Jpp/v19.1.0/JAcousticsTriggerProcessor_8cc_source.html

 #include <string>

 #include <iostream>

 #include <iomanip>

 #include <vector>

 #include <map>

 #include <algorithm>


 #include "TROOT.h"

 #include "TFile.h"


 #include "JDetector/JDetector.hh"

 #include "JDetector/JDetectorToolkit.hh"

 #include "JDetector/JHydrophone.hh"


 #include "JLang/JPredicate.hh"

 #include "JLang/JComparator.hh"


 #include "JTools/JRange.hh"

 #include "JTools/JQuantile.hh"

 #include "JTools/JHashMap.hh"


 #include "JSupport/JMultipleFileScanner.hh"

 #include "JSupport/JFileRecorder.hh"

 #include "JSupport/JMeta.hh"


 #include "JAcoustics/JToA.hh"

 #include "JAcoustics/JEmitterID.hh"

 #include "JAcoustics/JTransmission.hh"

 #include "JAcoustics/JReceiver.hh"

 #include "JAcoustics/JSoundVelocity.hh"

 #include "JAcoustics/JAcousticsToolkit.hh"

 #include "JAcoustics/JAcousticsSupportkit.hh"

 #include "JAcoustics/JTriggerParameters.hh"

 #include "JAcoustics/JEvent.hh"

 #include "JAcoustics/JSupport.hh"


 #include "Jeep/JContainer.hh"

 #include "Jeep/JProperties.hh"

 #include "Jeep/JPrint.hh"

 #include "Jeep/JParser.hh"

 #include "Jeep/JMessage.hh"


 #include "JTrigger/JMatch.hh"

 #include "JTrigger/JAlgorithm.hh"


 namespace JACOUSTICS {


   using JGEOMETRY3D::JPosition3D;

   using JTRIGGER::JMatch;

   using JLANG::JClonable;

   using JTOOLS::JRange;


   /**

    * Acoustic hit.

    */

   struct hit_type :

     public JPosition3D,

     public JTransmission

   {

     /**

      * Default constructor.

      */

     hit_type()

     {}


     /**

      * Constructor.

      *

      * \param  position         position

      * \param  transmission     transmission

      */

     hit_type(const JPosition3D& position, const JTransmission& transmission) :

       JPosition3D  (position),

       JTransmission(transmission)

     {}

   };


   /**

    * 3D match criterion for acoustic signals.

    */

   class JMatch3D :

     public JClonable< JMatch<hit_type>, JMatch3D>

   {

   public:

     /**

      * Constructor.

      *

      * \param  V                sound velocity

      * \param  Tmax_s           maximal extra time [s]

      */

     JMatch3D(const JSoundVelocity& V, const double Tmax_s = 0.0) :

       V(V),

       Tmax_s(Tmax_s)

     {}


     /**

      * Match operator.

      *

      * \param  first    hit

      * \param  second   hit

      * \return          match result

      */

     virtual bool operator()(const hit_type& first, const hit_type& second) const override

     {

       using namespace JPP;


       const double t1 = V.getTime(getDistance(first.getPosition(), second.getPosition()),

                                   first .getZ(),

                                   second.getZ());


       const double dt = fabs(first.getToA() - second.getToA());


       return dt <= t1  +  Tmax_s;

     }


     const JSoundVelocity V;

     const double         Tmax_s;

   };


   /**

    * Match of two events considering overlap in time.

    */

   struct JEventOverlap {


     typedef JRange<double> time_range;        //!< Type definition of time range.


     /**

      * Constructor.

      *

      * \param Tmax_s          maximal time difference between two consecutive events [s]

      */

     JEventOverlap(const double Tmax_s = 0.0) :

       range(-Tmax_s, +Tmax_s)

     {}


     /**

      * Match criterion.

      *

      * \param  first          first  event

      * \param  second         second event

      * \return                true if two events overlap in time; else false

      */

     bool operator()(const JEvent& first, const JEvent& second) const

     {

       using namespace JPP;


       if (first .empty()) return false;

       if (second.empty()) return false;


       time_range r1(make_array(first .begin(), first .end(), &JTransmission::getToA));

       time_range r2(make_array(second.begin(), second.end(), &JTransmission::getToA));


       r1.add(range);

       r2.add(range);


       return overlap(r1, r2);

     }


     const time_range range;

   };

 }


 /**

  * \file

  *

  * Main program to trigger acoustic data.

  *

  * An acoustic event is based on coincidences between times of arrival.\n

  * If the number of coincident times of arrival exceeds a preset minimum,

  * the event is triggered and subsequently stored in the output file.

  * \author mdejong

  */

 int main(int argc, char **argv)

 {

   using namespace std;

   using namespace JPP;


   typedef JTYPELIST<JEvent, JTriggerParameters, JMeta>::typelist  typelist;


   typedef JContainer< vector<JHydrophone> >  hydrophones_container;


   JMultipleFileScanner<JToA> inputFile;

   JLimit_t&                numberOfEvents = inputFile.getLimit();

   JTriggerParameters       parameters;

   int                      factoryLimit   = 10000;

   double                   TMaxExtra_s    = 100.0e-6;

   JFileRecorder<typelist>  outputFile;

   JSoundVelocity           V = getSoundVelocity;   // default sound velocity

   string                   detectorFile;

   hydrophones_container    hydrophones;            // hydrophones

   double                   precision;

   int                      debug;


   try {


     JProperties properties;


     properties.insert(gmake_property(parameters.Q));

     properties.insert(gmake_property(parameters.TMax_s));

     properties.insert(gmake_property(parameters.numberOfHits));

     properties.insert(gmake_property(factoryLimit));

     properties.insert(gmake_property(TMaxExtra_s));


     JParser<> zap("Main program to trigger acoustic data.");


     zap['f'] = make_field(inputFile,    "output of JConvertDB -q toashort");

     zap['n'] = make_field(numberOfEvents)                                    = JLimit::max();

     zap['@'] = make_field(properties,   "trigger parameters");

     zap['o'] = make_field(outputFile,   "output file")                       = "event.root";

     zap['V'] = make_field(V,            "sound velocity")                    = JPARSER::initialised();

     zap['a'] = make_field(detectorFile, "detector file");

     zap['H'] = make_field(hydrophones,  "hydrophone data")                   = JPARSER::initialised();

     zap['p'] = make_field(precision,    "precision time-of-arrival")         = 1.0e-6;

     zap['W'] = make_field(getEmitterID, "waveform identification data")      = JPARSER::initialised();

     zap['d'] = make_field(debug)                                             = 1;


     zap(argc, argv);

   }

   catch(const exception &error) {

     FATAL(error.what() << endl);

   }


   JDetector detector;


   try {

     load(detectorFile, detector);

   }

   catch(const JException& error) {

     FATAL(error);

   }


   V.set(detector.getUTMZ());


   const JMatch3D      match(V, TMaxExtra_s);

   const JEventOverlap overlap(parameters.TMax_s);


   JHashMap<int, JReceiver>   receivers;


   for (JDetector::const_iterator i = detector.begin(); i != detector.end(); ++i) {


     JPosition3D pos(0.0, 0.0, 0.0);


     if (i->getFloor() == 0) {                    // get relative position of hydrophone


       try {

         pos = getPosition(hydrophones.begin(),

                           hydrophones.end(),

                           make_predicate(&JHydrophone::getString, i->getString()));

       }

       catch(const exception&) {

         continue;                                // if no position available, discard hydrophone

       }

     }


     receivers[i->getID()] = JReceiver(i->getID(),

                                       i->getPosition() + pos,

                                       i->getT0() * 1.0e-9);

   }


   outputFile.open();


   if (!outputFile.is_open()) {

     FATAL("Error opening file " << outputFile << endl);

   }


   outputFile.put(JMeta(argc, argv));

   outputFile.put(parameters);


   // input data


   typedef vector<hit_type> buffer_type;          // data type


   map<int, map< int, buffer_type > >  f1;        // emitter -> receiver -> data


   while (inputFile.hasNext()) {


     if (inputFile.getCounter()%100000 == 0) {

       STATUS("counter: " << setw(8) << inputFile.getCounter() << '\r' << flush); DEBUG(endl);

     }


     JToA* parameters = inputFile.next();


     if (detector.getID() != parameters->DETID) { // consistency check

       FATAL("Invalid detector identifier " << parameters->DETID << " != " << detector.getID() << endl);

     }


     if (receivers.has(parameters->DOMID)) {


       const JReceiver&    receiver = receivers[parameters->DOMID];


       double toa = parameters->TOA_S();


       const JTransmission transmission(parameters->RUN,

                                        parameters->DOMID,

                                        parameters->QUALITYFACTOR,

                                        parameters->QUALITYNORMALISATION,

                                        receiver.getT(toa),

                                        receiver.getT(toa));

       try {

         f1[getEmitterID(parameters->WAVEFORMID)][receiver.getID()].push_back(hit_type(receiver.getPosition(), transmission));

       }

       catch(const exception&) {}

     }

   }

   STATUS(endl);


   for (map<int, map< int, buffer_type> >::iterator i = f1.begin(); i != f1.end(); ++i) {


     buffer_type data;


     for (map< int, buffer_type>::iterator receiver = i->second.begin(); receiver != i->second.end(); ++receiver) {


       // filter similar hits


       sort(receiver->second.begin(), receiver->second.end(), JTransmission::compare(precision));


       buffer_type::iterator __end = unique(receiver->second.begin(), receiver->second.end(), JTransmission::equals(precision));


       // selection based on quality


       for (buffer_type::const_iterator p = receiver->second.begin(); p != __end; ++p) {

         if (p->getQ() >= parameters.Q * (parameters.Q <= 1.0 ? p->getW() : 1.0)) {

           data.push_back(*p);

         }

       }

     }


     sort(data.begin(), data.end(), make_comparator(&hit_type::getToA, JComparison::lt()));          // sort according time-of-arrival


     buffer_type buffer(factoryLimit);               // local buffer of hits

     JEvent      out[2];                              // FIFO of events


     for (buffer_type::const_iterator p = data.begin(); p != data.end(); ++p) {


       if (distance(data.cbegin(),p)%1000 == 0) {

         STATUS("processed[" << i->first << "]: " << FIXED(5,1) << (double) (100 * distance(data.cbegin(),p)) / (double) data.size() << "%" << '\r' << flush); DEBUG(endl);

       }


       buffer_type::const_iterator q = p;


       while (++q != data.end() && q->getToA() - p->getToA() <= parameters.TMax_s) {}


       if (distance(p,q) >= parameters.numberOfHits) {


         if (distance(p,q) < factoryLimit) {


           buffer_type::iterator root = buffer.begin();

           buffer_type::iterator __p  = buffer.begin();

           buffer_type::iterator __q  = buffer.begin();


           *root = *p;


           ++__p;

           ++__q;


           for (buffer_type::const_iterator i = p; ++i != q; ) {

             if (match(*p,*i)) {

               *__q = *i;

               ++__q;

             }

           }


           if (distance(root,__q) >= parameters.numberOfHits) {


             __q = clusterize(__p, __q, match, parameters.numberOfHits - 1);


             if (distance(root,__q) >= parameters.numberOfHits) {

               out[1] = JEvent(detector.getID(), out[0].getCounter() + 1, i->first, root, __q);

             }

           }


         } else {


           out[1] = JEvent(detector.getID(), out[0].getCounter() + 1, i->first, p, q);

         }


         if (out[0].empty()) {


           out[0] = out[1];                           // shift


         } else if (overlap(out[0],out[1])) {


           out[0].merge(out[1]);                      // merge


         } else {


           outputFile.put(out[0]);                    // write


           out[0] = out[1];                           // shift

         }


         out[1].clear();

       }

     }


     if (!out[0].empty()) {


       outputFile.put(out[0]);                        // write

     }

     STATUS(endl);

     STATUS("triggers[" << i->first << "]: " << setw(7) << out[0].getCounter() << endl);

   }


   JMultipleFileScanner<JMeta> io(inputFile);


   io >> outputFile;


   outputFile.close();

 }

JAcousticsSupportkit.hh
Acoustics support kit.

JAcousticsToolkit.hh
Acoustics toolkit.

main
int main(int argc, char **argv)
Definition: JAcousticsTriggerProcessor.cc:182

JEvent.hh
Acoustic event.

JSupport.hh
ROOT TTree parameter settings.

JTriggerParameters.hh
Acoustic trigger parameters.

JAlgorithm.hh
Algorithms for hit clustering and sorting.

JContainer.hh
Container I/O.

outputFile
string outputFile
Definition: JDAQTimesliceSelector.cc:37

JDetectorToolkit.hh

JDetector.hh
Data structure for detector geometry and calibration.

JEmitterID.hh
Emitter identification.

JFileRecorder.hh
Recording of objects on file according a format that follows from the file name extension.

JHashMap.hh
General purpose class for hash map of unique elements.

JHydrophone.hh
Data structure for hydrophone.

JComparator.hh

JMatch.hh
Base class for match operations for cluster and hit-preprocessing methods.

JMessage.hh
General purpose messaging.

DEBUG
#define DEBUG(A)
Message macros.
Definition: JMessage.hh:62

STATUS
#define STATUS(A)
Definition: JMessage.hh:63

FATAL
#define FATAL(A)
Definition: JMessage.hh:67

debug
int debug
debug level
Definition: JSirene.cc:69

JMeta.hh
ROOT I/O of application specific meta data.

JMultipleFileScanner.hh
Scanning of objects from multiple files according a format that follows from the extension of each fi...

JParser.hh
Utility class to parse command line options.

make_field
#define make_field(A,...)
macro to convert parameter to JParserTemplateElement object
Definition: JParser.hh:2142

JPredicate.hh

JPrint.hh
I/O formatting auxiliaries.

JProperties.hh
Utility class to parse parameter values.

gmake_property
#define gmake_property(A)
macros to convert (template) parameter to JPropertiesElement object
Definition: JProperties.hh:1293

JQuantile.hh

JRange.hh
Auxiliary class to define a range between two values.

JReceiver.hh
Acoustic receiver.

JSoundVelocity.hh
Sound velocity.

JToA.hh
Acoustic event.

JTransmission.hh
Acoustic transmission.

distance
std::vector< T >::difference_type distance(typename std::vector< T >::const_iterator first, typename PhysicsEvent::const_iterator< T > second)
Specialisation of STL distance.
Definition: PhysicsEvent.hh:434

JACOUSTICS::JMatch3D
3D match criterion for acoustic signals.
Definition: JAcousticsTriggerProcessor.cc:87

JACOUSTICS::JMatch3D::V
const JSoundVelocity V
Definition: JAcousticsTriggerProcessor.cc:122

JACOUSTICS::JMatch3D::JMatch3D
JMatch3D(const JSoundVelocity &V, const double Tmax_s=0.0)
Constructor.
Definition: JAcousticsTriggerProcessor.cc:95

JACOUSTICS::JMatch3D::Tmax_s
const double Tmax_s
Definition: JAcousticsTriggerProcessor.cc:123

JACOUSTICS::JMatch3D::operator()
virtual bool operator()(const hit_type &first, const hit_type &second) const override
Match operator.
Definition: JAcousticsTriggerProcessor.cc:108

JDETECTOR::JDetector
Detector data structure.
Definition: JDetector.hh:96

JDETECTOR::JLocation::getString
int getString() const
Get string number.
Definition: JLocation.hh:135

JEEP::JProperties
Utility class to parse parameter values.
Definition: JProperties.hh:501

JGEOMETRY3D::JPosition3D
Data structure for position in three dimensions.
Definition: JPosition3D.hh:38

JGEOMETRY3D::JPosition3D::getPosition
const JPosition3D & getPosition() const
Get position.
Definition: JPosition3D.hh:130

JGEOMETRY3D::JVector3D::getZ
double getZ() const
Get z position.
Definition: JVector3D.hh:115

JLANG::JException
General exception.
Definition: JException.hh:24

JLANG::JObjectID::getID
int getID() const
Get identifier.
Definition: JObjectID.hh:50

JPARSER::JParser
Utility class to parse command line options.
Definition: JParser.hh:1698

JSUPPORT::JFileRecorder
Object writing to file.
Definition: JFileRecorder.hh:44

JSUPPORT::JMultipleFileScanner
General purpose class for object reading from a list of file names.
Definition: JMultipleFileScanner.hh:306

JSUPPORT::JMultipleFileScanner::hasNext
virtual bool hasNext() override
Check availability of next element.
Definition: JMultipleFileScanner.hh:409

JSUPPORT::JMultipleFileScanner::getCounter
counter_type getCounter() const
Get counter.
Definition: JMultipleFileScanner.hh:382

JSUPPORT::JMultipleFileScanner::next
virtual const pointer_type & next() override
Get next element.
Definition: JMultipleFileScanner.hh:457

JTOOLS::JHashCollection::has
bool has(const T &value) const
Test whether given value is present.
Definition: JHashCollection.hh:309

JTOOLS::JRange
Range of values.
Definition: JRange.hh:42

JTOOLS::JRange::add
range_type & add(argument_type x)
Add offset.
Definition: JRange.hh:446

JTRIGGER::JMatch
Function object interface for hit matching.
Definition: JMatch.hh:27

std::map
Definition: JSTDTypes.hh:19

std::vector< hit_type >

GAUSS_LEGENDRE::f1
const JPolynome f1(1.0, 2.0, 3.0)
Function.

JACOUSTICS
Auxiliary classes and methods for acoustic position calibration.
Definition: JAbstractSoundVelocity.hh:10

JACOUSTICS::getEmitterID
static JEmitterID getEmitterID
Function object for emitter identification.
Definition: JEmitterID.hh:119

JACOUSTICS::getPosition
JVector3D getPosition(T __begin, T __end, const JPredicate< JTypename_t, JComparator_t > &predicate)
Get position from element in data which corresponds to given predicate.
Definition: JAcousticsToolkit.hh:132

JACOUSTICS::hydrophones_container
JContainer< std::vector< JHydrophone > > hydrophones_container
Definition: JSydney.cc:79

JACOUSTICS::getSoundVelocity
static const JSoundVelocity getSoundVelocity(1541.0, -17.0e-3, -2000.0)
Function object for velocity of sound.

JDETECTOR::load
void load(const std::string &file_name, JDetector &detector)
Load detector from input file.
Definition: JDetectorToolkit.hh:505

JLANG::make_comparator
JComparator< JResult_t T::*, JComparison::lt > make_comparator(JResult_t T::*member)
Helper method to create comparator between values of data member.
Definition: JLang/JComparator.hh:185

JLANG::make_array
const array_type< JValue_t > & make_array(const JValue_t(&array)[N])
Method to create array of values.
Definition: JVectorize.hh:54

JLANG::make_predicate
JPredicate< JResult_t T::*, JComparison::eq > make_predicate(JResult_t T::*member, const JResult_t value)
Helper method to create predicate for data member.
Definition: JPredicate.hh:128

JMATH::getDistance
double getDistance(const JFirst_t &first, const JSecond_t &second)
Get distance between objects.
Definition: JMathToolkit.hh:118

JPP
This name space includes all other name spaces (except KM3NETDAQ, KM3NET and ANTARES).
Definition: JAAnetToolkit.hh:43

JRECONSTRUCTION::buffer_type
std::vector< JHitW0 > buffer_type
hits
Definition: JPerth.cc:71

JRECONSTRUCTION::JEvent
JFIT::JEvent JEvent
Definition: JHistory.hh:353

JTOOLS::overlap
bool overlap(const JRange< T, JComparator_t > &first, const JRange< T, JComparator_t > &second)
Test overlap between ranges.
Definition: JRange.hh:641

JTRIGGER::clusterize
static const struct JTRIGGER::clusterize clusterize

applications.data
data
Definition: applications.py:8

root
Definition: root.py:1

std
Definition: JSTDTypes.hh:14

FIXED
Auxiliary data structure for floating point format specification.
Definition: JManip.hh:448

JAANET::detector
Detector file.
Definition: JHead.hh:227

JACOUSTICS::JCounter::getCounter
int getCounter() const
Get counter.
Definition: JAcoustics/JCounter.hh:51

JACOUSTICS::JEventOverlap
Match of two events considering overlap in time.
Definition: JAcousticsTriggerProcessor.cc:130

JACOUSTICS::JEventOverlap::time_range
JRange< double > time_range
Type definition of time range.
Definition: JAcousticsTriggerProcessor.cc:132

JACOUSTICS::JEventOverlap::range
const time_range range
Definition: JAcousticsTriggerProcessor.cc:167

JACOUSTICS::JEventOverlap::operator()
bool operator()(const JEvent &first, const JEvent &second) const
Match criterion.
Definition: JAcousticsTriggerProcessor.cc:151

JACOUSTICS::JEventOverlap::JEventOverlap
JEventOverlap(const double Tmax_s=0.0)
Constructor.
Definition: JAcousticsTriggerProcessor.cc:139

JACOUSTICS::JEvent
Acoustic event.
Definition: JAcoustics/JEvent.hh:43

JACOUSTICS::JEvent::merge
void merge(const JEvent &event)
Merge event.
Definition: JAcoustics/JEvent.hh:165

JACOUSTICS::JReceiver
Acoustic receiver.
Definition: JReceiver.hh:30

JACOUSTICS::JReceiver::getT
double getT(const double t_s) const
Get corrected time.
Definition: JReceiver.hh:72

JACOUSTICS::JSoundVelocity
Implementation for depth dependend velocity of sound.
Definition: JSoundVelocity.hh:37

JACOUSTICS::JSoundVelocity::set
JSoundVelocity & set(const double z0)
Set depth.
Definition: JSoundVelocity.hh:62

JACOUSTICS::JSoundVelocity::getTime
virtual double getTime(const double D_m, const double z1, const double z2) const override
Get propagation time of sound.
Definition: JSoundVelocity.hh:147

JACOUSTICS::JToA
Time-of-arrival data from acoustic piezo sensor or hydrophone.
Definition: JToA.hh:26

JACOUSTICS::JToA::DOMID
uint32_t DOMID
DAQ run number.
Definition: JToA.hh:32

JACOUSTICS::JToA::QUALITYFACTOR
uint32_t QUALITYFACTOR
The ticks (16ns) part of the DAQ frame timestamp.
Definition: JToA.hh:37

JACOUSTICS::JToA::QUALITYNORMALISATION
uint32_t QUALITYNORMALISATION
A measure of how good the waveform match was to the signal.
Definition: JToA.hh:38

JACOUSTICS::JToA::WAVEFORMID
int32_t WAVEFORMID
DOM unique identifeir.
Definition: JToA.hh:33

JACOUSTICS::JToA::DETID
int32_t DETID
Definition: JToA.hh:30

JACOUSTICS::JToA::RUN
int32_t RUN
detector identifier
Definition: JToA.hh:31

JACOUSTICS::JToA::TOA_S
double TOA_S() const
Time of Arrival, expressed in seconds relative to Unix epoch (1 January 1970 00:00:00 UTC)
Definition: JToAImp.cc:40

JACOUSTICS::JTransmission::compare
Auxiliary class to compare transmissions.
Definition: JTransmission.hh:230

JACOUSTICS::JTransmission::equals
Auxiliary class to compare transmissions.
Definition: JTransmission.hh:198

JACOUSTICS::JTransmission
Acoustic transmission.
Definition: JTransmission.hh:31

JACOUSTICS::JTransmission::getToA
double getToA() const
Get calibrated time of arrival.
Definition: JTransmission.hh:126

JACOUSTICS::JTriggerParameters
Trigger parameters.
Definition: JAcoustics/JTriggerParameters.hh:28

JACOUSTICS::JTriggerParameters::Q
double Q
minimal quality if larger than one; else minimal normalised quality
Definition: JAcoustics/JTriggerParameters.hh:47

JACOUSTICS::JTriggerParameters::TMax_s
double TMax_s
maximal difference between times of emission [s]
Definition: JAcoustics/JTriggerParameters.hh:48

JACOUSTICS::JTriggerParameters::numberOfHits
int numberOfHits
minimal number of hits to trigger event
Definition: JAcoustics/JTriggerParameters.hh:49

JACOUSTICS::hit_type
Acoustic hit.
Definition: JAcousticsTriggerProcessor.cc:61

JACOUSTICS::hit_type::hit_type
hit_type()
Default constructor.
Definition: JAcousticsTriggerProcessor.cc:65

JACOUSTICS::hit_type::hit_type
hit_type(const JPosition3D &position, const JTransmission &transmission)
Constructor.
Definition: JAcousticsTriggerProcessor.cc:75

JEEP::JContainer
Auxiliary wrapper for I/O of container with optional comment (see JComment).
Definition: JContainer.hh:42

JLANG::JClonable
Template class for object cloning.
Definition: JClonable.hh:59

JLANG::JComparison::lt
Less than.
Definition: JComparison.hh:57

JLANG::JTypeList
Type list.
Definition: JTypeList.hh:23

JPARSER::initialised
Empty structure for specification of parser element that is initialised (i.e. does not require input)...
Definition: JParser.hh:68

JSUPPORT::JLimit
Auxiliary class for defining the range of iterations of objects.
Definition: JLimit.hh:45

JSUPPORT::JMeta
Auxiliary class for ROOT I/O of application specific meta data.
Definition: JMeta.hh:72

JTOOLS::JHashMap
General purpose class for hash map of unique keys.
Definition: JHashMap.hh:75

std::iterator
Definition: JSTDTypes.hh:21