void LoadSINQFocus::loadRunDetails(NXEntry & entry) {
API::Run & runDetails = m_localWorkspace->mutableRun();
// int runNum = entry.getInt("run_number");
// std::string run_num = boost::lexical_cast<std::string>(runNum);
// runDetails.addProperty("run_number", run_num);
std::string start_time = entry.getString("start_time");
//start_time = getDateTimeInIsoFormat(start_time);
runDetails.addProperty("run_start", start_time);
std::string end_time = entry.getString("end_time");
//end_time = getDateTimeInIsoFormat(end_time);
runDetails.addProperty("run_end", end_time);
double wavelength = entry.getFloat(m_instrumentPath + "/monochromator/lambda");
runDetails.addProperty<double>("wavelength", wavelength);
double energy = entry.getFloat(m_instrumentPath + "/monochromator/energy");
runDetails.addProperty<double>("Ei", energy, true); //overwrite
std::string title = entry.getString("title");
runDetails.addProperty("title", title);
m_localWorkspace->setTitle(title);
}
/** Execute the algorithm.
*/
void LoadILLReflectometry::exec() {
// Retrieve filename
std::string filenameData = getPropertyValue("Filename");
// open the root node
NeXus::NXRoot dataRoot(filenameData);
NXEntry firstEntry = dataRoot.openFirstEntry();
// Load Monitor details: n. monitors x monitor contents
std::vector<std::vector<int>> monitorsData = loadMonitors(firstEntry);
// Load Data details (number of tubes, channels, etc)
loadDataDetails(firstEntry);
std::string instrumentPath = m_loader.findInstrumentNexusPath(firstEntry);
setInstrumentName(firstEntry, instrumentPath);
initWorkSpace(firstEntry, monitorsData);
g_log.debug("Building properties...");
loadNexusEntriesIntoProperties(filenameData);
g_log.debug("Loading data...");
loadDataIntoTheWorkSpace(firstEntry, monitorsData);
// load the instrument from the IDF if it exists
g_log.debug("Loading instrument definition...");
runLoadInstrument();
// 1) Move
// Get distance and tilt angle stored in nexus file
// Mantid way
//// auto angleProp =
/// dynamic_cast<PropertyWithValue<double>*>(m_localWorkspace->run().getProperty("dan.value"));
// Nexus way
double angle =
firstEntry.getFloat("instrument/dan/value"); // detector angle in degrees
double distance = firstEntry.getFloat(
"instrument/det/value"); // detector distance in millimeter
distance /= 1000.0; // convert to meter
g_log.debug() << "Moving detector at angle " << angle << " and distance "
<< distance << std::endl;
placeDetector(distance, angle);
// Set the channel width property
auto channel_width = dynamic_cast<PropertyWithValue<double> *>(
m_localWorkspace->run().getProperty("monitor1.time_of_flight_0"));
m_localWorkspace->mutableRun().addProperty<double>(
"channel_width", *channel_width, true); // overwrite
// Set the output workspace property
setProperty("OutputWorkspace", m_localWorkspace);
}
/** Log the run details from the file
* @param localWorkspace :: The workspace details to use
*/
void
LoadMuonNexus1::loadRunDetails(DataObjects::Workspace2D_sptr localWorkspace) {
API::Run &runDetails = localWorkspace->mutableRun();
runDetails.addProperty("run_title", localWorkspace->getTitle(), true);
int numSpectra = static_cast<int>(localWorkspace->getNumberHistograms());
runDetails.addProperty("nspectra", numSpectra);
NXRoot root(m_filename);
try {
std::string start_time = root.getString("run/start_time");
runDetails.addProperty("run_start", start_time);
} catch (std::runtime_error &) {
g_log.warning("run/start_time is not available, run_start log not added.");
}
try {
std::string stop_time = root.getString("run/stop_time");
runDetails.addProperty("run_end", stop_time);
} catch (std::runtime_error &) {
g_log.warning("run/stop_time is not available, run_end log not added.");
}
try {
std::string dur = root.getString("run/duration");
runDetails.addProperty("dur", dur);
runDetails.addProperty("durunits", 1); // 1 means second here
runDetails.addProperty("dur_secs", dur);
} catch (std::runtime_error &) {
g_log.warning("run/duration is not available, dur log not added.");
}
// Get sample parameters
NXEntry runSample = root.openEntry("run/sample");
if (runSample.containsDataSet("temperature")) {
float temperature = runSample.getFloat("temperature");
runDetails.addProperty("sample_temp", static_cast<double>(temperature));
}
if (runSample.containsDataSet("magnetic_field")) {
float magn_field = runSample.getFloat("magnetic_field");
runDetails.addProperty("sample_magn_field",
static_cast<double>(magn_field));
}
}
/*
* Load data about the Experiment.
*
* TODO: This is very incomplete. In ISIS they much more info in the nexus file than ILL.
*
* @param entry :: The Nexus entry
*/
void LoadSINQFocus::loadExperimentDetails(NXEntry & entry) {
std::string name = boost::lexical_cast<std::string>(
entry.getFloat("sample/name"));
m_localWorkspace->mutableSample().setName(name);
}
void LoadLLB::loadRunDetails(NXEntry &entry) {
API::Run &runDetails = m_localWorkspace->mutableRun();
// int runNum = entry.getInt("run_number");
// std::string run_num = boost::lexical_cast<std::string>(runNum);
// runDetails.addProperty("run_number", run_num);
std::string start_time = entry.getString("start_time");
// start_time = getDateTimeInIsoFormat(start_time);
runDetails.addProperty("run_start", start_time);
std::string end_time = entry.getString("end_time");
// end_time = getDateTimeInIsoFormat(end_time);
runDetails.addProperty("run_end", end_time);
double wavelength = entry.getFloat("nxbeam/incident_wavelength");
runDetails.addProperty<double>("wavelength", wavelength);
double energy = m_loader.calculateEnergy(wavelength);
runDetails.addProperty<double>("Ei", energy, true); // overwrite
std::string title = entry.getString("title");
runDetails.addProperty("title", title);
m_localWorkspace->setTitle(title);
}
/**
* Load data about the run
* @param local_workspace :: The workspace to load the run information in to
* @param entry :: The Nexus entry
*/
void LoadISISNexus2::loadRunDetails(DataObjects::Workspace2D_sptr local_workspace, NXEntry & entry)
{
API::Run & runDetails = local_workspace->mutableRun();
// Charge is stored as a float
m_proton_charge = static_cast<double>(entry.getFloat("proton_charge"));
runDetails.setProtonCharge(m_proton_charge);
std::string run_num = boost::lexical_cast<std::string>(entry.getInt("run_number"));
runDetails.addProperty("run_number", run_num);
//
// Some details are only stored in the VMS compatability block so we'll pull everything from there
// for consistency
NXClass vms_compat = entry.openNXGroup("isis_vms_compat");
// Run header
NXChar char_data = vms_compat.openNXChar("HDR");
char_data.load();
runDetails.addProperty("run_header", std::string(char_data(),80));
// Data details on run not the workspace
runDetails.addProperty("nspectra", static_cast<int>(m_numberOfSpectraInFile));
runDetails.addProperty("nchannels", static_cast<int>(m_numberOfChannelsInFile));
runDetails.addProperty("nperiods", static_cast<int>(m_numberOfPeriodsInFile));
// RPB struct info
NXInt rpb_int = vms_compat.openNXInt("IRPB");
rpb_int.load();
runDetails.addProperty("dur", rpb_int[0]); // actual run duration
runDetails.addProperty("durunits", rpb_int[1]); // scaler for above (1=seconds)
runDetails.addProperty("dur_freq", rpb_int[2]); // testinterval for above (seconds)
runDetails.addProperty("dmp", rpb_int[3]); // dump interval
runDetails.addProperty("dmp_units", rpb_int[4]); // scaler for above
runDetails.addProperty("dmp_freq", rpb_int[5]); // interval for above
runDetails.addProperty("freq", rpb_int[6]); // 2**k where source frequency = 50 / 2**k
// Now double data
NXFloat rpb_dbl = vms_compat.openNXFloat("RRPB");
rpb_dbl.load();
runDetails.addProperty("gd_prtn_chrg", static_cast<double>(rpb_dbl[7])); // good proton charge (uA.hour)
runDetails.addProperty("tot_prtn_chrg", static_cast<double>(rpb_dbl[8])); // total proton charge (uA.hour)
runDetails.addProperty("goodfrm",rpb_int[9]); // good frames
runDetails.addProperty("rawfrm", rpb_int[10]); // raw frames
runDetails.addProperty("dur_wanted", rpb_int[11]); // requested run duration (units as for "duration" above)
runDetails.addProperty("dur_secs", rpb_int[12]); // actual run duration in seconds
runDetails.addProperty("mon_sum1", rpb_int[13]); // monitor sum 1
runDetails.addProperty("mon_sum2", rpb_int[14]); // monitor sum 2
runDetails.addProperty("mon_sum3",rpb_int[15]); // monitor sum 3
// End date and time is stored separately in ISO format in the "raw_data1/endtime" class
char_data = entry.openNXChar("end_time");
char_data.load();
std::string end_time_iso = std::string(char_data(), 19);
runDetails.addProperty("run_end", end_time_iso);
char_data = entry.openNXChar("start_time");
char_data.load();
std::string start_time_iso = std::string(char_data(), 19);
runDetails.addProperty("run_start", start_time_iso);
runDetails.addProperty("rb_proposal",rpb_int[21]); // RB (proposal) number
vms_compat.close();
}
/**
* Load data about the run
* @param local_workspace :: The workspace to load the run information in to
* @param entry :: The Nexus entry
*/
void
LoadISISNexus2::loadRunDetails(DataObjects::Workspace2D_sptr &local_workspace,
NXEntry &entry) {
API::Run &runDetails = local_workspace->mutableRun();
// Charge is stored as a float
m_proton_charge = static_cast<double>(entry.getFloat("proton_charge"));
runDetails.setProtonCharge(m_proton_charge);
std::string run_num =
boost::lexical_cast<std::string>(entry.getInt("run_number"));
runDetails.addProperty("run_number", run_num);
//
// Some details are only stored in the VMS comparability block so we'll pull
// everything from there
// for consistency
NXClass vms_compat = entry.openNXGroup("isis_vms_compat");
// Run header
NXChar char_data = vms_compat.openNXChar("HDR");
char_data.load();
// Space-separate the fields
char *nxsHdr = char_data();
char header[86] = {};
const size_t byte = sizeof(char);
const char fieldSep(' ');
size_t fieldWidths[7] = {3, 5, 20, 24, 12, 8, 8};
char *srcStart = nxsHdr;
char *destStart = header;
for (size_t i = 0; i < 7; ++i) {
size_t width = fieldWidths[i];
memcpy(destStart, srcStart, width * byte);
if (i < 6) // no space after last field
{
srcStart += width;
destStart += width;
memset(destStart, fieldSep, byte); // insert separator
destStart += 1;
}
}
runDetails.addProperty("run_header", std::string(header, header + 86));
// Data details on run not the workspace
runDetails.addProperty("nspectra",
static_cast<int>(m_loadBlockInfo.numberOfSpectra));
runDetails.addProperty("nchannels",
static_cast<int>(m_loadBlockInfo.numberOfChannels));
runDetails.addProperty("nperiods",
static_cast<int>(m_loadBlockInfo.numberOfPeriods));
// RPB struct info
NXInt rpb_int = vms_compat.openNXInt("IRPB");
rpb_int.load();
runDetails.addProperty("dur", rpb_int[0]); // actual run duration
runDetails.addProperty("durunits",
rpb_int[1]); // scaler for above (1=seconds)
runDetails.addProperty("dur_freq",
rpb_int[2]); // testinterval for above (seconds)
runDetails.addProperty("dmp", rpb_int[3]); // dump interval
runDetails.addProperty("dmp_units", rpb_int[4]); // scaler for above
runDetails.addProperty("dmp_freq", rpb_int[5]); // interval for above
runDetails.addProperty("freq",
rpb_int[6]); // 2**k where source frequency = 50 / 2**k
// Now double data
NXFloat rpb_dbl = vms_compat.openNXFloat("RRPB");
rpb_dbl.load();
runDetails.addProperty(
"gd_prtn_chrg",
static_cast<double>(rpb_dbl[7])); // good proton charge (uA.hour)
runDetails.addProperty(
"tot_prtn_chrg",
static_cast<double>(rpb_dbl[8])); // total proton charge (uA.hour)
runDetails.addProperty("goodfrm", rpb_int[9]); // good frames
runDetails.addProperty("rawfrm", rpb_int[10]); // raw frames
runDetails.addProperty(
"dur_wanted",
rpb_int[11]); // requested run duration (units as for "duration" above)
runDetails.addProperty("dur_secs",
rpb_int[12]); // actual run duration in seconds
runDetails.addProperty("mon_sum1", rpb_int[13]); // monitor sum 1
runDetails.addProperty("mon_sum2", rpb_int[14]); // monitor sum 2
runDetails.addProperty("mon_sum3", rpb_int[15]); // monitor sum 3
// End date and time is stored separately in ISO format in the
// "raw_data1/endtime" class
char_data = entry.openNXChar("end_time");
char_data.load();
std::string end_time_iso = std::string(char_data(), 19);
runDetails.addProperty("run_end", end_time_iso);
char_data = entry.openNXChar("start_time");
char_data.load();
std::string start_time_iso = std::string(char_data(), 19);
runDetails.addProperty("run_start", start_time_iso);
runDetails.addProperty("rb_proposal", rpb_int[21]); // RB (proposal) number
vms_compat.close();
}
