Program to determine inter-string time calibration. More...

#include <string>
#include <iostream>
#include <iomanip>
#include <type_traits>
#include <functional>
#include <future>
#include <mutex>
#include <thread>
#include <vector>
#include <set>
#include <memory>
#include <algorithm>
#include "km3net-dataformat/online/JDAQEvent.hh"
#include "km3net-dataformat/definitions/fitparameters.hh"
#include "JDAQ/JDAQEventIO.hh"
#include "JDetector/JDetector.hh"
#include "JDetector/JDetectorToolkit.hh"
#include "JDetector/JModuleRouter.hh"
#include "JDynamics/JDynamics.hh"
#include "JSupport/JMeta.hh"
#include "JSupport/JSupport.hh"
#include "JSupport/JMultipleFileScanner.hh"
#include "JSupport/JParallelFileScanner.hh"
#include "JSupport/JSummaryFileRouter.hh"
#include "JReconstruction/JHitW0.hh"
#include "JReconstruction/JEvt.hh"
#include "JReconstruction/JEvtToolkit.hh"
#include "JReconstruction/JMuonGandalfParameters_t.hh"
#include "JTrigger/JHitL0.hh"
#include "JTrigger/JBuildL0.hh"
#include "JFit/JFitToolkit.hh"
#include "JFit/JLine1Z.hh"
#include "JFit/JLine3Z.hh"
#include "JFit/JModel.hh"
#include "JFit/JGandalf.hh"
#include "JFit/JRegressorHelper.hh"
#include "JFit/JLine3ZRegressor.hh"
#include "JFit/JGradient.hh"
#include "JLang/JSTDObjectReader.hh"
#include "JLang/JVectorize.hh"
#include "JGeometry3D/JRotation3D.hh"
#include "JMath/JMath.hh"
#include "JMath/JQuantile_t.hh"
#include "JTools/JRange.hh"
#include "Jeep/JProperties.hh"
#include "Jeep/JParser.hh"
#include "Jeep/JMessage.hh"

Classes
struct	JRECONSTRUCTION::event_type
	Auxiliary data structure to store data and fit in memory. More...

struct	JRECONSTRUCTION::JEditor
	Auxiliary class for editing time offset. More...

struct	JRECONSTRUCTION::JPerth
	Thread pool for fits to data. More...

struct	JRECONSTRUCTION::JPerth_t
	Auxiliary data structure for chi2 function object. More...

Namespaces
	JRECONSTRUCTION
	Model fits to data.

Typedefs
typedef std::vector< JHitW0 >	JRECONSTRUCTION::buffer_type
	hits More...

typedef std::map< int, buffer_type >	JRECONSTRUCTION::map_type
	identifier -> hits More...

typedef std::vector< event_type >	JRECONSTRUCTION::data_type

typedef JLANG::JSTDObjectReader< const event_type >	JRECONSTRUCTION::input_type

typedef JFIT::JRegressorStorage< JFIT::JLine3Z, JFIT::JGandalf >	JRECONSTRUCTION::JRegressorStorage_t

typedef JFIT::JRegressor< JFIT::JLine3Z, JFIT::JGandalf >	JRECONSTRUCTION::JRegressor_t

Functions
int	main (int argc, char **argv)

Detailed Description

Program to determine inter-string time calibration.

Author: mdejong

Definition in file JPerth.cc.

Function Documentation

◆ main()

int main	(	int	argc,
		char **	argv
	)

Definition at line 281 of file JPerth.cc.

 {
   using namespace std;
   using namespace JPP;
   using namespace KM3NETDAQ;
  
   typedef JParallelFileScanner< JTypeList<JDAQEvent, JFIT::JEvt> > JParallelFileScanner_t;
   typedef JParallelFileScanner_t::multi_pointer_type               multi_pointer_type;
   typedef JTYPELIST<JCOMPASS::JOrientation,
                     JACOUSTICS::JEvt>::typelist                    calibration_types;
   typedef JMultipleFileScanner<calibration_types>                  JCalibration_t;
  
   JMultipleFileScanner<>   inputFile;
   JLimit_t&                numberOfEvents = inputFile.getLimit();
   string                   detectorFile;
   JCalibration_t           calibrationFile;
   double                   Tmax_s;
   string                   pdfFile;
   JMuonGandalfParameters_t parameters;
   bool                     overwriteDetector;
   set<int>                 strings;                              // string identifiers
   set<int>                 modules;                              // module identifiers
   int                      number_of_iterations    =  1000;
   int                      number_of_extra_steps   =     0;
   double                   epsilon                 =   1.0e-4;
   double                   T_ns                    =   2.5;      // step size
   size_t                   threads;                              // number of threads
   int                      debug;
  
   const int DEFAULT_ID = -1;
  
   try { 
  
     JProperties properties;
  
     properties.insert(gmake_property(number_of_iterations));
     properties.insert(gmake_property(number_of_extra_steps));
     properties.insert(gmake_property(epsilon));
     properties.insert(gmake_property(T_ns));
  
     JParser<> zap("Program to determine inter-string time calibration.");
     
     zap['f'] = make_field(inputFile);
     zap['a'] = make_field(detectorFile);
     zap['+'] = make_field(calibrationFile)     = JPARSER::initialised();
     zap['T'] = make_field(Tmax_s)              = 100.0;
     zap['n'] = make_field(numberOfEvents)      = JLimit::max();
     zap['P'] = make_field(pdfFile);
     zap['@'] = make_field(parameters)          = JPARSER::initialised();
     zap['A'] = make_field(overwriteDetector, "overwrite detector file provided through '-a' with fitted time offsets.");
     zap['S'] = make_field(strings,           "string identifiers (" << DEFAULT_ID << " => all)") =  JPARSER::initialised();
     zap['M'] = make_field(modules,           "module identifiers (" << DEFAULT_ID << " => all)") =  JPARSER::initialised();
     zap['%'] = make_field(properties,        "fit parameters")                                   =  JPARSER::initialised();
     zap['N'] = make_field(threads,           "number of threads")                                = 1;
     zap['d'] = make_field(debug)               = 1;
     
     zap(argc, argv);
   }
   catch(const exception& error) {
     FATAL(error.what() << endl);
   }
  
  
   if (strings.empty() == modules.empty()) {
     FATAL("Set either strings (option -S) or modules (option -M)." << endl);
   }
  
   JDetector detector;
  
   try {
     load(detectorFile, detector);
   }
   catch(const JException& error) {
     FATAL(error);
   }
  
   unique_ptr<JDynamics> dynamics;
  
   try {
  
     dynamics.reset(new JDynamics(detector, Tmax_s));
  
     dynamics->load(calibrationFile);
   }
   catch(const exception& error) {
     if (!calibrationFile.empty()) {
       FATAL(error.what());
     }
   }
  
   const JModuleRouter router(dynamics ? dynamics->getDetector() : detector);
  
   NOTICE("Reading PDFs... " << flush);
   
   const JRegressorStorage_t storage(pdfFile, parameters.TTS_ns);
  
   NOTICE("OK" << endl);
  
   JRegressor_t::debug              = debug;
   JRegressor_t::T_ns.setRange(parameters.TMin_ns, parameters.TMax_ns);
   JRegressor_t::Vmax_npe           = parameters.VMax_npe;
   JRegressor_t::MAXIMUM_ITERATIONS = parameters.NMax;
  
  
   // preprocess input data
   
   const JBuildL0<JHitL0>  buildL0;
  
   data_type    data;
  
   counter_type skip    = inputFile.getLowerLimit();
   counter_type counter = inputFile.getLowerLimit();
   
   for (JMultipleFileScanner<>::const_iterator i = inputFile.begin(); i != inputFile.end(); ++i) {
  
     JSummaryFileRouter  summary(*i, parameters.R_Hz);
  
     for (JParallelFileScanner_t in(*i); (skip -= in.skip(skip)) == 0 && in.hasNext() && counter != numberOfEvents; ++counter) {
  
       STATUS("event: " << setw(10) << counter << '\r'); DEBUG(endl);
  
       multi_pointer_type ps  = in.next();
     
       const JDAQEvent*   tev = ps;
       const JFIT::JEvt*  evt = ps;
  
       summary.update(*tev);
  
       if (dynamics) {
         dynamics->update(*tev);
       }
  
       if (!evt->empty()) {
  
         vector<JHitL0>  dataL0;
               
         buildL0(*tev, router, true, back_inserter(dataL0));
  
         const JFIT::JFit&  fit = (*evt)[0];
       
         const JRotation3D  R (getDirection(fit));
         const JLine1Z      tz(getPosition (fit).rotate(R), fit.getT());
         JRange<double>     Z_m;
  
         if (fit.hasW(JSTART_LENGTH_METRES)       &&
             fit.getW(JSTART_LENGTH_METRES) > 0.0) {
           Z_m = JZRange(parameters.ZMin_m, parameters.ZMax_m + fit.getW(JSTART_LENGTH_METRES));
         }
  
         const JFIT::JModel<JLine1Z> match(tz, parameters.roadWidth_m, JRegressor_t::T_ns, Z_m);
  
         // hit selection based on start value
  
         buffer_type buffer;
  
         for (vector<JHitL0>::const_iterator i = dataL0.begin(); i != dataL0.end(); ++i) {
  
           JHitW0 hit(*i, summary.getRate(i->getPMTIdentifier()));
  
           hit.rotate(R);
  
           if (match(hit)) {
             buffer.push_back(hit);
           }
         }
  
         // select first hit
  
         sort(buffer.begin(), buffer.end(), JHitL0::compare);
  
         buffer_type::const_iterator __end = unique(buffer.begin(), buffer.end(), equal_to<JDAQPMTIdentifier>());
  
         // re-organise data
         
         map_type map;
  
         for (buffer_type::const_iterator hit = buffer.begin(); hit != __end; ++hit) {
           
           const JModule& module = router.getModule(hit->getModuleID());
  
           if (!strings.empty()) { map[module.getString()].push_back(*hit); }
           if (!modules.empty()) { map[module.getID()]    .push_back(*hit); }
         }
         
         data.push_back({map, tz});
       }
     }
   }
   STATUS(endl);
  
  
   // fit
  
   JGradient fit(number_of_iterations, number_of_extra_steps, epsilon, 3);
  
   if (strings.count(DEFAULT_ID) != 0) { strings = getStringIDs(detector); }
   if (modules.count(DEFAULT_ID) != 0) { modules = getModuleIDs(detector); }
  
   for (int id : strings) { fit.push_back(JModifier_t(MAKE_STRING("string: " << FILL(4,'0') << id << FILL()), new JEditor(data, id), T_ns)); }
   for (int id : modules) { fit.push_back(JModifier_t(MAKE_STRING("module: " << setw(8)     << id),           new JEditor(data, id), T_ns)); }
  
   const JPerth_t perth = {storage, data, threads};
  
   const double   chi2  = fit(perth);
  
   STATUS("result: " << FIXED(12,6) << chi2 << ' ' << setw(6) << fit.numberOfIterations << endl);
  
   for (size_t i = 0; i != fit.size(); ++i) {
     {
       const JEditor* p = dynamic_cast<const JEditor*>(fit[i].get());
  
       if (p != NULL) { STATUS(fit[i].name << ' ' << FIXED(9,3) << p->t0 << " [ns]" << endl); }
     }
   }
  
  
   if (overwriteDetector) {
  
     detector.comment.add(JMeta(argc, argv));
  
     map<int, double> calibration;
  
     for (size_t i = 0; i != fit.size(); ++i) {
  
       const JEditor* p = dynamic_cast<const JEditor*>(fit[i].get());
  
       if (p != NULL) {
         calibration[p->id] = p->t0;
       }
     }
  
     const double t0 = getAverage(get_values(calibration), 0.0);
  
     for (JDetector::iterator module = detector.begin(); module != detector.end(); ++module) {
  
       if (!module->empty()) {
  
         map<int, double>::const_iterator p = (!strings.empty() ? calibration.find(module->getString()) :
                                               !modules.empty() ? calibration.find(module->getID())     :
                                               calibration.end());
         if (p != calibration.end()) {
           for (int pmt = 0; pmt != NUMBER_OF_PMTS; ++pmt) {
             module->getPMT(pmt).addT0(p->second - t0);
           }
         }
       }
     }
  
     NOTICE("Store calibration data on file " << detectorFile << endl);
  
     store(detectorFile, detector);
   }
 }

Classes

Namespaces

Typedefs

Functions

Detailed Description

Function Documentation

◆ main()