void LoadSINQFocus::initWorkSpace(NeXus::NXEntry& entry) { // read in the data NXData dataGroup = entry.openNXData("merged"); NXInt data = dataGroup.openIntData(); m_numberOfTubes = static_cast<size_t>(data.dim0()); m_numberOfPixelsPerTube = 1; m_numberOfChannels = static_cast<size_t>(data.dim1()); // dim0 * m_numberOfPixelsPerTube is the total number of detectors m_numberOfHistograms = m_numberOfTubes * m_numberOfPixelsPerTube; g_log.debug() << "NumberOfTubes: " << m_numberOfTubes << std::endl; g_log.debug() << "NumberOfPixelsPerTube: " << m_numberOfPixelsPerTube << std::endl; g_log.debug() << "NumberOfChannels: " << m_numberOfChannels << std::endl; // Now create the output workspace // Might need to get this value from the number of monitors in the Nexus file // params: // workspace type, // total number of spectra + (number of monitors = 0), // bin boundaries = m_numberOfChannels + 1 // Z/time dimension m_localWorkspace = WorkspaceFactory::Instance().create("Workspace2D", m_numberOfHistograms, m_numberOfChannels + 1, m_numberOfChannels); m_localWorkspace->getAxis(0)->unit() = UnitFactory::Instance().create( "TOF"); m_localWorkspace->setYUnitLabel("Counts"); }
/** * Load Data details (number of tubes, channels, etc) * @param entry First entry of nexus file */ void LoadILLReflectometry::loadDataDetails(NeXus::NXEntry &entry) { // read in the data NXData dataGroup = entry.openNXData("data"); NXInt data = dataGroup.openIntData(); m_numberOfTubes = static_cast<size_t>(data.dim0()); m_numberOfPixelsPerTube = static_cast<size_t>(data.dim1()); m_numberOfChannels = static_cast<size_t>(data.dim2()); }
size_t LoadILLSANS::loadDataIntoWorkspaceFromMonitors(NeXus::NXEntry &firstEntry, size_t firstIndex) { // let's find the monitors // For D33 should be monitor1 and monitor2 for (std::vector<NXClassInfo>::const_iterator it = firstEntry.groups().begin(); it != firstEntry.groups().end(); ++it) { if (it->nxclass == "NXmonitor") { NXData dataGroup = firstEntry.openNXData(it->nxname); NXInt data = dataGroup.openIntData(); data.load(); g_log.debug() << "Monitor: " << it->nxname << " dims = " << data.dim0() << "x" << data.dim1() << "x" << data.dim2() << '\n'; const size_t vectorSize = data.dim2() + 1; std::vector<double> positionsBinning; positionsBinning.reserve(vectorSize); for (size_t i = 0; i < vectorSize; i++) positionsBinning.push_back(static_cast<double>(i)); // Assign X m_localWorkspace->dataX(firstIndex) .assign(positionsBinning.begin(), positionsBinning.end()); // Assign Y m_localWorkspace->dataY(firstIndex).assign(data(), data() + data.dim2()); // Assign Error MantidVec &E = m_localWorkspace->dataE(firstIndex); std::transform(data(), data() + data.dim2(), E.begin(), LoadHelper::calculateStandardError); // Add average monitor counts to a property: double averageMonitorCounts = std::accumulate(data(), data() + data.dim2(), 0) / static_cast<double>(data.dim2()); // make sure the monitor has values! if (averageMonitorCounts > 0) { API::Run &runDetails = m_localWorkspace->mutableRun(); runDetails.addProperty("monitor", averageMonitorCounts, true); } firstIndex++; } } return firstIndex; }
void LoadILLSANS::initWorkSpace(NeXus::NXEntry &firstEntry, const std::string &instrumentPath) { g_log.debug("Fetching data..."); NXData dataGroup1 = firstEntry.openNXData("data1"); NXInt dataRear = dataGroup1.openIntData(); dataRear.load(); NXData dataGroup2 = firstEntry.openNXData("data2"); NXInt dataRight = dataGroup2.openIntData(); dataRight.load(); NXData dataGroup3 = firstEntry.openNXData("data3"); NXInt dataLeft = dataGroup3.openIntData(); dataLeft.load(); NXData dataGroup4 = firstEntry.openNXData("data4"); NXInt dataDown = dataGroup4.openIntData(); dataDown.load(); NXData dataGroup5 = firstEntry.openNXData("data5"); NXInt dataUp = dataGroup5.openIntData(); dataUp.load(); g_log.debug("Checking channel numbers..."); // check number of channels if (dataRear.dim2() != dataRight.dim2() && dataRight.dim2() != dataLeft.dim2() && dataLeft.dim2() != dataDown.dim2() && dataDown.dim2() != dataUp.dim2()) { throw std::runtime_error( "The time bins have not the same dimension for all the 5 detectors!"); } int numberOfHistograms = dataRear.dim0() * dataRear.dim1() + dataRight.dim0() * dataRight.dim1() + dataLeft.dim0() * dataLeft.dim1() + dataDown.dim0() * dataDown.dim1() + dataUp.dim0() * dataUp.dim1(); g_log.debug("Creating empty workspace..."); // TODO : Must put this 2 somewhere else: number of monitors! createEmptyWorkspace(numberOfHistograms + 2, dataRear.dim2()); loadMetaData(firstEntry, instrumentPath); std::vector<double> binningRear, binningRight, binningLeft, binningDown, binningUp; if (firstEntry.getFloat("mode") == 0.0) { // Not TOF g_log.debug("Getting default wavelength bins..."); binningRear = m_defaultBinning; binningRight = m_defaultBinning; binningLeft = m_defaultBinning; binningDown = m_defaultBinning; binningUp = m_defaultBinning; } else { g_log.debug("Getting wavelength bins from the nexus file..."); std::string binPathPrefix(instrumentPath + "/tof/tof_wavelength_detector"); binningRear = m_loader.getTimeBinningFromNexusPath(firstEntry, binPathPrefix + "1"); binningRight = m_loader.getTimeBinningFromNexusPath(firstEntry, binPathPrefix + "2"); binningLeft = m_loader.getTimeBinningFromNexusPath(firstEntry, binPathPrefix + "3"); binningDown = m_loader.getTimeBinningFromNexusPath(firstEntry, binPathPrefix + "4"); binningUp = m_loader.getTimeBinningFromNexusPath(firstEntry, binPathPrefix + "5"); } g_log.debug("Loading the data into the workspace..."); size_t nextIndex = loadDataIntoWorkspaceFromMonitors(firstEntry, 0); nextIndex = loadDataIntoWorkspaceFromHorizontalTubes(dataRear, binningRear, nextIndex); nextIndex = loadDataIntoWorkspaceFromVerticalTubes(dataRight, binningRight, nextIndex); nextIndex = loadDataIntoWorkspaceFromVerticalTubes(dataLeft, binningLeft, nextIndex); nextIndex = loadDataIntoWorkspaceFromHorizontalTubes(dataDown, binningDown, nextIndex); nextIndex = loadDataIntoWorkspaceFromHorizontalTubes(dataUp, binningUp, nextIndex); }