 of GroupDetectors here API::IAlgorithm_sptr childAlg = createSubAlgorithm("GroupDetectors",-1.0,-1.0,true,1); childAlg->setProperty("Workspace", tmpW); childAlg->setProperty< std::vector<detid_t> >("DetectorList",detectorList); childAlg->executeAsSubAlg(); try { // get the index of the combined spectrum int ri = childAlg->getProperty("ResultIndex"); if (ri >= 0) { resultIndeces.push_back(ri); } } catch(...) { throw std::runtime_error("Unable to get Properties from GroupDetectors sub-algorithm"); } } // Discard left-over spectra, but print warning message giving number discarded int discarded = 0; const int64_t oldHistNumber = tmpW->getNumberHistograms(); API::Axis *spectraAxis = tmpW->getAxis(1); for(int64_t i=0; i < oldHistNumber; i++) if ( spectraAxis->spectraNo(i) >= 0 && find(resultIndeces.begin(),resultIndeces.end(),i) == resultIndeces.end()) { ++discarded; } g_log.warning() << "Discarded " << discarded << " spectra that were not assigned to any group" << std::endl; // Running GroupDetectors leads to a load of redundant spectra // Create a new workspace that's the right size for the meaningful spectra and copy them in int64_t newSize = tmpW->blocksize(); API::MatrixWorkspace_sptr outputW = API::WorkspaceFactory::Instance().create(tmpW,resultIndeces.size(),newSize+1,newSize); // Copy units outputW->getAxis(0)->unit() = tmpW->getAxis(0)->unit(); outputW->getAxis(1)->unit() = tmpW->getAxis(1)->unit(); API::Axis *spectraAxisNew = outputW->getAxis(1); for(int64_t hist=0; hist < static_cast<int64_t>(resultIndeces.size()); hist++) { int64_t i = resultIndeces[hist]; double spNo = static_cast<double>(spectraAxis->spectraNo(i)); MantidVec &tmpE = tmpW->dataE(i); MantidVec &outE = outputW->dataE(hist); MantidVec &tmpY = tmpW->dataY(i); MantidVec &outY = outputW->dataY(hist); MantidVec &tmpX = tmpW->dataX(i); MantidVec &outX = outputW->dataX(hist); outE.assign(tmpE.begin(),tmpE.end()); outY.assign(tmpY.begin(),tmpY.end()); outX.assign(tmpX.begin(),tmpX.end()); spectraAxisNew->setValue(hist,spNo); spectraAxis->setValue(i,-1); } progress(1.); outputW->isDistribution(dist); // Assign it to the output workspace property setProperty("OutputWorkspace",outputW); return; }